AUSTRALIAN STEEL INSTITUTE (ABN)/ACN (94) 000 973 839
STEEL CONSTRUCTION JOURNAL OF THE AUSTRALIAN STEEL INSTITUTE VOLUME 36 NUMBER 2 SEPTEMBER 2002
Design of Pinned Column Base Plates
ISBN 0049-2205 Print Post Approved pp 255003/01614
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STEEL CONSTRUCTION -- EDITORIAL This paper is one of a planned series which deals with the design and use of rationalized structural connections. It draws draws heavi heavily ly on the the excel excelle lent nt work work done done in the the publ public icat atio ionn “Design of Structural Connections” by Tim Hogan and Ian Thomas. Since that time, there has been new research, some variations to the design models, new steel grades introduced introduced and some some minor changes changes in section section properties. properties. We have also seen the adoption of sophisticated 3D modeling software which has the capability to generate many different connection types. The ASI, through this proje project ct is endeav endeavou ourin ringg to provi provide de an indu indust stry ry wide wide ratio rational naliz ized ed set of dime dimensi nsion ons, s, mode models ls and and desi design gn capacities.
Editor: Peter Kneen STEELCONSTRUCTION STEELCONSTRUCTION is published published biannually biannually by the AustralianSteel AustralianSteel Institute (ASI). The ASI was formed in September 2002 following the merger of the Australian Institute Institute for Steel Construction (AISC) and the Steel Institute Institute of Australia (SIA). The ASI is Australia’s premier technical marketing organisation representing companies and individuals involved in steel manufact manufacture, ure, distribut distribution, ion, fabricat fabrication, ion, design, design, detailing detailing and construct construction. ion. Its mission mission is to promote promote the efficie efficient nt and economical economical use of steel. steel. Partof its work is to conduct technical seminars, educational lectures and to publish publish and market market technicaldesign technicaldesign aids.Itsservicesare available available free free of charge to financial corporate members. members. For details regarding ASI services, readers may contact the Institute’s offices, offices, or visit the ASI website www.steel.org.au www.steel.org.au Disclaimer: Every effort effort has been made and all reasonable care taken to ensure ensure the accuracy of the material material contained contained in this publication. publication. However However,, to the extent permitted permitted by law, law, the Authors, Authors, Editors Editors and Publishers of this publication: (a) will not be held liable or responsible in any way; and (b) expressly disclaim any liability or responsibility for any loss or damage costs or expenses incurred in connection with this
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STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Design of Pinned Column Base Plates Contents
This paper deals with the design of pinned base plates. The design actions considered are axial compression, axial tension, shear force and their combinations. The base plate is assumed to be essentially statically loaded, andadditionalconsiderations may be required in the case of dynamic loads or in fatigue applications.
1.
INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1. Design actions in accordance with AS 4100 . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. NOTATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. BASE PLATE COMPONENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4. AXIAL COMPRESSION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1. INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2. BASE PLATE DESIGN -- LITERATURE REVIEW . . . . . . . . . . . . . . . . . . . . 4.3. RECOMMENDED MODEL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5. AXIAL TENSION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1. INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2. BASE PLATE DESIGN -- LITERATURE REVIEW . . . . . . . . . . . . . . . . . . . . 5.3. DESIGN OF ANCHOR BOLTS -- LITERATURE REVIEW . . . . . . . . . . . . . 5.4. RECOMMENDED MODEL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6. SHEAR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1. INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2. TRANSFER OF SHEAR BY FRICTION OR BY RECESSING THE BASE PLATE INTO THE CONCRETE -LITERATURE REVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3. TRANSFER OF SHEAR BY A SHEAR KEY-- LITERATURE REVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.4. TRANSFER OF SHEAR BY THE ANCHOR BOLTS -LITERATURE REVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.5. RECOMMENDED MODEL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. BASE PLATE AND ANCHOR BOLTS DETAILING . . . . . . . . . . . . . . . . . . . . . . 8. ACKNOWLEDGEMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9. REFERENCES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10. APPENDIX A -- Derivation of Design and Check Expressions for Steel Base Plates Subject to Axial Compression . . . . . . . . . . . . . . . . . . . . . . . . 11. APPENDIX B-- Derivation of Design and Check Expressions for Steel Base Plates Subject to Axial Tension . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12. APPENDIX C -- Determination of Embedment Lengths and Edge Distances . . . . 13. APPENDIX D -- Design Capacities of Equal Leg Fillet Welds . . . . . . . . . . . . . . . . 14. APPENDIX E -- Design of Bolts under Tension and Shear . . . . . . . . . . . . . . . . . . .
1 1 1 3 3 3 4 10 12 12 12 17 21 30 30 30 30 31 34 36 38 38 40 46 49 53 53
Design of Pinned Column Base Plates Gianluca Ranzi School of Civil and Environmental Engineering The University of New South Wales Peter Kneen National Manager Technology Australian Steel Institute 1. INTRODUCTION This paper deals with the design of pinned base plates. The design actions considered are axial compression, axial tension, shear force and their combinations as shown in Fig. 1. The base plate is assumed to be essentially statically loaded, and additional considerations may be required in the case of dynamic loads or in fatigue applications. N *t
N*t
N*c V*x
Figure 1
N*c V*y
Column Design Actions: Axial and Shear Loads along minor and major axes (Ref. [26])
Firstly the requirements of AS 4100 ”Steel Structures” [11] in the calculation of the design actions for connections are outlined. Then for each design action available design guidelines and/or models are briefly presented in a chronological manner to provide an overview on how these have improved/changed over time. Attention has been given to try to ensure that the assumptions and/or limitations of each model presented arealwaysclearlystated.Amongthesemodels,themost representative onesin the opinion of the authorsare then recommended for design purposes. It is not intended to suggest that models, other than those recommended, may not give adequate capacities. The design of concrete elements is outside the scope of the present paper. Nevertheless some design considerations regarding the concrete elements still need to be addressed, i.e. bolts’ edge distances, bolts’ embedment lengths, concrete strength etc., and therefore it is necessary to ensure that such design assumptions/considerations are included in the final design of the concrete elements/structure. 1.1.
Design actions in accordance with AS 4100
Pinned type column base plates may be subject to the following design actions, as shown in Fig. 1: an axial force, N*, either tension or compression;
1
a shear force, V* (usually acting in the direction of either principal axis or both). Clause 9.1.4 of AS 4100 [11], which considers minimum design actions, does not specifically mention minimum design actions for column base plates but does require that: connections at the ends of tension or compression members be designed for a minimum force of 0.3 times the member design capacity; connections to beams in simple construction be designed for a minimum shear force equal to the lesser of 0.15 times the member design shear capacity and 40 kN. It is considered inappropriate for these provisions to be applied to column base plates, since the design of columns is usually governed by a combinations of axial loads and bending moments at other locations.
2. NOTATION The following notation is used in this work. Other symbols which are defined within diagrams may not be listed below. Generally speaking, the symbols will be defined when first used. a b = distance from centre of bolt hole to inside face of flange a e = minimum concrete edge distance (side cover) A 1 = bearing area which varies depending upon the assumed pressure distribution between the base plate and the grout/concrete A (i) = bearing area at the i-- th iteration in 1 Murray--Stockwell Model A 2 = supplementary area whichis the largest area of the supporting concrete surface that is geometrically similar to and concentric to A 1 A H = assumed bearing area (in the case of H--shaped sections it is a H--shaped area) in Murray-Stockwell Model A (i) = assumed bearing A H at the i--th iteration in H Murray--Stockwell Model A i = base plate area A psk = projected area over the concrete edge ignoring the shear key area A ps = effective projected area of concrete under uplift
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
A ps.1 = effective projected area of isolated anchor bolt (no overlapping of failure cones) A ps.2 = effective projected area of 2 anchor bolts with overlapping of their failure cones A ps.4 = effective projected area of 4 anchor bolts with overlapping of their failure cones. In this case each failure cone overlaps with all other 3 failure cones A s = tensile stress area in accordance with AS1275 [9] A sk = area of the shear key b c = width of the column section (RHS and SHS) b fc = width of the column section (H-- shaped sections and channels) b fc1 = width of the column flange ignoring web thickness b i = width of base plate b s = depth of shear key b t =distancefromfaceofwebtoanchorboltlocation d c = column depth d c1 = clear depth between flanges (column depth ignoring thicknesses of flanges) d f = nominal anchor bolt diameter d h = diameter of bolt hole d i = length of base plate d 0 = outside diameter of CHS f ′ c = characteristic compressive cylinder strength of concrete at 28 days f *p = uniform design pressure at the interface of the base plate and grout/concrete f uf = minimum tensile strength of bolt f uw = nominal tensile strength of weld metal f yi = yield stress of the base plate used in design f ys = yield stress of shear key used in design
N*c = column design axial compression load N*b = N *t ∕n b = design axial tension load carried by one bolt Ndes.c = design capacity of the base plate connection subject to axial compression Ndes.t = design capacity of the base plate connection subject to axial tension N*p = prying action N*t = design axial tension load of the column Ntf = nominal tensile capacity of a bolt in tension N*0 = portion of N*c acting over the column footprint s p = bolt pitch S i = plastic section modulus per unit width of plate t c = thickness of column section t i = base plate thickness t g = grout thickness t s = thickness of shear key t t = design throat thickness of fillet weld t w = thickness of column web v des = Ôv w = design capacity of the weld connecting the base plate to the column per unit length v *h and v *v = componentsof the loading carried bythe weld between column and base plate in one horizontal direction in the plane of the base plate and in the vertical direction respectively per unit length * v w = design action on fillet weld per unit length Vdes = design shear capacity of the base plate connection
V*s = design shear force to be transferred by means of the shear key W i and W e = internal and external work
k r = reduction factor to account for length of welded lap connection L d = minimum embedment length of anchor bolt
Ô = capacity factor
L h = hook length of anchor bolt
Ôf b = maximum bearing capacity of the concrete based on a certain bearing area A 1
L s = length of shear key L w = total length of fillet weld m p = plastic moment capacity of the base plate per unit width m s = nominal section moment capacity of the base plate per unit width m sk = nominal section moment capacity per unit width of shear key m *c = design moment per unit width due to N *c m *sk = design moment to be carried by the shear key per unit width m *t = design moment per unit width due to N *t
2
n b = number of anchor bolts part of the base plate connection
= maximum bearing strength of the concrete at Ôf (i) b the i--th iteration in Murray--Stockwell Model
ÔN c = design axial capacity of the concrete foundation ÔN c.lat = lateral bursting capacity of the concrete ÔN cc = design pull--out capacity of the concrete foundation ÔN s = design axial capacity of the steel base plate ÔN t = axial tension capacity of the base plate ÔN tb = design capacity of the anchor bolt group under tension ÔN th = tensile capacity of a hooked bar ÔN w = design axial capacity of the weld connecting the base plate to the column section
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Ôv w = design capacity of the fillet weld per unit length ÔV f = design shear capacity of the base plate transferred by means of friction ÔV s = design shear capacity of the shear key ÔV s.c = concrete bearing capacity of the shear key ÔV s.cc = pull--out capacity of the concrete ÔV s.b = shear capacity of the shear key based on its section moment capacity
There is a large variety of drilled--in anchors available, many of which are proprietary bolts whose installation and design is governed by manufacturers’ specifications. References [2], [15], [17], [31] and [33] contain information on these types of anchors. This paper deals only with cast--in--place anchors, and specifically hooked bars, anchor bolts with a head and threaded rods with a nut/washer/plate. Grade 4.6 anchor bolts are recommended to be utilised in base plate applications.
ÔV s.w = shear capacity of the weld between the shear key and the base plate ÔV w = design shearcapacity of the weld connecting the base plate to the column
η = ratio depth and width of column μ = coefficient of friction
3.
BASE PLATE COMPONENTS
Typical base plates considered in this paper are formed by one unstiffened plate only as shown in Fig. 3. For highly loaded columns or larger structures other base plate solutions or more elaborate anchor bolt systems might be required. Guidelines for the design and detailing of more complex base plates can be found in [4], [13], [14], [16] and [34]. Two types of anchor bolts are usually used, which are cast--in--place or drilled--in bolts. The former are placed before the placing of the concrete or while the concrete is still fresh while the latter are inserted after the concrete has fully hardened. Different types of cast--in--place anchors are shownin in Fig. 2. These include anchor bolts with a head, threaded rods with nut,threaded rods with a plate washer, hooked bars or U-- bolts. These are suitable for small to medium size structures considering anchor bolts up to 30 mm in diameter.
sp
sg
Figure 3
Typical unstiffened base plate (Ref. [26])
4. AXIAL COMPRESSION 4.1.
INTRODUCTION
The literature review presented covers only models regarding the design of the actual steel plate as the anchor bolts do not contribute to the strength of the connection under this loading condition. Unless special confinement reinforcement is provided the maximum bearing strength of the concrete Ôf b is calculated in accordance with Clause 12.3 of AS 3600 [10] as follows:
Ôf b = min Ô0.85f ′ c
(a) Hooked Bar
(b) Bolt with head
(c) Threaded Rod with Nut
(d) Threaded rod with plate washer
Figure 2
3
(1)
where: Ô = 0.6 Ôf b = maximum bearing capacity of the concrete based on a certain bearing area A 1 f ′ c = characteristic compressive cylinder strength of concrete at 28 days
Fillet welds Square plate
A 2 , Ô2f ′ c A 1
(e) U--Bolt
Common Forms of Holding Down Bolts (Ref. [26])
A 1 = bearing area which varies depending upon the assumed pressure distribution between the base plate and the grout/concrete A 2 = supplementary area whichis the largest area of the supporting concrete surface that is geometrically similar to and concentric to A 1
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
4.2.
BASE PLATE DESIGN -- LITERATURE REVIEW
The main design models available in literature differ for their assumptions adopted regarding the pressure distribution at the interface between the base plate and the grout/concrete and for the relative sizes of the base plate and the connected column. For example, the first model presented, here referred to as the Cantilever Model, is adequate for base plates whose dimensions (d i × b i ) are much greater than those of the column (d c × b fc ), while other models, such as Fling and Murray--Stockwell Models, deal with base plates with similar dimensions to the ones of the connected column. 4.2.1.
This model assumes that, in the case of a H--shaped column, the axial load applied by the column is concentrated over an area of 0.95d c × 0.80b fc which corresponds to the shaded area of Fig. 4(a). This causes the base plate to bend as a cantilevered plate about the edges of such area as shown in Fig. 4(b). The pressure at the underside of the base plate is assumed to be uniformly distributed, as shown in Fig. 4(c), therefore leading to a conservative design for large base plates. a1
Cantilever Model
Historically the cantilever model was the first available approach for the design of base plates. It is well suited for the design of large base plates with the dimensions ofthe base plate (di × b i)muchgreaterthanthoseofthe column (dc × b fc). It hasbeen present in the AISC(US) Manuals over several editions. Its formulation is suitable for the base plate design of only H--shaped columns. [5] bi b fc a1 dc
0.95d c
di
a1
a1 Dashed lines indicate yield lines Figure 5
0.8b fc
a2
Cantilever Model -- Collapse mechanisms
Eachof the two collapse mechanisms considered by this model assumes two yield lines to form at a distance a1 and a2 from the edge of the plate respectively as shown in Fig. 5. Comparing the two collapse mechanisms and according to the rules of yield line theory the governing design capacity is based on the longest cantilever length a m, being the maximum of the two cantilevered lengths a 1 and a2 shown in Fig. 4(a). The design moment m *c and the design capacity of the plate Ôm s are calculated per unit width in accordance with AS 4100 [11] as: m *c =
a2
a2
a2
N *c a 2m b id i 2
(2)
Ôm s = Ô f yiS i =
(a) Critical sections and assumed loaded area
0.9f yi t 2i
(3)
4
where:
Critical section in bending
am
N*c = column design axial compression load m *c = design moment per unit width due to N *c ti
N *c b id i (b) Deflection of the cantilevered plate N*c
N *c b id i
Figure 4
Cantilever Model (Ref. [26])
S i = plastic section modulus per unit width of plate a m = max(a 1, a 2) a 1 and a2 = cantilevered plate lengths
ti (c) Assumed bearing pressure
m s = plate nominalsection moment capacityper unit width f yi = yield stress of the base plate used in design
t i, d i and b i = thickness, length and width of base plate and ensuring that the plastic section modulus of the cantilevered plate Si is able to transfer the axial compression load N*c to the supporting material (verified per unit width of plate): N* a2 m c = c m b id i 2 *
≤
0.9f yi t 2i 4
= Ôms
(4)
yields a maximum design axial force of:
4
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
N c ≤ *
0.9f yi t 2i b id i
bi
(5)
2 a 2m
bc
or equivalently requires a minimum plate thickness of: t i ≥ a m
2N *c 0.9f yi b id i
a1
(6)
Provisions on how to extend this approach for channels and hollow sections columns have been provided in [21], [26] and [36]. The dimensions of the loaded areas and of the cantilevered lengths a1 and a 2 for channels and hollow sections are shown in Figs. 6, 7 and 8 and their values are summarised in Table 1 based on the recommendations in [21], [26] and [36]. The values in Table1assumethatthecolumnisweldedconcentrically to the base plate.
di
a1 0.95b fc
a2 Figure 7
a1
H--shaped section [21] Channel [26] SHS and RHS [36] SHS and RHS [21] CHS [21]
d i − 0.95d c 2 d i − 0.95d c 2 d i − d c + t i 2 d i − 0.95d c 2 d i − 0.80d o 2
b i − 0.80b fc 2 b i − 0.80b fc 2 b i − b c + t i 2 b i − 0.95b c 2 b i − 0.80d o 2
a1
dc
0.95d c
a1 a2
a2 0.8b fc Figure 6
Cantilevered plate lengths - RHS and SHS (Ref. [26])
a1 di
do
0.8do
a2
bi b fc
di
a2
bi
Table 1 Cantilever Model - Cantilevered plate lengths a1 and a2 (refer to Figs. 4, 6, 7 and 8 for the definition of the notation) SECTION
0.95d c
dc
Cantilevered plate lengths - Channels (Ref. [26])
a1 0.8d o
a2 Figure 8
a2
Cantilevered plate lengths -- CHS (Ref. [26])
Parker in [37] notes how other possible yield line patterns could be investigated for hollow sections such as the ones shown in Fig. 9. Nevertheless in [36] he recommends to investigate collapse mechanisms similar to the ones considered by the Cantilever Model with values of a1 and a2 as shown in Table 1. In [36] he also recommends to specify plate thicknesses not less than 0.2 times the maximum cantilever length in order to limit the deflection of the plate. Applying this model to base plates with similar dimensions to the onesof connected column would lead to inadequate design as the capacity of the base plate would be overestimated. Utilizing equations (5) and (6) the capacity of the base plate would increase and the plate thickness t i would decrease while decreasing the cantilevered plate length am. Other design models need to be adopted in these instances. bi Dashed lines bc indicate yield lines a1 di dc
0.95dc
a1 0.95b c
a2
5
a2
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
bi a1 d o di
0.8d o
d1
b es
a1 a2 Figure 9 4.2.2.
0.8d o
Dashed lines indicate yield lines
a2
Possible yield line pattern (Ref. [37])
β = tan θ
Fling Model
Fling,in[25],presentsadesignmodelapplicabletobase plates with similar dimensions to the ones of the connected column and reviewsthe design philosophyof the Cantilever Model. Only H--shaped columns are considered in this model. He recommends to apply both a strength and a serviceability criteria to the design of base plates. Regarding the Cantilever Method, which is based on a strength criteria, he recommends to apply also a serviceability check by limiting the deflection of the cantilevered plate. He argues that, while increasing the size of the plate, deflections of the cantilevered plate would increase reducing the ability of the most deflected parts of the plate to transfer the assumed uniform loading to the supporting material. Thus the load would re--distribute to the least deflected portions of the plate which may overstress the underlying support. His proposed deflection limit intends to prevent such overstressing. He also notes that such limit should vary depending upon the deformability of the supporting material. Fling suggests 0.01 in. (0.254 mm) to be a reasonable deflection limit to be imposed for most bearing plates, even if he clearly states that it is beyond the scope of his paper to specify deflection limits applicable to various supporting materials. [25] Regarding the design model for base plates with similar dimensions to the ones of the connected column he recommends to apply the following strength and serviceability checks. The strength check is based on the yield line theory and the assumed yield line pattern is shown in Fig. 10. The procedure is derived for a base plate with width and length equal to the column’s width and depth (therefore bi and di equal b fc and d c respectively). The support conditions assumed for the plate are fixed along the web, simply supported along the flanges and free on the edge opposite to the web.
Figure 10 Fling Model -- Yield Line Pattern (Ref. [25]) The internal and external work produced under loading are calculated as follows: W i = 1 (2d 1 + 4βb es)Ômp + 1 4b esÔm p (7) b es βb es W e = 2f *p(d 1 − 2βb es)b es 1 + 4 f *pβb2es 2 3
(8)
where: m p = plastic moment capacity of the baseplate per unit width f *p = uniform design pressure at the interface of the base plate and grout/concrete which is assumed to be equal to the maximum bearing strength of the concrete Ôf b W i and W e = internal and external work d 1, β and b es = as defined in Fig. 10 Fling introduces the following parameter λ to simplify the notation:
λ =
d1 b es
(9)
Equating the internal and external work yields: Ôm p(2λ + 4β + 4 ) = f *pb 2es( λ − 2 β) 3 β
(10)
The value of β which maximises the required moment capacity of the base plate is as follows:
β =
+ 3 4
1 − 1 4λ 2 2λ
(11)
which is obtained by differentiating for β the expression of the plastic moment derived from equation (10). Therequired baseplate thickness ti isthencalculatedas: [25]
t i ≥ 0.43b fcβ
= 0.43b fcβ
6
βb es
θ
f *p 0.9f yi (1 − β 2) Ôf b
0.9f yi(1 − β 2)
(12)
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
where:
bi
b fc = column flange width a3
Equation(12)includesasafetyfactorof1andtheplastic moment capacity is increased by 10% to allow for lack of full plastic moment at the corners (as recommended in [25]). This method assumes simultaneous crushing of the concrete foundation and yielding of the steel base plate as the pressure at the interface of the base plate and grout/concrete is assumed to be equal to the maximum bearing strength of the concrete Ô f b. The serviceability check verifies the adequacy of the maximum deflection of the base plate calculated from elastic theory and assumes the same support conditions as adopted in the strength check. The maximum deflection occurs at the middle of the free edge of the plate (opposite to the web). 4.2.3.
Murray--Stockwell Model
In 1975 Stockwell presents a design model for lightly loaded base plates with base plate dimensions similarto the column’s width and depth. His formulation is suitable to only H--shaped columns. He defines a lightly loaded base plate as one wherein the required base plate area is approximately equal to the column flange width times its depth. [40] The novelty of this model is to assume that the pressure distribution under the base plate is not uniform but is confined to an area in the immediate vicinity of the column profile and is approximated by a H--shaped area characterised by the dimension a3 as shown in Fig. 11. This pressure distribution implies that in relatively thin base plates uplift might occur at the free edge. A few years later Murray carried out a finite element study to verify the possibility introduced by Stockwell of uplift at the free edge. He established, from both modelling and testing, that thin base plates lift off the subgrade during loading and therefore the assumption ofuniformstressdistributionattheinterfaceisnotvalid. He also concludes that experimental evidence does not support the need for the serviceability check introduced by Fling. [32] Murray further expanded Stockwell’s model to obtain the model which is known today as the Murray-- Stockwell Model [41] and refines the definition of lightly loaded base plates to be relatively flexible plate approximately the same sizeas the outside dimensions of the connected column. [32] According to Stockwell there is only a little difference between the procedures specified in Fling and Murray--Stockwell Models as he considers both to be valid and logically derived. [41]
A H
di
dc a3 a3
a3 b fc
Figure 11 Murray--Stockwell Model -- Assumed shape of pressure distribution. The Murray-- Stockwell Model assumes that the pressure acting over the H--shaped bearing area is uniform and equal to the maximum bearing capacity of the concrete Ôf b. The values of A H and Ôf b are not known a priori and therefore an iterative procedure can be implemented to evaluate their values. The value of Ôf b is not known a priori as it depends upon the value of the bearing area A 1 which in this case is equal to A H. The area contained inside the column profile dc × b fc is used as a first approximation for the bearing area A H in the calculation of Ôf b as shown in equation (13).
= min Ô0.85f c′ Ôf (1) b
A 2 , Ô2f c′ A (1) 1
(13)
where: = maximum bearing strength of the concrete at Ôf (1) b the first iteration A (1) = bearing area at the first iteration equal to 1 d c × b fc The H--shaped bearing area A H is then calculated as the area required to spread the applied load with a uniform pressure equal to Ôf (1) . b A (1) = H
N *c Ôf (1)
(14)
b
where: A (1) = assumed H--shaped bearing area A H atthefirst H iteration If Ôf (1) is equal to the maximum possible concrete b bearing strength Ô 2f ′ c no further iterations are required and the value of the H-- shaped bearing area has converged to A (1) calculated with equation (14). In the H (1) case Ôf b is less than Ô2f ′ c, or equivalently if the ratio of A 2∕ A 1 is smaller than (2∕0.85) 2 = 5.53, the valueof the H--shaped bearing area can be further refined. Successive values of Ôf (i) and A (i) at the i--th iteration H b can be calculated as follows:
7
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
= min Ô0.85f ′c Ôf (i) b A (i) = H
A 2 , Ô2f ′ c A (i1 −1)
N *c Ôf (i)
(15)
(16)
b
where: = maximum bearing strength of the concrete at Ôf (i) b the i--th iteration A (i) = bearing area at the i--th iteration equal to A (iH−1) 1 A (i) = assumed H--shaped bearing A H at the i--th H iteration The value of A H can be further refined until the difference between the values obtained from two subsequentiterationscan be consideredto be negligible. The use of the iterative process allows to obtain the smallest possible value of A H which yields thinner base plate thicknesses. Ignoring to refine the value of A H would simply lead to a more conservative plate design. The value of a3 is then obtained from equation (14) observing that A H can be expressed as (refer to Fig. 11):
The Stockwell--Murray Method is recommended by DeWolf in Refs [21] and [22] and introduced in the AISC(US) Manuals in 1986. [7] [1] notes that there are cases where the value under the square root of equation (18) becomes negative. In such cases other design models should be adopted. Ref. [21] extends the application of Murray--Stockwell Model to channels and hollow section members as shown in Figs. 12, 13 and 14. For these sections the value of the bearing area A (1) (to be utilised in the first 1 iteration while calculating Ôf (1) and A (1) ) and the H b expressions of the cantilevered length a3 and of the H--shaped area A H are summarised in Table 2. [21][26] The same iterative procedure, as outlined for H--shaped sections, can be adopted to refine the value of A H if the calculated Ôf b is less than Ô2f ′ c. a3
a3
A H = 2b fca 3 + 2a 3(d c − 2a 3)
= 2b fca3 + 2d ca3 − 4a 23
(17) a3
where: a 3 = cantilevered langth
Figure 12 Murray--Stockwell Model: Assumed pressure distribution -Channels (Ref. [26])
A H = assumed H--shaped bearing area d c and b fc = depth and width of column and solving for a 3 yields:
a 3 = 1 (d c + b fc) − (d c + b fc) 2 − 4A H 4
a3
(18)
The plate is now designed in accordance with AS4100 [11] as a cantilevered plate of length a 3 supporting a uniform pressure equal to the converged value of the maximum bearing strength of the concrete previously calculated: a 23
2 N c a 3 * m c = Ôf b = A 2 2 H *
≤
0.9 f yi t 2i 4
= Ôms
The maximum axial load is then calculated as: N *c ≤
0.9f yi t 2i A H
(19)
2a 23
a3 a3
a3
Figure 13 Murray--Stockwell Model: Assumed pressure distribution -- RHS and SHS (Ref. [26]) d3
a3
or equivalently the minimum required plate thickness ti is determined as: t i ≥ a 3
2N *c 0.9f yi A H
(20)
The value of the cantilevered plate length a3 should be measured from the centre--line of the column’s plate elements as shown in Fig. 11.[21]. Nevertheless in the formulation presented here, as also carried out in [32] and [21], the full flange thickness is included in the calculation of the cantilevered plate length a3. This only leads to a slightly more conservative design.
8
do
Figure 14 Murray--Stockwell Model: Assumed pressure distribution -- CHS (Ref. [26])
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
4.2.4.
Thornton’s Model
In [42] and [43] Thornton recommends that a satisfactory design of a base plate should be carried out complying with the requirements of the Cantilever, Fling (ignoring the serviceability check) and Murray--Stockwell Models. He derived a compact formulation for the design procedure which includes all three models. His formulation is suitable for the design of only H--shaped columns. In [42] he also re-- derives the collapse load based on the same yield line pattern assumed by Fling in [25]. It is interesting to note that while Fling applied the principle of virtual work Thornton based his results on the equilibrium equations [35]. Obviously the results are identical. Note that Fling increased the required plate plastic moment by 10% to allow for lack of plastic moment at the corners. The design expression proposed by Thornton in [43] and currently recommended in the AISC(US) Manual [5] is as follows: t i = a m
2N *c 0.9f yib id i
(21)
where: a m = max(a 1, a 2, λa 4)
λ = min 1,
2 X 1 + 1 − X
a 4 = 1 d cb fc 4 * N0 = portion of N*c acting over the column footprint N *c b d b id i fc c 4b fcd c N *c X = (d c + b fc) 2 Ôf bd ib i =
Ôf b = min Ô0.85f ′ c
A 2 , Ô2f ′ c d ib i
a 5 = b fc + d c The concatenation of the three design models (Cantilever, Fling and Murray--Stockwell Models) is achieved in the calculation of am. The Cantilever Model is the governing criteria in the case am equals either a1 or a 2. In the case am is equal to λa 4 the Fling Model wouldbe governing if λ equals1or Murray--Stockwell Model would be governing if λ is less than 1. The use of λ leads to the selection of the thinner plate obtained by using the Fling Model and Murray--Stockwell Model in order not to loose the economy in design of the latter model in the case of lightly loaded columns. Recalling the description of Murray-- Stockwell Model no refinement in the calculation of A H is implemented in equation (21). It is interesting to note how this approach provides a more mathematical definitionof lightlyloadedcolumn where a column is said to be lightly loaded if its λ is less than 1, or equivalently if its X is less than (4 ∕5) 2 = 0.64. The expression of the plate thickness of Fling Model, re--derived in [42], is simplified by Thornton in [43] in order to reduce the complexity of the yield line solution. His simplification introduces an approximation in the value of a4 with an error of 0% (unconservative) and 17.7% (conservative) for values of d c∕b fc ranging from 3/4 to 3. The value of N *0 represents the portion of the total axial load N*c acting over the column footprint (d cb fc) under the assumption of uniform bearing pressure underthe base plate. Murray--Stockwell Model is concatenated in equation (21) to carry a design axial load equalto N *0 (noton N *c) over the assumedH--shaped bearing area inside the column footprint.
d cb fc d ib i b b 5 5 Table 2 Murray--Stockwell Model (refer to Figs. 4, 6, 7, 8, 11, 12, 13 and 14 for the definition of the notation)
= a2Ô4 f N *0 = a2Ô4 f
N *c
a3
SECTION
A (1) 1
H--shaped section [21]
b fcd c
(d c + b fc) − (d c + b fc) 2 − 4A H 4
2b fca 3 + 2a 3(d c − 2a 3)
Channel [26]
b fcd c
2b fca 3 + (d c − 2a 3)a 3
RHS SHS [21][26]
b cd c
(2b fc + d c) − (2b fc + d c) 2 − 8A H 4 (d c + b c) − (d c + b c) 2 − 4A H 4
CHS [21][26]
4.2.5.
π
d 20 4
d o − d 2o − 4A H∕π 2
Eurocode 3 Model
Clause 6.11 and Annex L of Eurocode 3 deal with the design of base plates. [23]
9
A H
d cb c − (d c − 2a 3)(b c − 2a 3) = 2(d c + b c)a3 − 4a 23
π(d 2o − d 23)∕4 where :
= π(doa 3 − a 23 ) d 3 = d o − 2a 3
Requirement of the EC3 is to provide a base plate adequate to distribute the compression column load over an assumed bearing area. The EC3 Model assumes an H--shaped bearing area as shown in Fig. 15(a). It requires that the pressure
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
assumed to be transferred at the interface base plate/foundation should not exceed the bearing strength of the joint f j.EC3 and the width of the bearing area should not exceed c calculated as follows: c = t i
c
c
f yi
3f j.EC3γ MO
(22)
c
c
(b) Short Projection
where: f j.EC3 = bearing strength of the joint
Figure 15 Assumed bearing pressure distributions specified in EC3 [23]
= β jk jf cd
β j = 2/3 provided that the characteristic strength of the grout is not less than 0.2 times the characteristic strength of the concretefoundation and the thickness of the grout is not greater than 0.2 timesthesmallest width ofthe steelbaseplate k j = concentration factor and may be taken as 1 or
N *c
h
a 1 = mina + 2a r, 5a, a + h, 5b1 ≥ a f cd = design value of the concrete cylinder compressive strength = f ck∕γ c f ck = characteristic concrete cylinder compressive strength (in accordance with Eurocode 2) γ c = partial safety factor for concrete material properties (in accordance with Eurocode 2) γ MO = 1.1 (boxed value from Table 1 of [23]) In the case of large or short projections the bearing area should be calculated as shown in Figs. 15(b) and (c). [23] [23] requires that the resistance moment m Rd per unit length ofa yieldlinein thebaseplate should be taken as: m Rd =
(23)
6γ MO
No specific expression for the sizing of the steel base plate are provided. N *c
≤ c
c
c
≤ c
c c
Bearing area
≤ c (a) General Case
10
This area not included in bearing area
Elevation
a1
b1
b
b 1 = minb + 2b r, 5b, b + h, 5a1 ≥ b
t 2i f yi
Baseplate
Concrete foundation
a 1b 1 ab a 1 and b 1 = dimensions of the effective area as shown in Fig. 16 otherwise as
(c) Large Projection
br ar
a
Plan
Figure 16 Column base layout [23] 4.3. 4.3.1.
RECOMMENDED MODEL Design considerations
The recommended design model is a modified version of the one proposed by Thornton in [43] and also adjusted to suit Australian Codes AS 3600 [10] and AS 4100 [11]. The Thornton Model is currently recommended by the AISC(US) Manual [5]. Unfortunately the Thornton Model presented in [5], [42] and [43] is suitable for the design of H--shaped columns only. His formulation has been here modified for H--shaped sections and extended for channels and hollows sections adopting a similar approach as in [43] which is outlined in Section 10. The modification to the Thornton Model introduced here regards the manner in which Murray--Stockwell Model is implemented. It is in the authors’ opinion that the calculation of A H and consequently of λ (refer to the literature review for further details regarding the notation) should be calculated based on N*c (total axial compression load) and not N *0 (portion of the total load N *c acting over the column footprint under the assumption of uniform bearing pressure). This intends to ensure that Murray--Stockwell Model would govern the design only for base plates of similar dimensions to the onesof the connected columns andfor lightlyloaded columns, which represents the actual base plate layout for which the model has been developed. The design would then be based on only one assumed pressure STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
distribution. Calculating A H based on N *0 could lead to the design situation for lightly loaded columns where the plate thickness is governed by Murray--Stockwell Model evenfor plate dimensions larger thanthose of the connected columns as the model would select the thinner plate between the ones calculated with Fling Model and with Murray--Stockwell Model. It is interesting to note how the assumed bearing area (H--shaped in the case of H--shaped column sections) could extend also beyond the footprint of the column section as shown in Fig. 17 in the case of H--shaped sections and hollow sections. [34] No specific design guidelines are provided in [34]. A similar pressure ditribution is considered in the Eurocode 3 Model. [23] Nevertheless in the recommended model the application of Murray--Stockwell Model is always carried out based on assumed bearing areas inside the column footprint even for base plates with dimensions greater than the column’s depth and width as other bearing distributions need to be validated by testings.
a
a a a
a
b
b
Design Concrete Bearing Strength
The maximum bearing strength of the concrete Ôf b is determined in accordance with Clause 12.3 of AS 3600 [10].
Ôf b = min Ô0.85f ′ c
b
4.3.4.
A 2 , Ô2f ′ c A 1
(26)
Steel Base Plate Design
The base plate thickness required to resist a certain design axial compression N*c is calculated as follow:
Design criteria
There are two different design scenarios which are considered here: the column is prepared for full contact in accordance with Clause 14.4.4.2 of AS 4100 [11] and the axial compression may be assumed to be transferred by bearing. Design requirements are as follows: N des.c = [ ÔN c ; ÔNs] min ≥ N *c
It is interesting to note from equation (26) that increasing the supplementary area A 2 increases the concrete confinement which yields larger design capacities ÔN c. The loss of bearing area due to the presence of the anchor bolt holes is normally ignored. [21]
Figure 17 Possible assumed bearing areas (Ref. [34])
the end of the column is not prepared for full contact and the welds shall have sufficient strength to carry the axial load. The design requirements are as follows:
11
4.3.3.
ÔN c = Ô f b A i
b b
4.3.2.
N*c = design axial compression load
The axial capacity of the concrete foundation ÔN c is then obtained multiplying the maximum concrete bearingstrength Ôf b bythe base platearea A i asfollows:
b b
where: Ndes.c = design capacity of the base plate connection subject to axial compression ÔN c = design axial capacity of the concrete foundation ÔN s = design axial capacity of the steel base plate ÔN w = design axial capacity of the weld connecting the base plate to the column section
where: Ô = 0.6 A 1 = b id i
a
Ineffective areas
b
N des.c = [ ÔN c ; ÔN s ; ÔN w] min ≥ N *c (25)
(24)
t i = a m
2N *c 0.9f yi d i b i
(27)
where: a m = max(a 1, a 2, λa 4)
λ = min 1, k
X 1 + 1 − X
X = YN *c a 1, a 2, a 4, k and Y are tabulated in Table 3. When X is greater than 1, λ should be taken as 1.
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Table 3 Values for the design and check specified by the recommended model for axial compression. Section
a1
a4
a2
H--shaped sections
d i − 0.95d c b i − 0.80b fc 2 2
dcbfc
Channels
d i − 0.95d c b i − 0.80b fc 2 2
2d cbfc
RHS
d i − 0.95d c b i − 0.95b c 2 2
SHS
d i − 0.95b c b i − 0.95b c 2 2
CHS
d i − 0.80d 0 b i − 0.80d o 2 2
3 2d ib i 23
ÔN s =
2 2a′ m
a4
λ
2 − 1 0.9f yid ib i
This model is applicable to column sections as outlined in Table 3 with the exception of H--shaped sections for which b fc∕2 is greater than d c as a different yield line pattern from those considered would occur. Weld design at the column base
The design of the weld at the base of the column is carried out in accordance with Clause 9.7.3.10 of AS 4100. [11] The weld is designed as a fillet weld and its design capacity ÔN w is calculated as follows: ÔN w = Ôv wL w = Ô 0.6f uwt tk rL w
(29)
where: Ôv w = design capacity of the fillet weld per unit length Ô = 0.8 for all SP welds except longitudinal fillet welds on RHS/SHS with t < 3 mm (Table 3.4 of AS 4100) 0.7 for all longitudinal SP fillet on RHS/SHS with t < 3 mm (Table 3.4 of AS 4100)
12
d ib i d cb fc
8N *c Ôf ba 25
2b fc + d c
4N *c Ôf ba 25
b c + d c
3 d ib i 2 bc
4N *c Ôf ba 25
2b c
2 d ib i d0
4N *c Ôf bπd 20
−
1.7
2 3
a 1, a 2, a 4, k and Y are tabulated in Table 3.
4.3.5.
b fc + d c
3 2
d ib i d cb fc
0.6 for all GP welds (Table 3.4 of AS 4100) f uw = nominal tensile strength of weld metal (Table 9.7.3.10(1) of AS 4100) t t = design throat thickness k r = 1 (reduction factor to account for length of welded lap connection) L w = total length of fillet weld Refer to Section 13. for tabulated values of the design capacity of fillet welds Ô v w.
5. AXIAL TENSION 5.1. INTRODUCTION
2 k a4 λ′ = max 1, 12 k t i Y a′ m = max a 1, a 2,
2
d0
where:
a5
4N*c Ôf ba 25
bc 3
(28)
Y
d ib i d cb fc
4
Thicknesses of base plates with dimensions similar to those of the connected column section calculated with equation (27) might be quite thin, especially in the case of lighlty loaded columns (where Murray--Stockwell Model applies). It is therefore recommended to specify plate thicknesses not less than 6mm thick for general purposes and not less than 10mm for industrial purposes. Similarly a procedure to evaluate/check the capacity of an existing plate is carried out as follows: 0.9f yi d ib i t 2i
k
There is notmuch guidance available in literaturefor the design of unstiffened base plates subject to uplift. The literature presented here outlines the available guidelines for the design of base plates and of anchor bolts. Two models presented here for the design of base platesforhollowsections,whicharetheIWIMMModel (named here after its authors) and Packer--Birkemoe Model, were firstly derived for bolted connections between hollow sections. [37] and [36] suggest their suitability also for the design of base plates. These models include also guidelines for determining the required number of anchor bolts. Such guidelines are incorporated in the literaturereviewfor the design of the steel base plates as their application is only suitable for the particular base plate model they refer to and as they do not account for the interaction between the anchor boltsand the concrete foundation, which is dealt with in the literature review on anchor bolts. 5.2.
BASE PLATE DESIGN -- LITERATURE REVIEW
The models presented here differ for their assumptions regarding the failure modes investigated. It is interesting to note that the design guidelines currently available deal with a limited number of base plate layouts. For each model outlined here, the column sections and the number of bolts considered by the model are specified after the model name.
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
5.2.1.
Murray Model (H--shaped sections with 2 bolts)
In [32] Murray presents a design procedure for base plates of lightly loaded H - shaped columns with only two anchor bolts subject to uplift. He also notes that to his knowledge no studies have been published on the design of lightly loaded column base plate subjected to uplift loading prior to his [32]. His design model is based on yield line analysis and the yield line pattern assumed is shown in Fig. 18. The expressions of the internal and external work can be written as follows:
experimental results, which consisted of 4 base plate specimens with dimensions ranging from 8” x 6” (203.2 x 152.4 mm) to 12” x 8” (304.8 x 203.2 mm) and thicknesses varying from 0.364 in. (9.246 mm) to 0.377 in. (9.576 mm). This method is included in the design model recommended by the current AISC(US) Manual [5]. b fc∕2
s g∕2 s g∕2
b fc∕2 b′
d c∕2
W i = Ôm p 2 2b′ + 1 4 2 b fc b′ b fc
= Ômp
4b′ 2 + 2b 2fc
b′ d c∕2 b′ = 2 (b fc∕2) ≤ d c∕2
(30)
b′b fc
1 unit
N *ts g N * s g 2 = W e = t 2 2 b fc 2b fc
b fc∕2
(31) b′
N*t = design tension axial load
b′ Figure 18 Murray Model Assumed Yield Line Patterns (Ref. [32])
s g and b′ = as defined in Fig. 18
5.2.2.
where:
Equating the external and internal work the expression of Ôm p can be written as follows: Ôm p =
b′b fc N *t s g 2 b fc 4b′ 2 + 2b 2fc
(32)
The value of b′ which maximises the required plate plastic capacityis obtaineddifferentiating equation(32) for b′ and is equal to: b′ =
b fc
2
Tensile Cantilever Model (Generic Model)
Tensile Cantilever Method, as it is referred here, assumes that the tension in the anchor bolts spreads out to act over an effective width of plate (be) which is assumed to act as a cantilever in bending ignoring any stiffening action of the column flanges.
1
(33)
1 bt
The presence of the flanges requires b′ to remain always less orequal to d c∕2 and therefore the value of b′ which maximises the plate plastic capacity varies depending upon the column cross--sectional geometry as follows: b′ = b′ =
b fc
b fc
d c ≤ 2 2
b d c d for fc ≥ c 2 2 2
for
2
(34) (35)
The minimum plate thicknessesrequired under a certain axial load N*t are obtained substituting equations (34) and (35) into equation (32) as shown below: t i ≥
t i ≥
N *t s g 2 b d for fc ≤ c 2 2 0.9f yib fc4
N *t s gd c b d for fc ≥ c 2 2 2 2 0.9f yi(d c + 2b fc)
13
dh
bt
be Figure 19 Tensile Cantilever Model (Ref. [26]) It can be applied to generic base plate layouts. Nevertheless it provides conservative designs as it ignores the two way action of the base plates. Reference [47] suggests a 45 degree angle of dispersion as shown in Fig. 19. This is based on considerations of elastic plate theory as described in reference [13]. The design moment and the design moment capacityare then calculated as:
(36)
N * m *t = n t b t b
(37)
Murray carried out a finite element study to investigate the adequacy of the proposed model. He also validated the reliability of equations (36) and (37) using limited
bt
Ôm s =
0.9b e t 2i f yi 4
(38)
(39)
where: m *t = design moment per unit width due to N *t
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
n b = number of anchor bolts
a2 a1
b t =distancefromfaceofwebtoanchorboltlocation d h = diameter of the bolt hole
do N*t
b e = 2b t + d h
N*t
The axial capacity of the base plate can then be determined equating the design moment and the section moment capacity as follows: 0.9f yib et 2i n b Nt ≤ 4 bt *
(40)
or equivalently the minimum base plate thickness ti under a certain loading condition is calculated as: t i = 5.2.3.
4N *t b t 0.9f yi b e n b
The IWIMM Model has been named here after the initials of the authors of the model. [27] The model was firstly derived for the design of CHS bolted connections. [37] and [36] suggest its use also for the design of base plates of CHS columns. The base platelayout consideredby this model is shown in Fig. 20. The plate thickness is calculated based on the design axial tension load N*t as follows:
2N*t Ôf yi π f 3
(42)
where: Ô = 0.9 d 0 = outside diameter of a CHS t c = thickness of column section
f 3 = 1 k 3 + k 23 − 4k 1 2k 1 r k 1 = ln r 2 3
k 3 = k 1 + 2 d 0 + a 1 2 d − t c r 3 = 0 2 a 1 and a2 as defined in Fig. 20 [27] recommends to keep the value of a1 as small as possible, i.e. between 1.5df and 2d f (where d f is the nominal diameter of the bolts), while ensuring a minimum of 5 mm clearance between the nut face and the weld around the CHS. r 2 =
ti
Figure 20 Bolted CHS Flange--plate Connection (Ref. [36]) [27] also recommends to determine the number of required anchor bolts as follows:
(41)
IWIMM Model (CHS with varying number of bolts)
t i ≥
ti
n b ≥
N*t 1 1 − 1 + f 3 f ln r 1 ÔN tf 3 r2
(43)
where: Ô = 0.9 Ntf = nominal tensile capacity of the bolt d 0 + 2a 1 2 d r 2 = 0 + a 1 2 a 1 = a 2 This procedure does not verify the capacity of the concrete foundation and its interaction with the anchor bolts needs to be checked. Assumptions adopted by this model are an allowance for prying action equal to 1/3 of the ultimate capacity of the anchor bolt (at ultimate state), a continuous base plate, a symmetric arrangement of the bolts around the column profile and a weld capacity able to develop the full yield strength of the CHS. [28] notes that adopting the above prying coefficient for the bolted CHS connection in the base plate design is conservativeduetothegreaterflexibilityoftheconcrete foundation when compared to the steel to steel connection. [36] r 1 =
5.2.4.
Packer--Birkemoe Model (RHS with varying number of bolts)
The Packer--Birkemoe Model is here named after the authors of the model. [36] This model deals with base plate for RHS as shown in Fig. 21 and it has been validated only for base plates with thickness varying between 12mm and 26mm. The model includes prying effects in the design procedure. The prying action decreases while increasing a2 asshowninFig.21.Thevalueof a2 should be kept less or equal to 1.25 a1, as nobenefitin the base plate performance would be provided beyond such value. a1 is defined as the distance between the bolt line and the face of the hollow section. Generally 4--5 bolt diameters are used as spacing of the bolts s p but shorter spacing are also possible. Based on the design loads the required number of anchor bolts should be calculated assuming that the
14
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
prying action absorbs about 20 - 40% of the anchor bolt capacity. The coefficient δ is thencalculated as follows: d δ = 1 − s h
p
(44)
where: s p = bolt pitch as defined in Fig. 21 The designer should then select a preliminary plate thickness in the following range:
KN *b ≤ t i ≤ KN *b 1 + δ
(45)
where:
The value of α previously calculated in equation (46) does not have to equal the value of α calculated from equation (48) as the former assumes the bolts to be loaded to their full tensile capacity. It interesting to note how equation (48) provides an estimate of the prying action present in the base plate. a2 a1 N*t tc a3 a4
= = = = =
=
4a 10 3 K = 3 Ôf yis p
N*t
sp
(where f yi is in MPa)
sp
Figure 21 Packer--Birkemoe Model (Ref. [36])
a 3 = a 1 − d f ∕2 + t c N*b = design axial tension load carried by one bolt N* = nt b
5.2.5.
d f = nominal anchor bolt diameter
The Eurocode 3 does not provide a specific design procedure for the design of base plates subject to tension. Nevertheless it provides very useful guidelines for the design of bolted beam--to--column connections (Appendix J.3 of [23]) which can be adapted for the design of base plates considering all anchor bolts as bolts on the tension side of the beam--to--column connection. The design of the end plate or of the column flange of the beam--to--column connection is carried out in terms of equivalent T--stubs as shown in Fig. 22.
The value of α represents the ratio of the bending moment per unit width of plate at the bolt line to the bending moment per unit width at the inner hogging plastic hinge. In the case of a rigid base plate α is equal to 0 while for a flexible base plate with plastic hinges forming at both the bolt line and at the inner face of the column (see Fig. 21) α is equal to 1. From equilibrium, the value α for preliminary base plate layout is calculated as follows:
α =
K ÔNtf − 1 t 2i
a 2 + d f ∕2 δ(a 2 + a 1 + t c)
(46)
Eurocode 3 Model (H--shaped sections with varying number of bolts)
0.8a 2 a
e m
α should be taken as 0 if its value calculated with equation (46) is negative. The capacity of the steel base plate is then calculated as follows: ÔN t =
t 2i (1 + δα)n b
K
where:
α =
l
e m
0.8r r
t f
(48) e min Figure 22 T--stub connection in EC3 (Ref. [23])
KN *t − 1 1 t 2i n b δ
d a 4 = min 1.25a 1, a 2 + f 2
15
t f
e min
ÔN t calculated with equation (47) must be greater than N*t . The actual tension in one bolt, including prying effects, is determined as follows:
a N δα N *b ≈ n t 1 + a 3 4 1 + δα b
m
(47)
where: ÔN t = axial tension capacity of the base plate
*
e
EC3 considers that the capacity of a T--stub may be governed by the resistence of either the flange, or the bolts, or the web or the weld between flange and web of T--stub. The failure modes considered are three as shown in Fig. 23. The axial capacity is calculated as follows:
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
F t.Rd = minF t.Rd1, F t.Rd2, F t.Rd3
(49)
where:
BF
t.Rd
4M pl.Rd m 2M pl.Rd + nΣB t.Rd F t.Rd2 = m + n F t.Rd3 = Σ B t.Rd
Mode 2
F t.Rd1 =
2λ 1 + 2 λ
Mode 1
0.25lt 2f f y M pl.Rd = γ MO n = e min ≤ 1.25m l = equivalent effective length calculated in equations (50), (51), (52) and (53)
ΣB t.Rd = tensile capacity of bolt group γ MO = partial safety factor = 1.10 (boxed value from Table 1 of [23]) F t.Rd1, F t.Rd2 and F t.Rd3 = tensile capacities of the T-- stub based on failure modes 1, 2 and 3 respectively Ft Mode 1: Complete flange yielding
Q
Ft + Q 2
Ft + Q 2
Q
4M plRd m
B
t
t
l t 2f f y∕γ MO m
B
t.Rd
Figure 24 Prying action in T--stub for the three failure modes considered in (Ref. [23]) The tension zone of the end plate should be considered to act as a series of equivalent T--stubs with a total length equal to the total effective length of the bolt pattern in the tension zone, as shown in Fig. 26.[23] The length to be utilised in the design of the equivalent T--stub is calculated as follows: for bolts outside the tension flange of the beam
l eff.b = min(αm, 2πm)
B ∕2 B ∕2
t.Rd
=
β
(50)
for first row of bolts below the tension flange of the beam Mode 2: Bolt failure with flange yielding
(51)
for other inner bolts l eff.c = min p,4m + 1.25e, 2πm
(52)
for other end bolts Q
l eff.d=min(0.5p+2m+0.625e, 4m+1.25e, 2πm) (53)
Ft Mode 3: Bolt failure
B ∕2 B ∕2 t
λ = n ∕m
β =
2
1
2λ 1 + 2 λ
l eff.a = min 0.5b p, 0.5w+2m x+0.625e x, 4m x+1.25ex, 2πm x)
Ft
Q
Mode 3
1
t
where: α = as defined in Fig. 27 It is interesting to note that the failure modes considered for example by equations (52) and (53) are the same as those considered to evaluate the capacity of an unstiffened flange. The yield line patterns of such failure modes are shown in Fig. 25.
Figure 23 Failure modes of a T--stub flange (Ref. [23]) It is interesting to note that the amount of prying action foracertainbaseplatelayoutcanbeobtainedastheratio F t.Rd∕ΣB t.Rd as shown in Fig. 24.
16
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
p
p
2π 65.5
1.4
e m
5
4.5 4.75 4.45
α
1.3 1.2
Centreline of web (a) Combined bolt group action
λ 2 1.1 1.0 0.9
Centreline of web (b) Separate bolt patterns
0.8 0.7 0.6
Centreline of web
0.5
(c) Circles around each bolt
Figure 25 Yield line patterns for unstiffened flange (Ref. [23]) bp w
Equivalent T--stub for extension
ex mx
0.4 0.3 0.2 0.1 0
l eff.a
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
ex mx l eff.b
p
λ 1 =
l eff.c
λ 2 =
p
e m e m bp
Portion between flanges b p∕2
l eff.a
l eff.a
Transformation of extension to equivalent T--stub Figure 26 Effective lengths of equivalent T--stub flanges representing an end plate (Ref. [23])
17
m1
m 1 + e
m2
m2
m 1 + e e
l eff.d
0.9 λ1
m1
Figure 27 Value of Effective lengths of α to calculate equivalent T--stub flanges (Ref. [23]) 5.3.
DESIGN OF ANCHOR BOLTS LITERATURE REVIEW
Available design guidelines regarding the behaviour of anchor bolts in tension distinguish between the behaviour of anchor bolts with an anchor head and of hooked anchor bolts and therefore these will be discussed here separately. For the purpose of this paper an anchor head is defined as a nut, flat washer, plate, or bolt head or other steel component used to transmit anchor loads from the tensile stress component to the concrete by bearing. [2] 5.3.1.
Anchor bolts with anchor head
The first detailedguidance on the design of anchor bolts is provided by the American Concrete Institute Committee 349 in 1976 in [3]. These recommendations are produced for the design of nuclear safety related structures. Some of the ACI Committee 349 members, very active in the preparation of [3], publish an article [17] where the guidelines provided in [3] are modified to suit concrete structures in general.
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
The design criteria at the base of [2] and of [17] is that anchor bolts should be designed to fail in a ductile manner, therefore the anchor bolt should reach yielding prior to the concrete brittle failure. This is achieved by ensuring that the calculated concrete strength exceeds the minimum specified tensile strength of the steel. [2][17] Typical brittle failure of an isolated anchor bolt is by pulling out ofa concreteconeradiating out at 45degrees from the bottom of the anchor as shown in Fig. 28. [2] and [17] recommend to calculate its nominal concrete
that the thickness of the anchor head is at least 1.0 times the greatest dimension from the outermost bearing edge of the anchor head to the face of the tensile stress component and that the bearing area of the anchor head is approximately evenly distributed around the perimeter of the tensile stress component. [2] The placing of washers or plates above the bolt head to increase the concrete pull--out capacity should be avoided asit onlyspreadsthe failure coneawayfromthe bolt--line which may cause overlapping of cones with adjacent anchors or edge distance problems. [31]
pull--out capacity based on the tensile strength Ô4 f ′ c
(where f ′ c is in psi) or Ô 0.33 f ′ c (where f ′ c is in MPa) acting over an effective area which is the projected area of the concrete failure cone. In both [3] and [17] it is recommended to use a capacity reductionfactorof0.65inthecalculationoftheconcrete cone capacity, which canbe increased to 0.85 in the case the anchor head is beyond the far face reinforcement. The value of 0.65 applies to the case of an anchor bolt in plain concrete. This intends to be a simplification of a very complex problem. [3][17] In the current version of ACI349 [2] the capacity reduction factor is equal to 0.65 unless the embedment is anchored either beyond the far face reinforcement, or in a compression zone or in a tension zone where the concrete tension stress (based on an uncracked section) at the concrete surface is less than the tensile strength of the concrete 0.4 f ′ c subjected to strength load combinations calculated in accordance with current loading codes (i.e. AS1170.0 [8]) in which cases a capacity reduction factor of 0.85 can be used. [2] An embedment is defined in [2] as that steel component embeddedin the concrete used to transmit applied loads to the concrete structure. The ACI Committee 349 recognises that there is notsufficient datato define more accurate values for the strength reduction factor. [2] Experimental results have generally verified the results of this approach. [31]
L d 45 o
L d Failure plane
Projected surface
Figure 28 Concrete failure cone (Ref. [26]) If reinforcement in the foundation is extended into the area of the failure cone additional strength would be present in practice since the nominal capacity of the failure cone is based on the strength of unreinforced concrete. The concrete pull--out capacity of a bolt group is calculated as the average concrete tensile strength Ô0.33 f ′ c times the effective tensile area of the bolt group. This effective area is calculated as the sum of the projected areas of each anchor part of the bolt group if these projected areas do not overlap; when overlapping occurs overlappedareas shouldbe considered only once in the calculation of the effective tensile area, thus leading to a smaller concrete pull--out capacity if compared to the sum of the concrete pull--out capacities of each anchor in the bolt group considered in isolation. [2][17]
The value of Ô 0.33 f ′ c represents an average value of the concrete stress on the projected area accounting for the stress distribution which occurs along the failure cone surface varying from zero at the concrete surface to a maximum at the bolt end. [31] In calculating the projected area of the failure cone the area of the anchor head should be disregarded as the failure cone initiates at the outside periphery of the anchor head. [2] Experimental results have shown that the head of a standard bolt, without a plate or washer, is able to develop the full tensile strength of the bolt provided, as specified in [2], that there is a minimum gross bearing area of at least 2.5 times the tensile stress area of the anchor bolt and provided there is sufficient side cover,
18
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Tension Force s s
L d
Transverse splitting
L d
2 cos −1
s 2L d
πL 2d
Shaded = π L 2d − + s2 360 0 Area (a) Two Intersecting Failure Cones
2 − s4
L 2d
− L d L d
s 2
=
L d
2 cos −1
Area = π L 2d −
s 2L d
360 0
πL 2d
+ L d + s2
2 L 2d − s 4
Circle -- Sector + Triangle (b) Failure Cone Near an Edge
(Note: the inverse cosine term listed in the equations is in degrees) Figure 29 Calculation of the projected area of two intersecting failure cones or one failure cone near an edge (Ref. [30]) Simple procedures to calculate the effective tensile areas of bolt groups are provided in [30], i.e. the procedure to calculate two intersecting cones is shown in Fig. 29. [30] Depending upon the bolt group layout other possible failure modes could take place such as the one shown in Fig. 30 where an entire part of the concrete foundation would pull--out. In such cases the effective tensile area should be calculated selecting the smallest projected area due to the possible concrete failure surfaces as shown in Fig. 30. A similar average tensile strength as in the case of the pull-- out cones can be adopted.[2][17]
Figure 31 Transverse splitting failure mode (Ref. [2]) It is interestingto note that in the case of shallow anchor bolts the angle at the bolt head formed by the failure cone tends to increase from 90 degrees to 120 degrees. An anchor bolt is classified as shallow when its length is less than 5in. (127 mm). Nevertheless for design purposes caution should be applied is using angles greater than 90 degrees as cracks might be present at the concretesurface.Itisrecommendednotuseanglesother than 90 degrees. [2][17] The previous considerations assume the concrete element to be stress--free and only subjected to the anchor bolts loading. [2] and [17] consider the case when there is a state of biaxial compression and tension in the plane of the concrete. The former loading condition would be beneficial to the anchor bolt’s strength while the latter loading state would lead to a significantly decrease in strength. Nevertheless, it is in the opinion of the ACI 349 Committee that a failure cone angle of 90 degrees can still be utilised as it is assumed that any cracking would be controlled by the main reinforcement designed in accordance with current concrete codes, i.e. AS 3600 [10]. The design procedure proposed by ACI 349 and [17] is also recommended by DeWolf in [21]. [21] notes that the use of cored holes, such as shown in Fig. 32, should not reduce the anchorage capacity based on the failure cone,provided that the coredhole does not extendnear thebottom of the bolt.This situation should be avoided if the dimensions shown in Fig. 32 are followed. [26]
Tension Force
Figure 30 Potential Failure Mode with limited depth (Ref. [2]) Transverse splitting is another failure mode which can occur between anchor heads of an anchor bolt group when their centre--to--centre spacing is less than the anchor bolt depth and is shown in Fig. 31. This failure modeoccursat a loadsimilar tothe one required tocause a pull--out cone failure in uncracked concrete and therefore no additional design checks need to be considered. [2][17]
19
Projection
3d f but ≥ 75mm
L d
d f
Figure 32 Suggested layout for Cored Holes to Permit Minor Adjustments in Position on Site (Ref. [26])
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Ô = 0.65 in Ref. [3],
45 o
45
Failure surface
= 0.85 in Refs. [2] and [17] Adopting the capacity reduction factor Ô equal to 0.85 the minimum side cover to avoid lateral bursting of the concrete can be calculated as follows:
Blow out cone
a e = d f
o
Figure 33 Failure Surface of Blow--out Cone due to Lateral Bursting of the Concrete (Ref. [31]) Lateral bursting of the concrete can occur when an anchor bolt is located close to the concrete edge as shown in Fig. 33, which is caused by a lateral force present at the bolt head location. This lateral force may be conservatively assumed to be one--fourth of the nominal tensile capacityof the anchor bolt for conventional anchor heads which can be calculatedinaccordancewithClause9.3.2.2ofAS4100 [11] as follows: Ntf = A sf uf = 0.75A 0f uf = 0.75
d 2f π 4
d f π 2
= shank area 4 f uf = minimum tensile strength of a bolt
The failure surface has the shape of a cone which radiates at 45 degrees from the anchor head towards the concreteedge. Theconcrete capacityis calculated as the average concrete tensile strength Ô0.33 f ′ c applied over the projected cone area as follows: [2][3][17] ÔN c.lat = Ô0.33 f ′ c π a 2e
(55)
where: Ô = 0.65 in Ref. [3], 0.85 in Refs. [2] and [17] ÔN c.lat = lateral bursting capacity of the concrete a e = side cover Equating the assumed lateral force (equal to 0.25 Ntf ) to the concrete lateral bursting capacity allows to express the minimum required side cover as a function of both the concrete and anchor bolt strengths as shown below:
0.25N tf = Ô Nc.lat = Ô0.33 f ′c π a 2e
(56)
and solving equation (56) for ae yields: a e = d f where:
20
f uf
Ô7 f ′ c
f uf
6 f ′ c
(58)
Equation (58) has also been recommended in [26] and [47]. Tension Force
Potential Failure Zone
Spiral reinforcement
f uf (54)
where: A s = tensile stress area in accordance with AS1275 [9] and conservatively approximated with 0.75 A 0 A 0 =
(57)
Figure 34 Reinforcement Against Lateral Bursting of Concrete Foundation (Ref. [2]) Based on the guidelines provided in reference [3], simplified design guidelines regarding minimum embedment lengths and minimum edge distances are presented in reference [39]. These minimum embedment lengths are calculated with an additional safety factor of 1.33 when compared to the guidelines presented in reference [3]. These simplified guidelines are as follows: for Grade 250 bars and Grade 4.6 bolts: L d ≥ 12d f a e = min(100, 5df ) for Grade 8.8 bolts: L d ≥ 17d f a e = min(100, 7df ) where: L d = minimum embedment length These minimum embedment lengths and edge distances have also been recommended in references [18], [21] and [26]. Reinforcement needs to be specified in the case anchor bolts are located too close to a concrete edge (the edge distance ae is less than the one required by equation (58)) or their embedment length is less than the one required to develop the bolt’s full tensile strength. Such reinforcement should be designed and located to intersect potential cracks ensuring full development length of the reinforcement on both sides of such cracks. The placement of the reinforcement should be concentric with the tensile stress field. [2]
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
In the specific case of insufficient embedment length a possible reinforcement layout to enhance the concrete pull--out capacity is detailed in Fig. 35 using hairpin reinforcement. The hairpins need to be placed as specified in Fig. 35 in order to effectively intercept potential failure planes. Other reinforcement configurations can be specified in accordance with AS 3600 while still complying with the specifications previously outlined for hairpin reinforcement to consider the reinforcement to be effective. These specifications are the maximum distance from the anchor head and the minimum embedment length equal to 8 reinforcement diameters. Tension Force 8x diameter of the hairpin reinforcement
L d
Development length from AS3600
L d 3
Maximum distance from anchor head for reinforcement to be considered effective
L d 3
Figure 35 Possible Placement of Reinforcement for Direct Tension (Ref. [2]) In the case of insufficient side cover ae there are no experimental results to validate a design procedure to include reinforcement to avoid lateral bursting of the concrete. The ACI 349 Committee recommends the use of spiral reinforcement as shown in Fig. 34 while also suggesting to refer to accepted practices forprestressing anchorages to resist the lateral bursting force. [2] [2] and [17] recommend that if proper anchorage of the reinforcement cannot be accomplished in the available dimensions, the anchorage configuration should be changed. Hooked bars
There are different opinions regarding the ability of hooked anchor bolts to carry tensile loading. Some authors do not recommend to use them to resist uplift loads, while others have provided some design guidelines. The major concern regarding the use of hooked bars in tension is that they tend to fail by straightening and pulling out of the concrete as shown by research carried out by the PCI.[24] [24] and [31] discuss the behaviour of smooth anchor bolts and recommend to use hooked anchor bolts with a bearing head as smooth bars are less able to develop their strength along their length than deformed bars. [24] recommends to use the following formula to determine thepull--outcapacity of a hookedanchorbolt:
21
(59)
where: Ô = 0.80 (as recommended in [26]) ÔN th = tensile capacity of a hooked bar d f = nominal diameter of the hooked bar L h = length of the hook DeWolf in [22] recommends to use hooked anchor bolts only under compressive axial loading, and where no fixity is needed at the base except during erection. Even for this case he recommends to design the hook to resist halfthedesigntensilecapacityoftheboltusingequation (59). He also recommends to use anchor bolts with a more positive anchorage which is formed when bolts or rods with threads and nut are used. [22] Similar design considerations are presented in reference [47]. The recommendations of the AISC(US) Manuals have changed over time. In reference [6]the design of hooked anchor rods under tension is recommendedto be carried out based on the design procedure presented in [24] as outlined in equation (59) while in reference [5] the use of hooked anchor rods is recommended only for axially loaded members subject to compression only. 5.4. 5.4.1.
Locate legs of hairpin reinforcement in this region
5.3.2.
ÔN th = 0.7f ′ cd f L h
RECOMMENDED MODEL Introduction
Available design guidelines have been included in the recommended design models where possible. Additional design models/provisions are here provided for those instances, to the knowledge of the authors, not covered by available design guidelines. Their use has been clearly stated and their derivations are illustrated in Section 11. It is interesting to note that depending upon the magnitude of the plate flexural deformation and the bolt elongation which occur in the loaded base plate connection, a prying action might be present. The possible collapse mechanisms which can occur are similar to those which can occur in bolted connections. These are shown in Fig. 36. *
Nb
N *t
N *b N*p
N*t
N *b
N *t
N*p
Schematic failure modes
Bending moment diagrams showing plastic hinges Figure 36 Possible plate deformations and anchor bolt elongations (modified from Ref.[13]) In the case the plate flexural deformationis smaller than the bolt elongationno prying action would take place as shown in Fig. 36(a). In the case the plate flexural
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
deformation is of similar or of greater magnitude as the bolt elongation, as shown in Fig. 36(b) and (c), prying actions N*p should be accounted for in the design. Possible bending moment diagram occurring in the plate in all three collapse mechanisms are also shown in Fig. 36. [13] For design purposes the use of a prying factor of 1.4 is conservatively recommended as suggested in [37] and [36]. 5.4.2.
ÔN tb =
Design Criteria
The recommended model for axial tension is based on the following design criteria: Ndes.t = [ ÔN t ; ÔN w ; Ô Ô pN tb] min ≥ N *t (60) with the following constraint to ensure a ductile failure of the anchorage system (connection of anchor bolt to concrete): ÔN cc > Ô N tb
(61)
and complying with the anchor bolts’ embedment lengths and concrete edge distances specified in Sections 5.4.5. and 5.4.6. and where: Ndes.t = design capacity of the base plate connection subject to axial tension ÔN t = design tensile axial capacity of the steel base plate ÔN w = design axial capacity of the weld connecting the base plate to the column ÔN tb = design capacity of the anchor bolt group under tension Ô p = 1/1.4 = 0.72 prying reduction factor as recommended in references [36] and [37] unless noted otherwise in 5.4.3. ÔN cc = design pull--out capacity of the concrete foundation N*t = design axial tension load 5.4.3.
Anchor bolt design
The tensile design capacity of the anchor bolt group ÔN tb is calculated in accordance with Clause 9.3.2.2 of AS4100 [11] as the sum of the design capacities of each single bolt ÔN tf . ÔN tb = n bÔN tf = n bÔ A sf uf
(62)
where: Ô = 0.8 Refer to Section 14. for tabulated values of the tensile capacities of anchor bolts. In the case the base plate is designed based on Packer--Birkemoe Model the preliminary number of bolts required is obtained from equation (62) which is then refined in the section describing the steel plate
22
design. Once the steel plate design is complete the capacity of the anchor bolt groups needs to be re--checked. The value of Ô p to be adopted in the Packer -- Birkemoe model is specified in equation (95). Inthecasethedesignofthebaseplateiscarriedoutbase on IWIMM Model (refer to Section 5.4.7.) the tensile design capacity of the anchor group should be calculated as follows: n bÔN tf 1 1 − 1 + f 3 f ln r 1 3 r2
(63)
where: Ô = 0.9 Ôp = 1 to be used in equation (60) as prying effects are already included in equation (63) d 0 + 2a 1 2 d r 2 = 0 + a 1 2 a 1 = a 2 (condition to apply equation (63)) r 1 =
f 3 = 1 k 3 + k 23 − 4k 1 2k 1 r k 1 = ln r 2 3
k 3 = k 1 + 2 d 0 + a 1 2 d − t c r 3 = 0 2 a 1, a 2 and d 0 are defined in Fig. 20 r 2 =
5.4.4.
Design of concrete pull--out capacity
The pull--out capacity of the concrete ÔN cc varies depending upon the anchor bolts layout and it can be calculated in accordance with AS 3600 as follows: ÔN cc = Ô 0.33 f ′ c A ps
(64)
where: Ô = 0.7 (based on Ô required for Clause 9.2.3 of AS 3600) A ps = effective projected area Equation (64) is similar to the expression provided in Clause 9.2.3 of AS 3600 to calculate the concrete capacity of a slab against punching shear, which involves a similar failure mechanism as the one of the pull--out cone.The value of β h tobecalculatedinClause 9.2.3 ofAS 3600would beequalto 1 astheshapeof the effective loaded area is a circle. AS 3600 recommends a strength reduction factor under shear of 0.7 (Table 2.3 of AS 3600). The capacities of a few common bolt layouts as shown in Fig. 37 are here outlined. [47]
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
L 1
L 2
a e = max 100, d f
s
Projected area
L 1
45 o
L 2
(a) Single Cone
(b) Two Intersecting Cones
L 4
f uf
6 f ′ c
(65)
Tabulated values of equation (65) are presented in Section 12. The following simplified expressions, which have been derived in Section 12., can be used in place of equation (65) leading to slightly more conservative side covers than those calculated with equation (65). for Grade 4.6 bolts and Grade 250 rods a e = 4 d f when f ′ c = 20, 25 and 32 MPa ≥ 100 when f ′c = 20, 25 and 32 MPa for Grade 8.8 bolts a e = 6 d f when f ′ c = 20 and 25 MPa = 5 d f when f ′ c = 32 MPa ≥ 100 when f ′c = 20, 25 and 32 MPa
(c) Four Intersecting
The requirement ofa minimum side cover of100 mm is based on recommendations of [21], [26] and [39].
Cones
s
5.4.6.
Minimum embedment lengths
The recommended minimum embedment length L d of an anchor bolt is determined in accordance with the design guidelines specified in [2] adjusted to suit AS 3600.
L 4 Figure 37 Common bolt layouts (Ref. [47])
ae
The effective projected areas of each anchor bolt layout shown in Fig. 37 is calculated as follows: A ps.1 = effective projected area of isolated anchor bolt (nooverlappingoffailurecones)asshowninFig. 37(a)
L d
= πL 21 A ps.2 = effective projected area of 2 anchor bolts with overlapping of their failure cones as shown in Fig. 37(b);
= π d 22 × 1 −
2 cos −1(s∕2L 2) 360
+ − ∕ s L 2 2 2
s 2 4
A ps.4 = effective projected area of 4 anchor bolts with overlapping of their failure cones. In this case each failure cone overlaps with allother 3 failure cones as shown in Fig. 37(c).
2 cos −1(s∕2L 4) = πd 0.75 − 360 + s2 L 24 − s 2∕4 + s 2∕4 where the inverse cosine term is in degrees. 2 4
5.4.5.
Concrete cover requirements
The cover requirements for an anchor bolt are determined in accordance with [2] and [17] in order to prevent lateral bursting of the concrete which can occur when a bolt is located close to a concrete edge as shown in Fig. 33. The minimum cover to be provided is calculated as follows: [17][2]
23
L h
Edge of Concrete Foundation
Figure 38 Hook, embedment lengths and edge distances for anchor bolts (Ref. [26]) The minimum embedment length L d for an isolated anchor bolt should be calculated as follows: (refer to Fig. 38) L d =
− d 2f + d2f + 4γ 2
≥ 100
(66)
where: Ô = 0.7 (based on Ô in Clause 9.2.3 of AS 3600) f uf A s γ= Ô0.33 f ′ c π Even if it hasbeen observed that for shallow anchors the angle at the bolt head formed by the concrete failure cone tends to increase from 90 degrees to 120 degrees (therefore increasing the concrete pull--out capacity) a minimumlimit of 100mm is here introduced in equation (66) as cracks might be present at the concrete surface. Refer to Section 12. for the derivation of equation (66) and of the simplified expressions shown below which can be used in place of equation (66). for Grade 4.6 bolts and Grade 250 rods
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s
L d = 9 d f when f ′ c = 20, 25 and 32MPa for Grade 8.8 bolts L d = 13 d f when f ′ c = 20 MPa = 12 d f when f ′ c = 25 MPa = 11 d f when f ′ c = 32 MPa
y
Hooked anchor bolts, as shown in Fig. 38, need to be detailed with a minimum embedment length as specified for boltswith an anchor head of same nominal diameter(specified by equation (66) or by its alternative simplified expressions) and with a minimum hook length calculated as follows:[24][26] L h ≥
A sf uf 0.7f ′ cd f
(67)
where: L h = hook length of anchor bolt
y
Figure 39 Yield line pattern -- H --shaped column section with 2 anchor bolts Theplatethicknessrequiredtoresistadesignaxialforce ÔN *t is calculated as follows: ÔN t = 0.9f yit 2i α
H--SHAPED COLUMN -- 2 anchor bolts
The yield line pattern considered by the recommended model is shown in Fig. 39 and is similar to the one considered in MurrayModel modified to account forthe reduction in plate capacity due to the anchor bolt holes.
24
t i ≥
N*t 0.9f yiα
y = min
Design of the Steel Base Plate
The recommended procedure to design or check the steel base plate varies depending upon the column section and number of bolts considered. Recommended models are illustrated below for the following combinations of column section and number of bolts: H--shaped column section - 2 anchor bolts (*) H--shaped column section - 4 anchor bolts (*) Channel - 1 anchor bolt (*) Channel - 2 anchor bolts (*) Hollow section (RHS, SHS, CHS) - 2 anchor bolts (*) Hollow section (RHS, SHS) -- 4 anchor bolts (*) Hollow section (CHS) - varying no. of anchor bolts (IWIMM Model described in the literature review) Hollow section (RHS) - varying no. of anchor bolts (Packer--Birkemoe Model described in the literature review) The derivation of the models marked with (*) is illustrated in Section 11. It is important to note that, similarly to Murray Model, in the case of open sections thederived models to determine the capacity of the steel base plate capacityaccountonly forthe strength of plate present inside the column footprint. The reduction in plate capacity due to the bolt hole has been included in the model. The yield line patterns considered for open sections are assumed to develop inside the internal faces of the column profile.
d c1 2
b fc
The anchorage length (embedment length and hook length) should be such as to prevent bond failure between the anchor bolt and concrete prior to yielding of the bolt. When possible, a more positive anchorage shouldbeadoptedattheendofthehook,forexampleby means of a nut. 5.4.7.
d c1 2
d c1 , 2
(68)
(69)
b fc1 − d h b fc1 2
(70)
where: ÔN t = axial tension capacity of the base plate b fc1 = width of the column flange ignoring web thickness = b fc − t w d c1 = clear depth between flanges (column depth ignoring thicknesses of flanges) t w = thickness of web d h = diameter of bolt hole
α =
2b2fc1 − 2b fc1d h + 4y 2
4sy y and s = as defined in Fig. 39 In this model the reduction in plate capacity due to the presenceofaboltholealongtheyieldlineperpendicular to the web has been included. Further reductions due to other yield lines intersecting bolt holes have not been considered as they are very unlikelyto occur and a more detailed analysisshould be carried out in such situation. The critical yield line pattern is a function of the value of y calculated from equation (70). To ensure that none of the oblique yield lines intersects the bolt hole, as assumed in the model derived, the following condition needs to be satisfied: y > l 2
(71)
where: d l 1 = h 2
− 1
d2h 4s 2
l 1l 3
l 2 = s−
− d2 h 4
l 21
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
y c = mina b, y
and the notation is defined in Fig. 40. l3
y d = min a b,
b fc1 − d h s 2
a b = distance from bolt hole to inside face of flange s
s Web
diameter of hole = d h y
l1 l2
d ∕4 − l 2 h
2 1
y
Edge of plate
Figure 41 Yield line pattern (a) H sections s
H--SHAPED COLUMN -- 4 anchor bolts
The yield line patterns considered by the recommended model are shown in Figs. 41, 42, 43, 44 and 45. In the case of yield line patterns (a), (b) and (c) the derived model does not assume that the oblique lines intersect the bolt hole. This should be verified and considered in a similarmanner as previously outlined in the case of H--shaped column with 2 anchor bolts (refer to equation (71) and Fig. 40). The recommended design procedure is as follows: ÔN t = 0.9f yit i α
t i ≥
y =
N*t 0.9f yiα
b fc1 − d h b fc1 2
(72)
y sp y y
ab
b fc Figure 42 Yield line pattern (b) H sections
(73) ab y
(74)
sp y ab b fc Figure 43 Yield line pattern (c) H sections s
2b 2fc1 − 2b fc1d h + 4y 2
2sy b fc1(b fc1 − d h)(a b + y) + 2(y + a b)a by α b = 2sa by b 2fc1 − d hb fc1 + 2y 2c + s py c α c = 2sy c bfc1s − d hs + 2y 2d + s py d − d hy d α d = sy d − + b fc1s 2d hs 4a 2b + 2a bs p − 2a bd h α e = 2a bs
25
ab
y
s
and the value of α is calculated as follows: s p α = max(α a, α b) when y < 2 s p = α b when y < and y > a b 2 s p = max(α c, α d, α e) when y ≥ 2 where:
α a =
d c1 2
b fc
Figure 40 Yield line layout near the bolt hole
2
d c1 2
y
ab
sp y
ab
b fc Figure 44 Yield line pattern (d) H sections
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s
t i ≥ y
ab
(76)
d c1 , (2b fc1 − d h)b fc1 2
(77)
where: ab
α =
2b2fc1 − b fc1d h + y 2
2sy y and s = as defined in Fig. 47
b fc
CHANNEL -- 2 anchor bolts
Figure 45 Yield line pattern (e) H sections
The yield line patterns considered by the recommended model are shown in Figs. 48, 49, 50, 51 and 52. In the case of yield line patterns (a), (b) and (c) the derived model does not assume that the oblique lines intersect the bolt hole. This should be verified and considered in a similar manner as previously outlined in the case of H--shaped column with 2 anchor bolts (refer to equation (71) and Fig. 40).
s ab
sp ab
The recommended design procedure is as follows: ÔN t = 0.9f yit 2i α
b fc Figure 46 Yield line pattern (f) H sections
t i ≥
CHANNEL -- 1 anchor bolt
The yield line pattern considered by the recommended model is shown in Fig. 47 and is similar to the one considered in the case of H--shaped sections with 2 anchor bolts. The derived model does not assume that the oblique lines intersect the bolt hole. This should be verified and considered in a similarmanner as previously outlined in the case of H--shaped column with 2 anchor bolts (refer to equation (71) and Fig. 40). s
y y
d c1 2 d c1 2
N*t 0.9f yiα
(78)
(79)
(80)
and the value of α is calculated as follows: s p α = max(α a, α b) when y < 2 s p = α b when y < and y > a b 2 s p = max(α c, α d, α e) when y ≥ 2 where:
α d =
Theplate thickness required to resist a design axial force ÔN *t is calculated as follows:
y = (2b fc1 − d h)b fc1
α c =
Figure 47 Yield line pattern - Channel with 1 anchor bolt
ÔN t = 0.9f yit 2i α
2b 2fc1 − b fc1d h + y 2 α a = sy b (2b − d h)(a b + y) + (y + a b)a by α b = fc1 fc1 2sa by
b fc
26
N*t 0.9f yiα
y = min
sp y
(75)
α e =
4b 2fc1 − 2d hb fc1 + 2y 2c + s py c 4sy c 2b fc1s − d hs + 2y 2d + s py d − d hy d 2sy d b fc1s − d hs + 2a 2b + a bs p − a bdh 2a bs
y c = min a b, y
y d = min a b,
2b fc1 − d h s 2
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s
s y
ab
ab
sp
sp
ab
ab
y y y
b fc
b fc Figure 48 Yield lines (a) Channels, 2 bolts s
Figure 52 Yield lines (e) Channels, 2 bolts HOLLOW SECTION (RHS, SHS, CHS) -2 anchor bolts
ab y sp y ab b fc
The yield line patterns considered by the recommended model are shown in Figs. 53 and 54. In the case of yield line pattern (a) the derived model does not assume that the oblique lines intersect the bolt hole.This should be verifiedand considered in a similar manner as previously outlined in the case of H--shaped column with 2 anchor bolts (refer to equation (71) and Fig. 40). The recommended design procedure is as follows:
Figure 49 Yield lines (b) Channels, 2 bolts s y
ab
sp y
ab
b fc Figure 50 Yield lines (c) Channels, 2 bolts s ab y sp y
ÔN t = 0.9f yit 2i α
t i ≥
N*t 0.9f yiα
y = (2s 2 − d h)s 2
(81)
(82)
(83)
and the value of α is calculated as follows: l l α = max(α a, α b) when y ≤ i = α b when y > i 2 2 where: 2s 22 − d hs 2 + y 2 α a = ys 1 l α b = i 2s3 s 3 = distancefrom centerline of bolt hole to yield line location specified by s4 s 4 = cantilevered lengths a1 or a 2 of Cantilever Model depending upon orientationof the column section s2 s1
ab y
b fc Figure 51 Yield lines (d) Channels, 2 bolts
27
li
y
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s2 s1 y li y
In the case of yield line pattern (a) the derived model does not assume that the oblique lines intersect the bolt hole.This should be verifiedand considered in a similar manner as previously outlined in the case of H--shaped column with 2 anchor bolts (refer to equation (71) and Fig. 40). The recommended design procedure is as follows: ÔN t = 0.9f yit 2i α
s2 t i ≥
s1
y
N*t 0.9f yiα
(84)
y = (2s 2 − d h)s 2
(85)
(86)
and the value of α is calculated as follows:
li
l i − s p 2 l i − s p = α b when y > 2
y
α = max(α a, α b) when y ≤
Figure 53 Yield lines (a) Hollows, 2 bolts
where:
s4
α a = α b =
s3 li
4s 22 − 2d hs 2 + 2y 2 + s py li 2s3
2ys 1
s2 s1 y
s4
sp
s3
li y
li s2 s1 s3
s4
y li
sp li
y
Figure 55 Yield lines (a) Hollows, 4 bolts Figure 54 Yield lines (b) Hollows, 2 bolts HOLLOW SECTION (RHS and SHS) -4 anchor bolts
The yield line patterns considered by the recommended model are shown in Figs. 55 and 56.
28
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s4
HOLLOW SECTION (RHS) -varying no. of anchor bolts (Packer--Birkemoe Model)
s3
RHS COLUMNS -- varying no. of bolts
li
The model recommended here is Packer--Birkemoe Model. This model is applicable only to base plates between 12mm and 26mm. Thedesignprocedureis as follows (referto theliterature review for further details regarding the model and to Fig. 21 regarding the notation): a preliminary number of bolts required is determined from equation (62) a bolt spacing s p equal to 4--5 d f should be used (even if smaller spacing are possible) and that:
s4 s3
li
a 2 ≤ 1.25a 1
(89)
Calculate δ: d δ = 1 − s h p
(90)
The designer should then select a preliminary plate thickness in the following range:
Figure 56 Yield lines (b) Hollows, 4 bolts
+
HOLLOW SECTION (CHS) -varying no. of anchor bolts (IWIMM Model)
KN *b ≤ t i ≤ KN *b 1 δ
The recommended model for the design of base plates of CHS with a symmetric arrangement of bolts around the column profile as shown in Fig. 20 is based on IWIMM Model previously outlined in the literature review. The recommended design procedure is as follows: ÔN t =
t i ≥
Ôf yi π f 3t 2i
2
(87)
(88)
where: Ô = 0.9 f 3 = 1 k 3 + k 23 − 4k 1 2k 1 r k 1 = ln r 2 3
k 3 = k 1 + 2 d r 2 = 0 + a 1 2 d − t c r 3 = 0 2 a 1, a 2 and d 0 are defined in Fig. 20 [27] recommends to keep the value of a1 as small as possible, i.e. between 1.5df and 2d f (where d f is the nominal diameter of the bolts), while ensuring a minimum of 5 mm clearance between the nut face and the weld around the CHS. Assumptions adopted by this model are a continuous base plate and a weld capacity able to develop the full yield strength of the CHS.
29
(91)
where: 4a 3103 K = Ôf yis p
(where f yi is in MPa)
a 3 = a 1 − d f ∕2 + t c calculate α:
α =
K ÔNtf − 1 t 2i
a 2 + d f ∕2 δ(a 2 + a 1 + t c)
(92)
with the constraint of α ≥ 0
2N*t Ôf yi π f 3
The capacity of the steel base plate is then calculated as follows: ÔN t =
t 2i (1 + δα)n b
(93) K And Ô N t calculated with equation (93) must be greater than N *t. The actual tension in the anchor bolt group, including prying effects, is determined as follows:
a N *tb ≈ N *t 1 + a 3 4
+δαδα 1
(94)
where: N*tb = design tension in anchor bolt group including prying effects
α =
KN *t −1 1 t 2i n b δ
d a 4 = min 1.25a 1, a 2 + f 2
Theanchorboltgroupcapacitycalculatedwithequation (62) needs to be greater than the axial loads applied to the bolt group calculated with equation (94). This is
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
achievedadopting a value Ô p tobeusedinequation(60) equal to: Ô b =
a δα 1 + a 3 4 1 + δα
−1
≤1
Design of weld at column base
The design of the weld at the base of the column is carried out in accordance with Clause 9.7.3.10 of AS 4100.Theweldisdesignedasafilletweldanditsdesign capacity ÔN w is calculated as follows: ÔN w = Ô v wL w = Ô0.6f uw t t k rL w
ÔV f = Ô μN *c
(95)
The evaluation of the capacity of an existing base plate is carriedout following the design procedure previously outlined. Instead of the preliminary values the actual number of bolts and plate thickness are utilised. 5.4.8.
transferred by means of friction when the column is subject to axial compression loading. The shear capacity is calculated as follows:
(96)
where: Ô = 0.8 for all SP welds except longitudinal fillet welds on RHS/SHS with t < 3 mm (Table 3.4 of AS 4100) 0.7 for all longitudinal SP fillet on RHS/SHS with t < 3 mm (Table 3.4 of AS 4100) 0.6 for all GP welds (Table 3.4 of AS 4100)
μ = 0.9
6. SHEAR
Available design information regarding the transfer of shear by each of these means with and without axial loading is now outlined. It is interesting to note how there are still very different opinions regarding the ability of anchor bolts to transfer shear actions. For clarity, the literature review regarding the behaviour of anchor bolts is further divided into the case of anchor bolts subject to shear only or to shear and axial compression and the case of anchor bolts subject to shear and axial tension. TRANSFER OF SHEAR BY FRICTION OR BY RECESSING THE BASE PLATE INTO THE CONCRETE -LITERATURE REVIEW
There is general agreement regarding the determination of the shear capacity of a base plate which can be
30
μ = 0.7
μ = 0.55
INTRODUCTION
The shearaction may be assumed to be transferred from the column to the concrete base either: 1. by friction between between base plate and concrete/grout base or by recessing the base plate into the concrete footing; 2. by a shear key (or shear lug); 3. by the anchor bolts; 4. by a combination of two or more of the above.
6.2.
(97)
where: Ô = 0.8 μ = coefficient of friction ÔV f = shearcapacity of the base plate transferred by friction Coefficients of friction μ available in literature are shown in Fig. 57 and are specified as follows: [2][21][22] 0.9 - concrete or grout against as--rolled steel when the contact plane is the full base plate thickness below the concrete surface (i.e. recessed); 0.7 -- for concrete or grout placed against the as--rolled steel surface with the contact plane coincidental with the concrete surface; 0.55 -- for grouted conditions with the contact plane between the grout and the as - rolled steel exterior to the concrete surface (normal condition).
k r = 1 (reduction factor to account for length of welded lap connection) Refer to Section 13. for tabulated values of Ô v w. The fillet weld is recommended to be placed all around the column section profile.
6.1.
Figure 57 Coefficients of Friction (Ref. [26]) 6.3.
TRANSFER OF SHEAR BY A SHEAR KEY-- LITERATURE REVIEW
Available design guidelines agree that in the presence of a shear key, the shear force is transferred through the shear key acting as a cantilever and bearing against the concrete surface as shown in Fig. 58 while no bearing is assumed to occur against the grout. The bearing capacityof the concreteis calculated in accordance with AS 3600 [10]. Uniform bearing pressure is assumed to occur at the interface between the shear key and the concrete equal to the maximum bearing capacity of the concrete. The shear key is designed as a cantilever to carry the assumed bearing pressure. [26] The required area of the shear key is determined based on the bearing concrete strength 0.85Ôf ′ c as shown in Fig. 58: A sk =
V *s 0.85Ô cf ′ c
(98)
where: Ô = 0.8 A sk = area of the shear key STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
V*s = design shear force to be transferred by means of the shear key The actual length of the shear key L s is then determined based on the available plate depth in contact with the concrete, which, referring to Fig. 58, is equal to (b s − t g). The design moment per unit width of plate m *sk carried by the shear key can then be calculated as follows: m *sk =
V *s b s + t g L s 2
(99)
Ô0.33 f ′ c (where f ′ c is in MPa) with Ô is equal to 0.85. [2]
where: m *sk = design moment to be carried to the shear key
Theweldoftheshearkeyshallbedesignedtocarryboth design shear and moment actions acting on the shear key.
L s = length of shear key b s = depth of shear key t g = grout thickness Equating the design moment to the plastic nominal section moment capacity of the shear key the following is obtained (per unit width of plate): V s b s + t g 0.9f ys t 2s * = 4 = Ô msk (100) m sk = L s 2 *
where: m sk = nominal section moment capacity per unit width of shear key f ys = yield stress of shear key used in design t s = thickness of shear key from whichthe minimum thickness for the shearkey tsk can be calculated in accordance with AS4100 as follows: t s =
4m *sk = 0.9f ys
V *s b s + t g 2 L s 0.9f ys
(101)
or equivalently the shear capacity of a shear key is calculated as: 0.9f ys t 2sL s ÔV s = bs + t g 2
to resist the part of the design shear force that cannot be resisted by friction. For shear keys located near a free concrete edge it should be verified that the concrete is able to carry the applied shear action. The possible failure surface is the one which radiates at 45 degrees from the shear key’s edges towards the concrete edge. The concrete capacity should be determined by multiplying the effective concrete stress area, determined as the projected area of the failure surface on the concrete edge ignoring the shear key area, by the average concrete tensile stress of
(102)
It is interesting to note that the shear key can be welded to the underside of the base plate at any angle even if it is common to choose directions parallel to one or both of the principal axes of the column as these are usually the axes along which the shear needs to be transferred. Reference [26] extends this design procedure for shear keys in two orthogonal directions applying the same design procedure in both orthogonal directions. 6.4.
TRANSFER OF SHEAR BY THE ANCHOR BOLTS -- LITERATURE REVIEW
6.4.1.
Shear only or Shear and Axial Compression
An anchor bolt located away from a concrete edge and with sufficient embedment length would typically transfer the shear through bearing at the surface of the concrete and testing has shown that this transfer mode could cause a concrete wedge to form as shown in Fig. 59. It has been observed that the depth of the concrete wedge can be approximated to be one quarter of the anchor bolt diameter. In the presence of a base plate the translation of the concrete wedge is prevented by a clamping force provided by the base plate and anchor bolts. While the anchor’s behaviour remains in the elastic range the clamping force applied by the anchor bolt and base plate is proportional to the shear force.
where: ÔV s = design shear capacity of the shear key
Applied Shear Concrete Wedge
d f ∕4
ts V *c tg
bs
Shear Key 0.85f ′ c Figure 58 Forces acting on Shear Keys (Ref. [26]) In the presence of combined shear and axial compression actions, the shear key is normally assumed
31
d f
Figure 59 Concrete wedge failure mode under anchor bolt shear force (Ref. [31]) Locating an anchor bolt near the concrete free edge could lead to another failure mode to occur as shown in Fig. 60. The concrete failure surface is determined by radiating at 45 degrees from the anchor bolt at the
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
concrete surface towards the free edge. The concrete capacity is calculated by multiplying the projected area ofthefailuresurfaceattheconcreteedgebytheconcrete average tensile strength of Ô 0.33 f ′ c. Applied Shear
Failure Surface
Side
Front
Figure 60 Concrete failure surface under bolt shear force near a concrete edge (Ref. [31]) The minimum side cover required to ensure a ductile failure requires the concrete wedge capacity to carry a shear load equal to the nominal shear capacity of the anchor bolt. The concrete capacity of the wedge cone can be calculated as follows: ÔV u.c = Ô0.33 f ′ c
πa 2e 2
(103)
where: Ô = 0.65 in [3] and 0.85 in [17] ÔV u.c = concrete capacity against wedge cone failure Experimental results have shown that equation (103) provides a good estimateof the concrete wedge capacity using Ô equal to 0.65. [44][45] Based on [2], [3] and [17] the nominal shear capacity of the anchor bolt is calculated assuming that the shear is transferred by friction between the steel and the concrete with a friction coefficient of 0.7: V u.b = 0.7
πd 2f f uf 4
(104)
where: Vu.b = nominal shear capacity of an anchor bolt assumed to be transferred by friction between anchor and concrete with a friction coefficient of 0.7 The minimum sidecover ae to be adopted for the anchor bolt to avoid the concrete wedge failure can be determined ensuring that the concrete capacity against wedge failure ÔVu.c is able to carry the shear capacity of the bolt transferred by friction V u.b and equating equation (103) to equation (104): [2] ÔV u.c = Ô0.33 f ′
= 0.7
πd 2f 4
c
πa 2e 2
f uf = V u.b
and solving equation (105) for ae:
32
(105)
a e ≥ d f
f uf
Ô0.94 f ′ c
(106)
where: Ô = 0.65 in [3] and 0.85 in [17] Based on the guidelines provided in reference [3], simplified design guidelines of the minimum edge distances calculated with equation (106) using Ô equal to 0.65 are presented in reference [39] which are as follows: for Grade 250 bars and Grade 4.6 bolts: a e ≥ 12d f minimum bolt spacing ≥ 16d f for Grade 8.8 bolts: a e ≥ 17d f minimum bolt spacing ≥ 24d f These minimum bolt spacings intend to avoid overlapping of anchors’ concrete failure cones. These have also been recommended in reference [26]. For completeness minimum edge distances have been derived in Section 12. based on equation (106) with Ô equalto0.65and0.85.Alsosimplifiedexpressionshave been derived as shown in Tables 4 and 5. Table 4 Grade 4.6 bolts and 250 Grade rods Ô
f ′ c
ae
0.65
20
13 df
0.65
25
12 df
0.65
32
11 df
0.85
20
11 df
0.85
25
10 df
0.85
32
10 df
Table 5 Grade 8.8 bolts Ô
f ′ c
ae
0.65
20
18 df
0.65
25
17 df
0.65
32
16 df
0.85
20
16 df
0.85
25
15 df
0.85
32
14 df
References [26] and [47] recommend edge distances based on Ô values equal to 0.85. In the case the side cover is less than ae (calculated with equation (106)) caution should be placed in the design and positioning of the reinforcement. The shear capacity of an anchor bolt located at a distance less than a e∕3 from a concrete edge should be ignored. Adopting a similarreinforcementlayout as suggestedin Fig. 35 to resist direct tensile loading it has been observed by limited testing that concrete failure would occur when
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
anchor bolts are located with a side cover less than 2a e∕3. A possible reinforcement layout to be utilised in the case the side cover is in between ae∕3 and 2ae∕3 is shown in Fig. 61. Allowance for the full development of the reinforcement should be allowed for in accordance with AS 3600 regardless of the reinforcement layout adopted and in the case such allowance is not feasible the shear capacity of the anchor bolt with edge distance problems should be disregarded. [2][17] Experimental studies have shown that possible failure modes which can occur by transferring shear actions by means of anchor bolts are concrete failure with and without wedge cone, concrete failure with pull--out cone and shear failure of the anchor bolt. [45] Shear force
* Potential failure zone
*
* -- Development length from AS3600
Figure 61 Reinforcement for Shear Near an Edge of Concrete Foundation (Ref. [2]) [45] notes that by ensuring sufficientembedment length of the anchor bolt no concrete pull - out can occur. The concrete edge cone failure can be prevented if either an edge distance ae as determined in equation (106) or adequate reinforcement are provided. From test data, [45] concludes that among available guidelines the one of [3], outlined in equation (106), is the most appropriate. [45] shows that equation (106) is not applicable to anchor bolt groups as it can lead to unsafe design particularly for large edge distances and that the nominal concrete capacity is related to both edge distance and bolt spacing. [45] provides no alternative design guidelines but notes that from experimental results the nominal capacity of a two bolt group may only be 60% more than that of a single bolt for the same edge distance.[45] No guidance is currently available for calculating the nominal shear capacity of anchor bolt groups. Itisinterestingtonotethatforthecasewhereagroutpad exists between the base plate andthe concrete, the grout pad allows bending deformation of the anchor bolt to occur under an applied shear force. The lateral
33
deformation of the bolt leads to tensile stress in the bolt but this is generally insufficient to cause pullout. [38] Some authors do not recommend that shear be resisted by the anchor bolts. Rickerin[38]specificallynotesthatanchorboltsshould not beused toresist shear forces ina columnbase. Inhis opinion bolts have a low bending resistance and that if a plate eases sideways to bear against a bolt, bending is inducedintheboltwhichactsasacantileverwithalever arm equal to the grout thickness plus an additional distance should the concrete foundation crush locally. Fischer in [24] notes that in his opinion no more than two anchor bolts for each anchor group would transfer shear. He explains that under normal loading condition only one bolt would be carrying shear in bearing as shown in Fig. 62. The column would then rotate subject to a shear action till a second anchor would go into bearing. Due to the oversize holes specified in base plates it is not possible to ensure that the boltsof the bolt group would deform sufficiently to allow all bolts to go into bearing. [24] Ref. [31] considers that, in the case of base plates, there is not enough data available to precisely quantify the shear strength of an individual anchor bolt, much less a group of anchor bolts.
Figure 62 Transfer of shear by bearing of anchor bolts DeWolf in [22] recommends to avoid the use of anchor bolts to resist shear and suggests that the transfer of shear through anchor bolts takes place by either shear friction or bearing. In the former instance the transfer of shear occurs once a clamping force is developed to the base plate. [22] Even if the anchor bolts are not tightened properly the clamping force can still develop as a consequence of a wedge concrete failure which would tend to lift the base plate up and therefore tensioning the anchor bolts. [31] No specific guidelines are available to evaluate the contribution of the clamping force to the shear resistance of the bolt and in practice this clamping force may not necessary be available. The other transfer mode of anchor bolts described by DeWolf is by bearing between the anchor and the bolt hole, but he regards this very unlikely to occur in practice in more than one or two anchors as the bolt holesof base plates are usually oversized holes. [22] He also notes that a more reliable method of shear transfer through theanchor boltscan be achieved by welding the nuts to the base plate or by providing special washers
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
with normal size holes (bolt dia + 2 mm) which fit over the oversize holes and are welded to the base plate. [21] Projected area of wedge cone
Anchor bolt Top of concrete block
ae
ae
α = 45 o Anchor bolt Overlapped area
ae
α
45 o
ae
4100 [11], for the design of the anchor bolts. Shipp and Haninger suggest in [39] that the total area of anchor bolt required should be the sum of that required to resist tension and that required to resist shear. They argue that the shear force causes a bearing failure nearthe concrete surface and translates the shear load on the anchor bolt into an effective tension load by friction, so that the bolt must have enough tension capacity to resist both effects. [30] notes that for an anchor bolt subject to both shear force and axial tension, design difficulties exist because the interaction of shear and tension is not understood and generally a straight line interaction relationship is assumed, which requires the total steel bolt area be obtained by adding the area required for shear force and the area required for tension. [30] notes that this approach is conservative but is warranted since test data concerning combined shear and tension are lacking for most anchors. Reference [20] suggests an elliptical interaction relationship between tension and shear for the design of anchor bolts while considering the linear interaction relationship to be conservative. References [2] and [17] recommend, in the case of anchor bolts subject to combined shear and tension, to adopt the design recommendations regarding minimum embedment length and edge distances provided in the case of anchor bolts subject to tension and shear separately. 6.5.
Anchor bolts Figure 63 Concrete edge failure cones (Ref. [45]) Ref. [34] notes that it is common and successful industrial practice to use anchor bolts of pinned--base portals to resist the shear forces while recommending the following design guidelines: if shear force is less than 20% of the axial load, then no special provisions are required; for higher levels of shear force, it suggests that great attention be paid to ensuring good grouting under the base plate and around the anchor bolts using a mix of minimum shrinkage; excessive clearance between the anchor bolts and the holes in the base plate should be avoided; to avoid possible horizontal deformation of the column the shear actions should be transferred either by recessing the base plate into concrete, or by means of a shear key or by tying the steel columns to share the load among adjacent columns. 6.4.2.
Shear and Axial Tension
The ability of anchor bolts to transfer shear actions was considered in the previous paragraph. Here only available models to describe the interaction of shear and tension are considered. [39] notes that most references suggest the use of a parabolic interaction equation, similar to the one adopted for conventional bolts as also specified in AS
34
RECOMMENDED MODEL
6.5.1.
Introduction
The recommended design model allows shear action to be transferred by friction between the base plate and the concrete/grout base, by recessing the base plate into the concrete footing, by a shear key or by a combination of the above. It is in the authors’ opinion that due to the uncertainty regarding the ability of anchor bolts to transfer shear it is left up to designer to decide whether or not to design the anchor bolts to carry shear actions. 6.5.2.
Design criteria
The recommended model for the design of base plate subject to shear or combined shear and axial actions is base on the following design criteria: V des = ÔVf + ÔV s, ÔV w min ≥ V *
(107)
N des.c ≥ N *c N des.t ≥ N *t * v des = Ô v w ≥ v w
where: Vdes = design shear capacity of the base plate connection ÔV f = design shear capacity of the base plate transferred by means of friction ÔV s = design shear capacity of the shear key
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
design n shearcapa shearcapacit city y of the the weld weld conn connect ectin ing g ÔV w = desig the base plate to the column Ndes.t = desig design n capaci capacity ty of the the base base plate plate conne connecti ction on subject to axial tension as determined in Section 5.4. Ndes.c = desig design n capaci capacity ty of the the base base plate plate conne connecti ction on subject to axial compression as determined in Section 4.3.
Nc* if the the colu column mn end end is not not prep prepar ared ed for for full full L w contact
v v* =
=0 if the the colu column mn end end is prep prepar ared ed for for full full contact (under axial compression only) The fillet weld capacity between the column and the base plate Ôv w is designed in accordance with Clause 9.7.3.10 of AS 4100 [11] as follows: Ôv w = Ô 0.6f uw uwt tk r
Nt* = design axial tension load Nc* = design axial compression compression load v des = Ôv w = desig design n capaci capacity ty of the the weld weld conn connect ectin ing g the base plate to the column per unit length of weld * v w = design load per unit length acting on the weld conn connect ectin ing g the the base base plate plate to the the colum column. n. Its Its direction depends upon the combined shear and axial loading
The The addi additio tiona nall checkon checkon the the weld weld capaci capacity ty is requ requir ired ed as the critical action acting on the weld (between column and base base plate) is caused by a combinatio combination n of shear and axial loading. 6.5.3. 6.5.3.
Design Design of shear transfer transfer by friction friction and by recessing the base plate in the concrete
The design shear capacity of the base plate transferred transferred by meansof meansof fric frictio tion n and and by reces recessi sing ng the the base base plate plate into into the concrete footing is calculated as follows: ÔV f = Ô μN c*
(108)
where: Ô = 0.8 coefficient of friction μ = coefficient = 0.9 -- concrete or grout against asa s--rolled steel when the contact plane is the full base plate thick thickne ness ss below below the concr concrete ete surf surface ace (i.e (i.e.. recessed) = 0.7 -- for concrete or grout placed against the as--rolled steel surface with the contact plane coincidental with the concrete surface = 0.55 --- for grouted conditions with the contact plane between the grout and the as--rolled as--rolled steel exte exteri rior or to the the conc concre rete te surf surfac acee (nor (norma mall condition) 6.5.4.
(110)
where: Ô = 0.8 for all SP welds except longitudinal longitudinal fillet fillet welds on RHS/SHS with t < 3 mm (Table (Table 3.4 of AS 4100) 0.7 for all longitudinal SP fillet on RHS/SHS with t < 3 mm (Table 3.4 of AS 4100) 0.6 for all GP welds (Table 3.4 of AS 4100) Refer to Section 13. for tabulated values of the fillet weld capacity Ôv w. 6.5.5. 6.5.5.
Design Design of shear transfer transfer by a shear key
The The shearcapa shearcapacit city y of a shearkey shearkey canbe calcul calculate ated d once once the bearing and pull--out -out capacity of the concrete, concrete, the shearcapa shearcapacit city y ofthe shearkey shearkey due due to its its nomin nominalsecti alsection on moment capacity and the weld capacity between the shear key and the base plate are determined as shown below. ÔV s = ÔV s.c; ÔV s.cc; ÔV s.b; ÔV s.w
min
≥ V *
(111)
where: ÔV s = design shear capacity of the shear key ÔV s.c = concrete concrete bearing capacity of the shear key pull--out capacity capa city of the concrete ÔV s.cc = pull--out ÔV s.b = shear capacity of the shear key based on its section moment capacity ÔV s.w = shear capacity of the weld between the shear key and the base plate The concrete bearing capacity of the shear key Ô V s.c is calculated as follows: ÔV s.c = Ô0.85f c′L s(b s − t g)
(112)
where: Ô = 0.6 L s and b s = length and depth of the shear key as shown in Fig. 64
Design of the column weld
The design action applied to the weld between the column and the base plate is calculated as follows: follows: * = v w
v
*2
h
+ v v* 2
(109)
tg bs
Shear Key Shear Key ts
where: v h* and v v* = comp compon onen ents ts of the the loadi loading ng carri carried ed bythe weld between column and base plate in one hori horizo zonta ntall dire directi ction on in the the plane plane of the the base base plate plate and in the vertica verticall directi direction on respect respectivel ively y per unit unit length * v h* = V L w
35
L s
Figure Figure 64 Shear Key Details Details (Ref. (Ref. [26]) In the case case the shear shear key is located located near near a concrete concrete edge edge the capacity of the concrete could be reduced by the
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
sp
formation of a failure surface radiating at 45 degrees from the shear key’s edges towards the concrete edge. The concret concretee capacitycalcula capacitycalculated ted overthe project projected ed area area of such failure surface ignoring the shear key area is determined as follows: ÔV s.cc = Ô0.33 f c′ A psk ≤ ÔV s.c
(113)
where: Ô = 0.7 (based on as Ô required for Clause 9.2.3 of AS3600) A psk = proj project ected ed area area over over the the concr concrete ete edge edge ignoring ignoring the shear key area The The shearcapa shearcapacit city y of the the shearkey shearkey basedon basedon its its nomi nominal nal section section moment moment capacity capacity ÔV s.b is calculat calculated ed as follow follows: s: ÔV s.b =
2 0.9f ys ys t sL s b s + t g 2
Ôv w2L s
1 +
bs+ts
ts
Typical base plate layouts considered considered in this paper are shown in Figs. 65, 66, 67 and 68. Typical anchor bolts used in base plate applications are cast--in -in anchors anchors of categor category y 4.6/S 4.6/S and of diameter diameter either either M16, M20, M20, M24 M24 or M30. Masonry Masonry anchors anchors of diameter M16, M20, M24 may also be used.
Component to suit Grout pad Typical Typical
Figure 65 2--bolt base plate to UB /UC column column (Ref. [26])
36
Figure 67 2--bolt base plate to channel column (Ref. [26])
(115)
BASE PLATE PLATE AND ANCHOR BOLTS BOLTS DETAILING
sg
sp
2
where: Ôv w = design capacity of the fillet weld per unit length (as calculated in equation (110) or as tabulated tabulated in Section 13.)
7.
Figure 66 4--bolt base plate to UB/UC column column (Ref. [26])
(114)
The capacit capacity y of the fillet fillet weld weld connectin connecting g the shear shear key to the base plate ÔV s.w calculate calculated d in the directi direction on perpendicular to the shear key is determined as follows (assuming (assuming the shear key is welded all around): around): ÔV s.w =
sg
Legend: Anchor Bolt Location Hole to allow grout egress
Figure 68 2--bolt base plate to hollow columns (Ref. [26]) Preferr Preferred ed anchor anchor bolt bolt gauge gauge (sg) and and pitc pitch h (sp) are are give given n in Reference [12]. The The ”weld ”weld all roun round” d” philo philosop sophy hy some sometim times es adop adopted ted in the the weld weld desig design n of base base plate platess can lead lead to overover--weldi - welding ng and can become very expensive. The details shown in Figs. Figs. 65, 65, 66, 66, 67 and 68 can, can, if design designed ed for for light light loading loadings, s, tend tend to the other other extreme extreme and some some fabric fabricator atorss mayprefer mayprefer to incr increas easee the the amoun amountt ofweldingabov ofweldingabovee that that show shown n on the the desig design n draw drawin ings gs in orde orderr to preve prevent nt damage during handling and shipping. There is usually a compromise possible between these two extremes. Another design consideration is the likelihood of a nominal nominally ly pinned pinned basebeing subject subjected ed to some some bending bending moment in a real situation. situation. [26] Prior to erecting the column/base plate assembly, the levelofthebaseplateareashouldbesurveyedandshims placed to indicate the correct level of the underside of the base plate as shown in Fig. 69. For heavier column / base plate assemblies, levelling--nut levelling--nut arrangements may be used in order to allow accurate levelling levelling of the base plateas plateas outl outline ined d in [7] [7] and and [38] [38].. Hole Hole sizesin sizesin base base plate platess
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
may be up to 6mm larger than the anchor bolt diameter in accordance with Clause 14.3.5.2 of AS 4100 [11].
Shims
Level of U/S Baseplate Concrete surface
Tack weld 10mm reinforcing bars to form cage ca ge -- no no tacks on HS bolts.
Figure Figure 69 Use of shims for levelling levelling purpose purposess (Ref. [26]) Holes require require a special special plate plate washer washer of 4 mm minimum minimum thicknessunderthenutiftheboltholeismorethan3mm larger than the anchor bolt diameter. Base plates should be provided with at least one grout inspe inspecti ction on hole hole thro throug ugh h which which the the grou groutt will will rise rise indicating a satisfactory grouting operation. Anchor bolts are usually galvanized, even for an interior applicat application ion,, in order order to avoid avoid corros corrosion ion during during the construction period where the steel columns may stand for some time in the open air. The size and location of any permanent steel shims under the base plate should be shown on the drawings. Tempor emporar ary y pack packer erss whic which h are used used for for erect erectio ion n purp purpos oses es unti untill the the under undersid sidee of the the base base plate plate is grou grouted ted or concreted should be left to the erector to detail. The minimum space between the underside of the base plate and the concrete foundation should be: 25 mm for grouting; 50 mm for mortar bedding; 75 mm for concrete bedding. Tolerances on anchor bolt positions and level of base plate plate shou should ld confo conform rm to the the prov provisi ision onss of Claus Clausee 5.12 5.12 of AS 4100.[11] [24] notes that possible possible design and detailing problems for base plates include: include: inadequate development of the anchor bolts for tension and of concrete reinforcing steel; improper selection of anchor bolt material; inadequate inadequate base plate thickness; thickness; poor placement of anchor bolts; shear and fatigue loading on anchor bolts. Based on a survey carried out in the UK [29] notes that poor poor fit fit of base base plate platess onto onto hold holdingdown ingdown boltsis boltsis amon among g one of the four most commonly reported problems of lack of fit on site. To ensure that the bolt centres match the nominated centr centres es and and the the hole hole centr centres es dril drilled led in the the base base plate plate,, the the bolts are often caged into a group as shown in Fig. 70. Also useful is the provision of cored holes usually for formed med by usin using g poly polyst styr yren enee whic which h allo allow w the the adjus adjustme tment nt of ancho anchorr bolt bolt posit positio ions ns once once the the concr concrete ete is cast cast in orderto orderto exact exactly ly matchthe matchthe hole hole centr centres es in the the base base plate as already shown in Fig. 32. Anchor bolt centres must comply with the tolerances set out out inClaus inClausee 15.3 15.3.1of .1of AS4100 AS4100 as show shown n in see see Fig.71. Fig.71.
37
Figure Figure 70 Locating Locating Holding Holding Down Bolts Bolts with a Cage (Ref. [26]) 1
2
3
Specified dimension (+/ -- 6 in every 30m but not greater than +/-- 25 overall) Max deviation +/-- 6
C/L Anchor bolts Max deviation +/-- 6 Max deviation +/-- 6 C/L Anchor bolts +/-- 3
C/L Grid
Detail Detai l of off--ce off--centre ntre location of anchor bolts
+/-- 3 C/L Grid
4 Unles nlesss othe otherw rwis isee specified, dimensions are in millimetres
Main column C/L grid
Max deviation +/-- 6 if column offset from main column line.
Figure 71 Tolerances in Anchor Anchor Bolt Location after AS 4100 (Ref. [26]) [19] and [38] present a discussion of a number of practical aspects of the use of anchor bolts and should be referred to if problems problems arise on site. [19] deals with gene genera rall aspe aspect ctss rega regard rdin ing g desi design gn,, inst instal alla lati tion on,, anchora anchorage, ge, corros corrosion ion of anchor anchor bolts, bolts, bedding bedding and grouting as well as the responsibilities of all parties in
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
the construction process but no firm recommendations are made on design however.
8. ACKNOWLEDGEMENTS Thispaperstartedfromtheverysignificantworkcarried out by Tim Hogan and Ian Thomas who collated the majority of the research results on steel connections from around the world in Ref [26]. Valuable input and support for this current work has come from OneSteel - in particular Anthony Ng, Gary Yum and Nick van der Kreek. The ASI State Managers -- Leigh Wilson, Rupert Grayston, John Gardner and Scott Munter have all contributed industry insights. Several overseas researchers, notably Jeffery Packer and John DeWolf, havecontributedsignificantlyinthisareaandtheirwork and comments are acknowledged.
[14] [15] [16]
[17]
[18] [19]
9. REFERENCES [1]
[2]
[3]
[4]
[5]
[6]
[7]
[8] [9] [10] [11] [12]
[13]
38
Ahmed, S. and Kreps, R.R., “Inconsistencies in Column base Plate design in the New AISC ASD Manual”, Engineering Journal, American Institute of Steel Construction, Vol. 27, No. 3, 1990, pp 106 -- 107. American Concrete Institute, ”Code Requirements for Nuclear Safety Related Structures”, ACI 349 - 90, Manual of Concrete Practice (1994). American Concrete Institute, ”Code Requirements for Nuclear Safety Related Structures”, ACI 349 -- 1976, Manual of Concrete Practice. American Institute of Steel Construction, “Detailing for Steel Construction”, Second Edition, 2002. American Institute of Steel Construction, “Manual of Steel Construction - Load and Resistance Factor Design”, Third Edition, 2001. American Institute of Steel Construction, “Manual of Steel Construction - Volume II Connections”, Ninth Ed./First Edition, 1992. American Institute of Steel Construction, “Manual of Steel Construction - Load and Resistance Factor Design”, First Edition, 1986. AS/NZ 1170.0:2002 -- “Structural design actions -- Part 0: General principles”, 2002 AS 1275 - ”Metric Screw Threads for Fasteners”, 1985. AS 3600 - ”Concrete Structures”, 2001. AS 4100 - ”Steel Structures ”, 1998. Australian Institute of Steel Construction, ”Standardized Structural Connections”, Third Edition, 1985. Ballio, G. and Mazzolani, F.M., “Theory and Design of Steel Structures”, Chapman and Hall, 1983.
[20]
[21]
[22]
[23]
[24]
[25]
[26]
[27]
[28]
Bangash, M.Y.H., “Structural detailing in Steel”, Thomas Telford, 2000 Bickford, J.H. and Nassar, S., Handbook of Bolts and Bolted joints”, Marcel Dekker, 1998 Blodgett, O., Design of Welded Structures”, The James F Lincoln Arc Welding Foundation, Fifth Printing, 1972, Section 3.3. Cannon, R.W., Godfrey, D.A. and Moreadith, F.L., ”Guide to the Design of Anchor Bolts and Other Steel Embedments”, Concrete International, July 1981, pp 28 - 41. Chen, W.F., “Handbook of Structural Engineering”, CRC Press, 1997 Concrete Society/British Constructional Steelwork Association/Constructional Steel Research and Development Organisation, ”Holding Down Systems for Steel Stanchions”, 1980. Cook, R. and Klingner, R., “Behaviour of Ductile Multiple--Anchor Steel--to Concrete Connections with Surface--Mounted Baseplates”, from “Anchors in Concrete -Design and Behavior” edited by Senkiw, G.A. and Lancelot III, H.B., American Concrete Institute, 1991 DeWolf, J.T, ”Column Base Plates”, American Institute of Steel Construction, Design Guide Series No. 1, 1990. (Publication also contains Refs. [38] and [42]) DeWolf, J.T, ”Column Anchorage Design”, American Institute of Steel Construction, National Eng Conf., New Orleans, Proceedings, Paper 15, April/May 1987. Eurocode 3: Design of steel structures DD ENV 1993--1--1 Part 1.1 General rules and rules for buildings, 1992 Fischer, J.M., “Structural details in Industrial buildings”, Engineering Journal, American Institute of Steel Construction, Vol. 18, No. 3, 1981, pp 83--89. Fling, R.S., ”Design of Steel Bearing Plates”, Engineering Journal, American Institute of Steel Construction, Vol. 7 No. 2, April 1970, pp 37 - 40. Hogan, T.J. and Thomas, I.R., “Design of structural connections”, Fourth Edition, Australian Institute of Steel Construction, 1994. Igarashi, S., Wakiyama, K., Inove, R., Matsumoto, T. and Murase, Y., “Limit Design of high strength Bolted Tube Flange joint Parts 1 - 2”, Journal of Structural and Construction Engineering Transactions of AIJ, Department of Architecture reports, Osaka University, Japan, 1985. Jaspart, J.P. and Vandegans, D., “Application of the component method to column bases”, Proceedings of the International Conference on STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
[29] [30]
[31]
[32]
[33]
[34]
[35] [36]
[37]
[38]
[39]
[40]
[41]
[42]
39
Advances in Steel Structures, Hong Kong, Vol.1, 1996, pp 139 - 144. Mann, A.P. and Morris, L.J., “Lack of fit in steel structures”, CIRIA Report 87, 1981 Marsh M.L. and Burdette, E.G., ”Multiple Bolt Anchorages: Method for Determining the Effective Projected Area of Overlapping Stress Cones”, Engineering Journal, American Institute of Steel Construction, Vol. 22 No. 1, 1985, pp 29 -- 32. Marsh, M.L. and Burdette, E.G., ”Anchorage of Steel Building Components to Concrete”, Engineering Journal, American Institute of Steel Construction, Vol. 22 No. 1, 1985, pp 33 -- 39. Murray, TM., Design of Lightly Loaded Steel Column Base Plates”, Engineering Journal, American Institute of Steel Construction, Vol. 20 No. 4, 1983, pp 143 - 152. National Institute of Standards and Technology, “Post--Installed Anchors -- A Literature Review”, NISTIR 6096, 1998. Owens, G.W. and Cheal, B.D., ”Structural Steelwork Connections”, Butterworths, London, 1989. Park, R. and Gamble, W.L., “Reinforced Concrete Slabs”, Wiley, 1980. Parker, J.A. and Henderson, J.E., “Hollow structural section connections and trusses -- A design guide”, Second Edition, Canadian Institute of Steel Construction, 1997. Parker, J.A., “Design with structural steel hollow sections - Australian Institute of Steel Construction Seminar”, Australian Institute of Steel Construction, March 1996. Ricker, D.T, ”Some Practical Aspects of Column Base Selection”, Engineering Journal, American Institute of Steel Construction, Vol. 26 No. 3, 1989, pp 81 - 89. Shipp, J.G. and Haninger, E.R., ”Design of Headed Anchor Bolts”, Engineering Journal, American Institute of Steel Construction, Vol. 20 No. 2, 1983, pp 58 - 69. Stockwell, F.W., ”Preliminary Base Plate Selection”, Engineering Journal, American Institute of Steel Construction, Vol. 12 No. 3, 1975, pp 92 -- 93. Stockwell, F.W., ”Base Plate Design”, American Institute of Steel Construction, National Eng Conf, Proceedings, Paper 49, April/May 1987. Thornton W.A., ”Design of Small base Plates for Wide Flange Columns”, Engineering Journal, American Institute of Steel Construction, Vol. 27, No. 3, 1990, pp 108--110.
[43]
[44]
[45]
[46]
[47]
Thornton W.A., ”Design of Base Plates for Wide Flange Columns -- A Concatenation Method”, Engineering Journal, American Institute of Steel Construction, Vol. 27, No. 4, 1990, pp 173--174. Ueda, T, Kitipornchai, S. and Ling, K., ”Experimental Investigation of Anchor Bolts Under Shear”, Journal of Structural Engineering, 1990 Ueda, T, Kitipornchai, S. and Ling, K., ”An Experimental Investigation of Anchor Bolts Under Shear”, University of Queensland, Dept of Civil Eng., Research Report No. CE93, Oct. 1988. Wood, R.H. and Jones, L.L., “Yield--line analysis of slabs”, Thames and hudson, Chatto & Windus, London, 1967. Woolcock, S.T, Kitipornchai, S. and Bradford, M.A., ”Limit State Design of Portal Frame Buildings”, Second Edition, Australian Institute of Steel Construction, 1993.
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
10. APPENDIX A -- Derivation of Design and Check Expressions for Steel Base Plates Subject to Axial Compression The design model for base plates subject to axial compression recommended in this paper is a modified version of Thornton Model presented in [43] which is suitable for H--shaped columns only. Its derivation has also been extended here for channels and hollow sections. The recommended model concatenates the Cantilever, Fling and Murray--Stockwell Models as follows: t i ≥ a m
2N c 0.9f yi d i b i *
a m = max(a 1, a 2, λa 4) Forclarity themodel which describes the design of base plates subject to uniform pressure using yield line theory is referred to throughout this section as Yield Line Model. In the case of H--shaped sections Fling Model and the YieldLine Model coincide. The assumed yield line patterns are based on the external dimensions of the column profile. Values of a1 and a 2 are available in [21], [26] and [36] for H--shaped columns, channels and hollow sections while values of λ and a 4 are available in [5] and [43] for only H--shaped sections. In the recommendedmodel presented here the values of λ and a4 have been re--derived and modified for H--shaped sections and have been derived for channels and hollow sections. Thederivationofsuchvaluesisoutlinedbelowbasedon a procedure similar to the one utilised by Thornton in [43]. The values of λ and a 4 allow the inclusion in the recommended model of the results obtained with Murray--Stockwell Model and with the Yield Line Model respectively. It is important to note that, similarly to Thornton Model, the recommended model always adopts the thinnest plate determined using Murray--Stockwell Model and the Yield Line Model. In the following derivation the values of a 4 are firstly determinedto include the YieldLine Model and then the value of λ to include Murray--Stockwell Model is determined. A.1
DERIVATION FOR DESIGN PURPOSES -- H--SHAPED SECTIONS
A.1.1
DETERMINATION OF a 4 (Yield Line Model -- Fling Model)
The base plate is designed assuming a yield line pattern as shown in Fig. 72. The present derivation is suitable for H--shaped sections for which b fc∕2 is less than dc as a different yield line pattern would otherwise occur.
d1
Dashed lines indicate yield lines
b es
θ Figure 72 Yield line pattern for H--shaped sections The base plate is considered to be simply supported along the flanges, fixed along the web and free along the edge opposite to the web. Solutions from yield line theory are available for this kind of support conditions carrying a uniformly distributed load f *p and based on the results presented in [35]:
24Ômp 1 + f *p =
b 2fc 3 −
4+48η2−2 4η 2
4+48η 2−2 4η 2
(116)
where:
η = d c∕b fc In this case the uniform load f *p is calculated as follows: f *p =
N*c d ib i
The required design plastic moment Ôm p to support a uniform pressure of f *p is obtained by re--arranging equation (116) as follows: b 2fc 6η 2 − 1 + 12η 2 + 1 Ôm p = f p 24 2η 2 + 1 + 12η 2 − 1 *
= 18 f *pb 2fcα2
(117)
where: 6η 2 − 1 + 12η 2 + 1 α 2 = 1 3 2η 2 + 1 + 12η 2 − 1 The value of α 2 introduced in equation (117) is approximated by the following expression with an error of - 0% (unconservative) and +17.7%(conservative) for values of η (which is equal to dc∕b fc ) between 3/4 and 3:
α = 1 η 2
(118)
The required plate thickness to support f *p can be determined by equating the nominal section moment capacityof the plate Ôm s (per unitwidth) to the required design plastic capacity (per unit width) as follows:
40
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Ôm s =
0.9f yit 2i 4
≥ 18 f *pb 2fcα2 = Ômp
(119)
and re--arranging equation (119)in terms of the required plate thickness yields:
t i = 1 d cb fc 4
= a 4
Substituting equations (122) and (123) into equation (124) and solving for a 3 the following expression for a3 is obtained: a 3 =
2f *p 0.9f yi
=
2N *c 0.9f yid ib i
(120)
A.1.2
a 5 1 − 1 − X 4
X =
The thickness of the base plate calculated according to Murray--Stockwell Model is determined as follows:
2N *c 0.9f yi A H
(121)
It is interestingto note how, in the formulation presented in [5], [42] and [43], the load adopted in equation (121) would have been equal to N*0 instead of N *c, where N *0 is the portion of full column load N *c acting over the column footprint under the assumption of uniform bearing pressure, while in the derivation presented the full column load N*c is assumed to be applied on the H--shaped area A H. Referring to Fig. 11 the H - shaped bearing area A H can be expressed as follows: A H = 2a 3a 5 − 4a 23
(125)
4N *c Ôf ba 25
Substituting the value of a3 calculated in equation (125) into equation (122) yields, after simplifying, the following expression for the H--shaped bearing area A H:
DETERMINATION OF λ (Murray--Stockwell Model)
t i = a 3
4Ôf b
where:
where: a 4 = 1 dcb fc 4
Ôf ba 5 − (Ôf ba 5) 2 − 4Ôf bN *c
A H =
a 25X
4
(126)
The required plate thickness can now be calculated substituting the values of A H and a3 calculated from equations (125) and (126) into equation (121). t i =
a 5 1 − 1 − X 4
= λa 4
λ = 2
2N *c 0.9f yid ibi
8N *c 0.9f yi a 25X
(127)
where:
(122)
X d ib i d cb fc 1 + 1 − X
where: a 5 = b fc + d c
A.2
DERIVATION FOR DESIGN PURPOSES -- CHANNELS
In this derivation, similarly to Thornton Model, the iterative procedure for the calculation of A H and Ôf b described in the literature review is not implemented and is terminated at the first iteration. The value of the maximum bearing strength of the concrete Ôf b is calculated as follows:
A.2.1
DETERMINATION OF a 4 (Yield Line Model)
Ôf b = min Ô0.85f ′ c
A 2 , Ô2f ′ c A 1
(123)
where: Ô = 0.6 A 1 = bearing area equal to the base plate area A i The H--shaped area A H is defined as the area able to support the applied axial compression load N*c at a uniform pressure of Ôf b. A H =
41
N *c Ôf b
The yield line pattern assumed in the case of channels is similar to the one assumed in the case of H--shaped column sections as shown in Fig. 73 andit is suitable for channels with bfc less than d c, as a different yield line pattern would otherwise occur.
Dashed lines indicate yield lines
(124) Figure 73 Yield line pattern for Channels
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
The base plate is considered to be simply supported along the flanges and the web and free at the edge opposite to the web. Available solutions as proposed in [35] for a uniformly distributed load f *p are utilised.
8Ôm p 4+9η 2−2
η2
f *p =
b 2fc 3 −
2 4 4+ 9η − 2
η2
3
(128)
η = d c∕b fc Similarly to the case of H--shaped column sections the uniform load f *p is calculated as follows:
Ôm p = f *pb 2fc
24
4 + 9η − 2 2
(129)
The thickness of the base plate calculated according to Murray--Stockwell Model is determined as follows:
9 η 2 − 4 4 + 9η 2 + 8 24 4 + 9η 2 − 48
α = 1 η 3
0.9f yit 2i 4
≥ f *pb 2fcα 2 = Ô mp
(131)
and re--arranging equation (131) in terms of the required plate thickness yields:
2dcbfc
= a 4 where:
42
(133)
(134)
The value of the maximum bearing strength of the concrete Ôf b is calculated as follows:
Ôf b = min Ô0.85f ′ c
2f p 0.9f yi
2N *c 0.9f yid ib i
*
A 2 , Ô2f ′ c A 1
(135)
N*c Ôf b
(132)
(136)
Substituting equations (134) and (135) into equation (136) and solving for a 3 the following expression for a3 is obtained: a 3 =
Ôf ba 5 − (Ôf ba 5) 2 − 8Ôf bN *c
4Ôf b
=
a 5 1 − 1 − X 4
(137)
where: X =
8N *c Ôf ba 25
Substituting the value of a3 calculated in equation (137) into equation (134) yields, after simplifying, the following expression for the assumed bearing area A H: A H =
where: Ô = 0.6 A 1 = bearing area equal to the base plate area A i
(130)
The required plate thickness to support f p can be determined by equating the nominal section moment capacityof the plate Ôm s (per unit width)to the required design plastic capacity (per unit width) as follows:
3
A H = a 3a 5 − 2a 23
*
t i =
2N *c 0.9f yi A H
Referring to Fig. 12 the assumed bearing area A H canbe expressed as follows:
A H =
The value of α 2 introduced in equation (129) can be approximated by the following expression with an error of --0% (unconservative) and +6.7% (conservative) for values of η (which is equal to dc∕b fc ) between 1.25 and 4 (which include the channel sections available in Australia):
Ôm s =
The assumed area A H is defined as the area able to support the applied axial compression load N*c at a uniform pressure of Ô f b.
where:
=
DETERMINATION OF λ (Murray--Stockwell Model)
A.2.2
9η 2 − 4 4 + 9η 2 + 8
= f *pb 2fcα 2
α
3
where: a 5 = 2b fc + d c
N *c d ib i
The required design plastic moment Ôm p to support a uniform pressure of f *p is obtained by re--arranging equation (128) as follows:
2
2dcbfc
t i = a 3
where:
f *p =
a 4 =
a 25X
8
(138)
The required plate thickness can now be calculated substituting the values of A H and a3 calculated from equations (137) and (138) into (133). t i =
a 5 1 − 1 − X 4
16N *c 0.9f yi a 25X
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
= λa 4
2N *c 0.9f yid ibi
(139)
λ = 3 2
X d ib i d cb fc 1 + 1 − X
ti
DERIVATION FOR DESIGN PURPOSES -- RECTANGULAR HOLLOW SECTION
A similar procedure to the ones adopted in the case of H-- shaped sections and channels is adopted for rectangular hollow sections.
The yield line pattern considered in the case of rectangular hollow sections is shown in Fig. 74 and the required design plastic moment Ôm p under a uniform pressure f *p can be expressed as follows (based on [35]): Ôm p = f *pb 2c
1 + 3η
2
− 1
24η 2
α
=
1 + 3η
2
− 1
=
2d cb c 23
= f *pb 2cα2
(140)
(142)
= a 4
a 4 =
2N *c 0.9f yid ib i
2d cb c 23
Referring to Fig. 13 the assumed bearing area A H canbe expressed as follows:
(144)
where:
Ôf b = min Ô0.85f ′ c
A 2 , Ô2f ′ c A 1
(145)
where: Ô = 0.6 A 1 = bearing area equal to the base plate area A i
dc
The assumed area A H is defined as the area able to support the applied axial compression load N*c at a uniform pressure of Ô f b.
bc
A H = Figure 74 Yield line pattern for Rectangular Hollow Sections The plate is assumed to be simply supported along all the edges. The value of α introduced in equation (140) can be approximated by the following expression with an error of - 0% (unconservative) and +11.1% (conservative) for values of η (which is equal to d c∕b c) between 3/4 and 4:
(141)
The required plate thickness to support f *p can be determined by equating the nominal section moment capacityof the plate Ôm s (per unit width)to the required design plastic capacity (per unit width) as follows:
N*c Ôf b
(146)
Substituting equations (144) and (145) into equation (146) and solving for a 3 the following expression for a3 is obtained: a 3 =
2
η 23
(143)
DETERMINATION OF λ (Murray--Stockwell Model)
A.3.2
24η 2
The value of the maximum bearing strength of the concrete Ôf b is calculated as follows:
2
η = d c∕b c
α =
a 5 = b c + d c
N* f *p = c d ib i
43
2f *p 0.9f yi
A H = 2a 3a 5 − 4a 23
2
where: 2
≥ f *pb 2cα2 = Ô mp
where:
DETERMINATION OF a 4 (Yield Line Model)
A.3.1
4
and re--arranging equation (142) in terms of the required plate thickness yields:
where:
A.3
0.9f yit 2i
Ôm s =
=
2Ôf ba 5 − 4(Ôf ba 5) 2 − 16Ôf bN *c 8Ôf b
a 5 1 − 1 − X 4
(147)
where: X =
4N *c Ôf ba 25
Substituting the value of a3 calculated in equation (147) into equation (144) yields, after simplifying, the following expression for the assumed bearing area A H:
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
A H =
a 25X
4
(148)
The required plate thickness can now be calculated utilising the values of A H and a3 calculated from equations (147) and (148) as previously carried out for H--shaped sections and channels. t i =
a 5 1 − 1 − X 4
= λa 4
2N *c 0.9f yid ibi
(149)
+ − + −
≈ 1.7 A.4
d ib i d cb c
23 8 1
d ib i d cb c 1
X 1
X 1
X
X
(150)
where: N *c d ib i
a 4 =
2f *p 0.9f yi
2N *c 0.9f yid ib i
(152)
1 b ≈ 1 b 10.7 c 3 c
(153)
where: a 5 = 2b c The value of the maximum bearing strength of the concrete Ôf b is calculated as follows:
Ôf b = min Ô0.85f ′ c
A 2 , Ô2f ′ c A 1
(154)
where: Ô = 0.6 A 1 = bearing area equal to the base plate area A i The assumed area A H is defined as the area able to support the applied axial compression load N*c at a uniform pressure of Ô f b. A H =
bc
N*c Ôf b
(155)
In a similar manner as previously carried out the value of a 3 can be determined as follows:
bc
Figure 75 Yield line pattern for Square Hollow Sections The plate is assumed to be simply supported along all the edges. The required plate thickness to support f *p can be determined by equating the nominal section moment capacityof the plate Ôm s (per unit width)to the required design plastic capacity (per unit width) as follows: 44
= a 4
A H = 2a 3a 5 − 4a 23
The yield line pattern considered in the case of rectangular hollow sections is shown in Fig. 75 and the required design plastic moment Ôm p under a uniform pressure f *p can be expressed as follows (based on [35] and [46]):
f *p =
1 b 10.7 c
Referring to Fig. 13 the assumed bearing area A H canbe expressed as follows:
A similar procedure to the one previously adopted is carried out for square hollow sections. A.4.1 DETERMINATION OF a 4 (Yield Line Model)
f *pb 2c 21.4
(151)
DETERMINATION OF λ (Murray--Stockwell Model)
A.4.2
DERIVATION FOR DESIGN PURPOSES -- SQUARE HOLLOW SECTION
Ôm p =
where:
where:
λ =
t i =
8N *c 0.9f yi a 25X
4
f * b 2
p c ≥ 21.4 = Ômp
and re--arranging equation (151) in terms of the required plate thickness yields:
0.9f yit 2i
Ôm s =
a 3 =
b c 1 − 1 − X 2
X =
4N *c Ôf ba 25
(156)
where:
and the value of the assumed bearing area A H can be expressed as follows: A H =
a 25X 4
= b 2cX
(157)
The required plate thickness can now be calculated. t i =
b c 1 − 1 − X 2
2N *c 0.9f yi b 2cX
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
2N *c 0.9f yid ibi
= λa 4
(158)
Referring to figure 14 the assumed bearing area A H can be expressed as follows:
where:
A H = π [d 20 − (d 0 − 2a 3) 2] = π (a 3d 0 − a 23) 4
X d ib i λ = 3 2 bc 1 + 1 − X A.5
DETERMINATION OF λ (Murray--Stockwell Model)
A.5.2
DERIVATION FOR DESIGN PURPOSES -- CIRCULAR HOLLOW SECTION
The value of the maximum bearing strength of the concrete Ôf b is calculated as follows:
Ôf b = min Ô0.85f ′ c
A similar procedure to the one previously adopted is carried out for circular hollow sections. DETERMINATION OF a 4 (Yield line theory)
A.5.1
The yield line pattern considered in the case of circular hollow sections is shown in Fig. 76 and the required design plastic moment Ôm p under a uniform pressure f *p can be expressed as follows (based on [35]): Ôm p =
f *pd 20
24
f *p =
A 2 , Ô2f ′ c A 1
(163)
where: Ô = 0.6 A 1 = bearing area equal to the base plate area A i The assumed area A H is defined as the area able to support the applied axial compression load N*c at a uniform pressure of Ô f b. A H =
(159)
where:
(162)
N*c Ôf b
(164)
In a similar manner as previously carried out the value of a 3 can be determined as follows:
Nc d ib i *
a 3 =
d 0 1 − 1 − X 2
X =
4N*c d 20πÔf b
(165)
where: do
and the value of the assumed bearing area A H can be expressed as follows: A H = π
Figure 76 Yield line pattern for Circular Hollow Sections
t i =
The required plate thickness to support f *p can be determined by equating the nominal section moment capacityof the plate Ôm s (per unit width)to the required design plastic capacity (per unit width) as follows: Ôm s =
4
≥
f *pd 20 24
= Ô mp
(160)
d0 2 3
2f *p 0.9f yi
where:
2N *c 0.9f yid ib i
d0
2 3
(166)
2N *c 0.9f yid ibi
8N*c 0.9f yi πd 20X
(167)
where:
λ = π
12
(161)
≈ 2 A.6
a 4 =
45
= a 4
d 0 1 − 1 − X 2
= λa 4
and re--arranging equation (160) in terms of the required plate thickness yields: t i =
4
The required plate thickness can now be calculated.
The plate is assumed to be simply supported along all the edges.
0.9f yit 2i
d 20X
dibi d0
dibi d0
X 1 + 1 − X
X 1 + 1 − X
DERIVATION FOR CHECK PURPOSES -- ALL SECTIONS
The base plate capacity for a given base plate according to each Model considered is first determined and then a unique expression which concatenates them is derived.
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
The following notation is used in the derivation: ÔN c.1 =designcapacitybasedon a1 oftheCantilever Model ÔN c.2 =designcapacitybasedon a2 oftheCantilever Model ÔN c.3 = design capacity based on the Yield Line Model ÔN c.4 = design capacity based on Murray Stockwell Model ÔN c.1 =
ÔN c.2 =
ÔN c.3 =
0.9f yid ib it 2i
(168)
2a 21 0.9f yid ib it 2i
(169)
2a 22 0.9f yid ib it 2i
(170)
2a 24
The calculation of the design capacity ÔN c.4 based on Murray--Stockwell model requires the following derivation: t i = λ a 4
=
2ÔN c.4 0.9f yid ib i
ÔN c.4 Y
1 + 1 − ÔNc.4Y
ka 4
2 0.9f yid ib i
(171)
where:
λ = k
X 1 + 1 − X
X = ÔNc.4Y and re--arranging equation (171) yields: ÔN c.4 =
0.9f yib id i 2a 24
t 2i λ′
(172)
where:
λ′ = 12 k
2ka 4 ti
Y
2 −1 0.9f yib id i
The design capacity of the base plate is then calculated as follows: ÔN c = min(ÔN c.1, ÔN c.2, ÔN c.5)
11. APPENDIX B-- Derivation of Design and Check Expressions for Steel Base Plates Subject to Axial Tension The derivation of the expressions for the design and check of base plate subject to axial tensile loading has been here carried out for common base plate layouts when no design guidelines were found in literature. Yield line theory, based on conservative yield line patterns (in the authors’ opinion), has been utilised in the derivation. The plate moment capacity per unit length of yield line has been calculated here based on the plastic section modulus of the plate as alsocarried outin Australianand American guidelines [5], [21] and [26]. It is interesting to note that [23] recommends to use the elastic section modulus. The reduction of plate capacity due to the anchor bolt holes has beenaccounted for. Ignoring the effectsof bolt holes is a substantialsimplification as alsonoted in [37]. Murray Model, which considers the design of base plates for lightly loaded H--shaped columns with two anchor bolts, has been here re--derived and modified to include the plate reduction capacity due to bolt holes. Here the yield lines are conservatively assumed to remain inside the internal faces of the column profile, while in Murray Model they extend to the centerline of the web and to the outside faces of the flanges. The derivations of the capacity or required thickness for the yield line patterns considered have been carried out for various combinations of column sections and number of anchor bolts as listed in Section 5.4.7. The derivation for the case of a H--shaped column with anchor bolts, as shown in Fig. 77, is outlined below. All other cases are considered in a similar manner and the relevant expressions of their derivation are summarised in Table 6. Similar considerations outlined for the validity of the Yield Line Model for the case of a H-- shaped column section with 2 bolts can be applied to the other base plate configurations considered. B.1
H--SHAPED COLUMN WITH 2 ANCHOR BOLTS
In the case of H--shaped column sections with two anchor bolts the yield line pattern assumed is shown in Fig. 77. It is the same as the one considered in Murray Model. The base plate dimensions are conservatively assumed to be equal to the outside column dimensions unless noted otherwise.
(173)
where: ÔN c.5 = max(ÔN c.3, ÔN c.4)
and ÔN c.1, ÔN c.2, ÔNc.3 and ÔN c.4 area calculated as shown in equations (168), (169), (170) and (172).
46
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
s
where:
t w
y = as calculated from equation (179) or equivalently the minimum plate thickness required for a certain design tension load N*t :
d c1 2
y y
d c1 2
t i ≥
b fc Figure 77 Yield line pattern: H--shaped column with 2 bolts Considering the symmetry about the column web the derivation of the internal work and external work is carried out only considering half the plate area:
+ +
b fc1 W i = Ôm p 1 y 4 2 − 2d h
= Ômp W e = 2N *b
2b fc1 − 2d h y
2 2y b fc1
4y b fc1
s
(174) (175)
b fc1
where: b fc1 = b fc − t w
4syN *t 0.9f yi 2b 2fc1 − 2b fc1d h + 4y 2
Further reductions due to other yield lines intersecting bolt holes have not been considered as they are very unlikelyto occur and a more detailed analysisshould be carried out in such situation. The critical yield line pattern is a function of the value of y calculated from equation (179). To ensure that none of the oblique yield lines intersects the bolt hole, as assumed in the model derived, the following simplified condition needs to be satisfied: y > l 2
− 1
d2h 4s 2
l 1l 3
l 2 = s−
− d2 h 4
l 21
and the notation is defined in Fig. 78. l3
Thevalueofywhichminimises N*b (or equivalently that maximises the required Ôm p) is determined differentiating equation (176) for y.
s Web
diameter of hole = d h
(177)
l1
Solving equation (177) for y yields: y =
b fc1 − d h b fc1 2
l2
(178)
The presence of the flanges requires the value of y to be always less or equal to dc∕2 and therefore y is re--defined as follows: y = min
d c1 , 2
(182)
where:
b fc1 2b fc1 − 2d h 4y + Ôm p (176) y 2s b fc1
dN *b 2b fc1 − 2d h = − + b4 = 0 dy y2 fc1
(181)
In this model the reduction in plate capacity due to the presenceofaboltholealongtheyieldlineperpendicular to the web has been included.
d l 1 = h 2
y and s are defined in Fig.77 Equating the internal and external work the expression of the design axial tension load per bolt N*b is obtained as follows: N *b =
b fc1 − d h b fc1 2
(179)
The design axial tension capacity of the base plate Ô N t is then obtained re--arranging equation (176) as follows: 0.9f yit i ÔN t = 2b fc1 − 2b fc1d h + 4y 4sy
d ∕4 − l 2 h
2 1
Edge of plate
Figure 78 Yield line layout near the bolt hole Substituting a nil value for the diameter of the bolt hole d h in equations (179) and (181) would lead to the determination of plate thicknesses ti similar to those obtained with Murray Model.
2
2
47
2
(180)
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Table 6 Summary of Internal and External Work for the Various Base Plate Configurations (refer to figures of Section 5.4.7. to view the yield line patterns considered) Section / No. Bolts H--shaped section 2--bolts H--shaped section 4--bolts (a) H--shaped section 4--bolts (b) H--shaped section 4--bolts (c) H--shaped section 4--bolts (d) H--shaped section 4--bolts (e) Channel 2--bolts
Wi
Ôm p
Channel 4--bolts (c) Channel 4--bolts (d) Channel 4--bolts (e) Hollow 2--bolts (a) Hollow 2--bolts (b) Hollow 4--bolts (a) Hollow 4--bolts (b)
48
Ôm p
2bfc1 − 2d h 4y +b y
2Ôm p
2bfc1 − 2d h 4y +b y
fc1
fc1
Ôm p
2N*b
Ôm p
bfc1 − 2d h 4a + 2s p − 2d h + b ab s
2N*b
Ôm p
4bfc1 − 2dh 2y +b y
4Ôm p
Ôm p
fc1
2bfc1 − 2d h 2y +b y
fc1
fc1
2N*b
Ôm p
Ôm p
2bfc1 − 2dh 4ab + 2s p − 2d h + ab s
2N*b
4
4s2 − 2d h 2y + s p + s y 2
l Ôm p s i 2
s p 2
d c1 , (2b fc1 --d h)b fc1 2
y ≤ a b,
(2bfc1 − d h)bfc1
sp 2
y ≤
s p 2
min ab, (2b fc1 --d h)bfc1
min ab,
s N*b s 1
4s2 − 2d h 2y +s y 2
2
2bfc1 − d h s 2
(2s2 − dh)s2
2y ≤ l i
s N*b s 3
l Ôm p s i Ôm u
bfc1
(2bfc1 − dh)bfc1
2N*b s b fc1
4bfc1 − 2d h 2y + s p + b y
Ôm u
y ≤
b fc1 --d h s 2
min ab,
min
sp 2
b fc1 - d h b fc1 2
min ab,
2N*b s b fc1
4bfc1 − 2d h 4y + 2s p − 2d h + y s
d h
2
y ≤ a b,
bfc1
fc1
d h
b fc1
2N *b s b fc1
4bfc1 --2d h 4b --2d 2y+2a + fc1y h + b b ab
Ôm p
b fc1 --d h b fc1 2
2
N*b s b fc1
bfc1
4N*b s b fc1
2bfc1 − 2d h 4y + 2s p − 2d h + y s
d c1 , 2
Restraints
− −
4N*b s b fc1
2b fc1 − 2d h 4y + 2s p + b y fc1
min
4N *b s b fc1
fc1
Ôm p
y
2N*b s b fc1
2bfc1 --2dh 2bfc1 --2d h 4y+4ab + + y ab b
Channel 4--bolts (a) Channel 4--bolts (b)
We
4
s 2N*b s 1 2
(2s2 − d h)s2
2y + s p ≤ l i
s 2N *b s 3 4
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
12. APPENDIX C -- Determination of Embedment Lengths and Edge Distances
The tensile capacity of the anchor bolt is determined in accordance with Clause 9.3.2.2. of AS 4100 as follows:
The recommended guidelines regarding the minimum embedment lengths and concrete edge distances are here derived in a similar manner as carried out in references [39] and [47]. The guidelines derived in [39] are also recommended in [21] and [26]. Differences between the derivations carried out here and those presented in references [39] and [47] are noted. C.1
MINIMUM EMBEDMENT LENGTH OF ANCHOR BOLTS
The recommended model requires the anchorage system (anchor to concrete connection) to fail in a ductile manner. This is achieved by ensuring that the concrete capacity is greater than the tensile capacity of the anchor bolt. [2] Minimum embedment lengths are here derived, similarly to [39], for isolated anchor bolts. Anchor bolts in bolt groups might require longer embedment lengths due to overlapping of the concrete failure envelopes. The calculation of the concrete capacity is based on the procedure described in the recommended model. The concrete cone projected area is calculated ignoring the area of the bolt calculated using the nominal bolt diameter df . In [39] the projected area is calculated ignoring the area of a circle equivalent to the projected area of a heavy hexagonal head. Comparing the ratios L d∕d f (where L d is the minimum embedment length required and d f is the nominal bolt diameter) regarding the same types of bolts, the results obtained here appear to be of theorder of 1% more conservative than theones obtained in [39]. The further simplification of simply considering the cone as starting at the embedded end of the anchor bolt has been adopted in reference [47]. The concrete capacity is calculated as follows: ÔN cc = Ô 0.33 f ′ c A ps
(183)
where: Ô = 0.7 (based Ô required for Clause 9.2.3 of AS 3600) instead of 0.65 as adopted in references [39] and [47]
− =
d A ps = π L d + f 2
= π(L 2d + d f L d)
49
2
π
d f 2
N tf = A sf uf
(184)
where: A s = tensile stress area in accordance with AS 1275 [9] The minimumembedment length is calculated equating equations (183) and (184) as follows:
= A sf uf
Ô0.33 f ′ c π L 2d + d f L d
(185)
and solving for L d: L d =
− d f + d2f + 4γ 2
≥ 100
(186)
where:
γ =
f uf A s
Ô0.33 f ′ c π
The minimum embedment lengths derived and recommended in [39] have been calculated adding an additional safety factor of 1.33. The recommended embedment lengths recommended here do not include the additional safety factor of 1.33 (similarly to reference [47]). For completeness the embedment lengths have been here calculated with and without the safety factor of 1.33. The calculation of the minimum embedment lengths for anchors with different bolts tensile strengths and for different concrete strengths is carried out in Tables 7 and 8 in order to explicitly show how this additional safety factor of 1.33 introduced in references [39] is incorporated in the results. The tabulated results are smaller than those presented in reference [47] due to the different procedure utilised to determinetheprojectedareaevenifherea Ô equalto0.7 has been adopted. Including the additional factor of safety Ô sf = 1.33 recommended in reference [39] equation (186) can be re--written as : L d = Ô sf
2
− d 2f + d2f + 4γ 2
≥ 100
(187)
where: Ô sf = 1.33 f uf A s
γ =
Ô0.33 f ′ c π
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Table 7 Minimum embedment lengths for Grade 4.6 bolts and Grade 250 rods (f uf = 400 MPa) Bolt Type
df mm
A s mm2
f’ c MPa
L d mm
Min ratio L d /df
1.33 L d
Table 9 Grade 4.6 bolts and 250 grade rods where Ô sf is a safety factor introduced in reference [39]
1.33 L d /df
Ô sf
mm
Ld
1
f ′ c (MPa) 20
9 df
M12
12
84.3
20
100.0
8.4
127.8
10.7
1
25
9 df
M16
16
157
20
131.3
8.2
174.7 10.9
1
32
9 df
M20
20
225
20
164.1
8.2
218.2 10.9
1.33
20
12 df
M24
24
324
20
196.9
8.2
261.9 10.9
1.33
25
11 df
M30
30
519
20
248.4
8.3
330.3
11.0
1.33
32
10 df
M36
36
759
20
299.8
8.3
398.8
11.1
M12
12
84.3
25
100.0
8.4
120.5
10.0
M16
16
157
25
123.8
7.7
164.7 10.3
M20
20
225
25
154.6
7.7
205.7 10.3
M24
24
324
25
185.6
7.7
246.9 10.3
M30
30
519
25
234.1
7.8
311.4
M36
36
759
25
282.6
7.9
375.9 10.4
M12
12
84.3
32
100.0
8.4
112.8
9.4
M16
16
157
32
115.9
7.2
154.2
9.6
M20
20
225
32
144.8
7.2
192.6
9.6
M24
24
324
32
173.8
7.2
231.2
9.6
M30
30
519
32
219.3
7.3
291.6
9.7
M36
36
759
32
264.7
7.4
352.1
9.8
10.4
Table 8 Minimum embedment lengths for Grade 8.8 bolts (f uf = 830 MPa except f uf = 800 MPa for M12 bolts ) Bolt df Type mm
A s mm2
f’ c MPa
L d mm
Min ratio L d /df
1.33 L d
Table 10 Grade 8.8 bolts where Ôsf is a safety factor introduced in reference [39]
1.33 L d /df
mm
M12
12
84.3
20
138.3
11.5
183.9
15.3
M16
16
157
20
192.5
12.0
256.1
16.0
M20
20
225
20
240.5
12.0
319.9
16.0
M24
24
324
20
288.7
12.0
384.0
16.0
M30
30
519
20
364.1
12.1
484.2
16.1
M36
36
759
20
439.5
12.2
584.5
16.2
M12
12
84.3
25
130.5
10.9
173.5
14.5
M16
16
157
25
181.7
11.4
241.6
15.1
M20
20
225
25
226.9
11.3
301.8
15.1
M24
24
324
25
272.4
11.4
362.3
15.1
M30
30
519
25
343.5
11.5
456.9
15.2
M36
36
759
25
414.7
11.5
551.5
15.3
M12
12
84.3
32
122.3
10.2
162.7
13.6
M16
16
157
32
170.3
10.6
226.6
14.2
M20
20
225
32
212.8
10.6
283.0
14.2
M24
24
324
32
255.4
10.6
339.7
14.2
M30
30
519
32
322.1
10.7
428.4
14.3
M36
36
759
32
388.8
10.8
517.1
14.4
C.2
Ô sf
f ′ c (MPa)
Ld
1
20
13 df
1
25
12 df
1
32
11 df
1.33
20
17 df
1.33
25
16 df
1.33
32
15 df
MINIMUM CONCRETE EDGE DISTANCES - Anchor bolt subject to tension
[2] provides a design procedure to determine the minimum concrete edge distances to avoid lateral bursting of the concrete as discussed in the literature review of anchor bolts subject to tension. This has been included in the recommended model. The minimum edge distance is calculated as follows: a e = d f
f uf
6 f ′ c
(188)
The required minimum edge distances ae calculated with equation (188) are tabulated in Tables 11 and 12 for different combinations of anchor bolts and concrete strengths.
Observing the results of Tables 7 and 8 the embedment lengths requirements can be simplifiedas shown below.
50
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Table 11 Minimum concrete edge distances for anchor bolts Grade 4.6 bolts and Grade 250 rods (f uf = 400 MPa) subject to tension Bolt type
df (mm)
M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
12 16 20 24 30 36 12 16 20 24 30 36 12 16 20 24 30 36
f’c (MPa) 20 20 20 20 20 20 25 25 25 25 25 25 32 32 32 32 32 32
ae (mm) 46.3 61.8 77.2 92.7 115.8 139.0 43.8 58.4 73.0 87.6 109.5 131.5 41.2 54.9 68.7 82.4 103.0 123.6
ae / df 3.9 3.9 3.9 3.9 3.9 3.9 3.7 3.7 3.7 3.7 3.7 3.7 3.4 3.4 3.4 3.4 3.4 3.4
Table 12 Minimum concrete edge distances for anchor bolts Grade 8.8 bolts (f uf = 830 MPa except f uf = 800 MPa for M12 bolts ) subject to tension Bolt type
df (mm)
M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
12 16 20 24 30 36 12 16 20 24 30 36 12 16 20 24 30 36
f’c (MPa) 20 20 20 20 20 20 25 25 25 25 25 25 32 32 32 32 32 32
ae (mm) 65.5 89.0 111.2 133.5 166.9 200.2 62.0 84.2 105.2 126.2 157.8 189.4 58.3 79.1 98.9 118.7 148.4 178.0
ae / df 5.5 5.6 5.6 5.6 5.6 5.6 5.2 5.3 5.3 5.3 5.3 5.3 4.9 4.9 4.9 4.9 4.9 4.9
The values of minimum edge distances required expressed in terms of d f can be summarised as follows: for Grade 4.6 bolts and Grade 250 rods a e = 4 d f when f ′ c = 20, 25 and 32 MPa for Grade 8.8 bolts
51
a e = 6 d f when f ′ c = 20 and 25 MPa = 5 d f when f ′ c = 32 MPa The recommended model requires the minimum edge distance ae to be always at least equal to 100mm as recommended in [21], [26] and [39]. Minimum edge distance recommended in reference [47] is 50mm. C.3
MINIMUM CONCRETE EDGE DISTANCES - Anchor bolt subject to shear
Guidelines on minimumedge distances to be adopted in the case of bolts in shear are provided in [2], [3], [17], [26], [39] and [47]. These are allbased on the design procedure presented in [2], [3] and [17] which requires the minimum edge distance to be calculated as (refer equation (106)): a e ≥ d f
f uf
Ô0.94 f ′ c
(189)
where: Ô = 0.65 according to references [3] and [39] = 0.85 according to references[17], [26] and [47] For completeness edge distances calculated with both values of Ô have been considered and tabulated here. It is up to designer to decide whether or not to design the anchor bolts to carry shear and to select a value of Ô. These values of ae are tabulated in tables13, 14, 15 and 16 for different combinations of anchor bolts and concrete strengths and for different values of Ô. Table 13 Minimum concrete edge distances for anchor bolts Grade 4.6 bolts and Grade 250 rods (f uf = 400 MPa) subject to shear with Ô = 0.65 Bolt type
df (mm)
M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
12 16 20 24 30 36 12 16 20 24 30 36 12 16 20 24 30 36
f’c (MPa) 20 20 20 20 20 20 25 25 25 25 25 25 32 32 32 32 32 32
ae (mm) 145.2 193.6 242.0 290.4 363.0 435.6 137.3 183.1 228.9 274.6 343.3 411.9 129.1 172.1 215.2 258.2 322.7 387.3
ae / df 12.1 12.1 12.1 12.1 12.1 12.1 11.4 11.4 11.4 11.4 11.4 11.4 10.8 10.8 10.8 10.8 10.8 10.8
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
Table 14 Minimum concrete edge distances for anchor bolts Grade 8.8 bolts (f uf = 830 MPa except f uf = 800 MPa for M12 bolts) subject to shear with Ô = 0.65 Bolt type
df (mm)
M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
12 16 20 24 30 36 12 16 20 24 30 36 12 16 20 24 30 36
f’c (MPa) 20 20 20 20 20 20 25 25 25 25 25 25 32 32 32 32 32 32
ae (mm) 205.3 278.9 348.6 418.3 522.9 627.4 194.2 263.7 329.7 395.6 494.5 593.4 182.6 247.9 309.9 371.9 464.9 557.9
ae / df 17.1 17.4 17.4 17.4 17.4 17.4 16.2 16.5 16.5 16.5 16.5 16.5 15.2 15.5 15.5 15.5 15.5 15.5
Table 15 Minimum concrete edge distances for anchor bolts Grade 4.6 bolts and Grade 250 rods (f uf = 400 MPa) subject to shear with Ô = 0.85 Bolt type M12
M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
52
df (mm) 12 16 20 24 30 36 12 16 20 24 30 36 12 16 20 24 30 36
f’c (MPa) 20 20 20 20 20 20 25 25 25 25 25 25 32 32 32 32 32 32
ae (mm) 127.0 169.3 211.6 253.9 317.4 380.9 120.1 160.1 200.1 240.2 300.2 360.2 112.9 150.5 188.1 225.8 282.2 338.7
ae / df 10.6 10.6 10.6 10.6 10.6 10.6 10.0 10.0 10.0 10.0 10.0 10.0 9.4 9.4 9.4 9.4 9.4 9.4
Table 16 Minimum concrete edge distances for anchor bolts Grade 8.8 bolts (f uf = 830 MPa except f uf = 800 MPa for M12 bolts) subject to shear with Ô = 0.85 df (mm) f’c (MPa) 12 20 16 20 20 20 24 20 30 20 36 20 12 25 16 25 20 25 24 25 30 25 36 25 12 32 16 32 20 32 24 32 30 32 36 32
Bolt type M12
M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36 M12 M16 M20 M24 M30 M36
ae (mm) 179.6 243.9 304.8 365.8 457.2 548.7 169.8 230.6 288.3 345.9 432.4 518.9 159.6 216.8 271.0 325.2 406.5 487.8
ae / df 15.0 15.2 15.2 15.2 15.2 15.2 14.2 14.4 14.4 14.4 14.4 14.4 13.3 13.6 13.6 13.6 13.6 13.6
Re--arranging equation (189) the ratios ae∕df for differentcombinations of concrete andbolt strengths for different values of Ô are obtained as shown below. Table 17 Grade 4.6 bolts and 250 Grade rods Ô
0.65 0.65 0.65 0.85 0.85 0.85
f ′ c (MPa)
ae
20 25 32 20 25 32
13 df 12 df 11 df 11 df 10 df 10 df
Table 18 Grade 8.8 bolts f ′ c (MPa)
Ô
0.65 0.65 0.65 0.85 0.85 0.85
20 25 32 20 25 32
ae
18 df 17 df 16 df 16 df 15 df 14 df
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
13. APPENDIX D -- Design Capacities of Equal Leg Fillet Welds
14. APPENDIX E -- Design of Bolts under Tension and Shear
Table 19 Category SP, Ô =0.8, k r=1.0
Table 23 Design Capacities Commercial Bolts 4.6/S Bolting Cat. f uf =400MPa, Ô =0.8
Weld size (mm)
t w 2 3 4 5 6 8 10 12
Design Capacity per unit length of fillet weld except for RHS/ SHS with thickness less than 3 mm (kN/mm) E41XX/W40X E48XX/W50X 0.278 0.326 0.417 0.489 0.557 0.652 0.696 0.815 0.835 0.978 1.11 1.30 1.39 1.63 1.67 1.96 f uw=410 MPa f uw=480 MPa
tt 1.41 2.12 2.83 3.54 4.24 5.66 7.07 8.49
Table 20 Category SP, Ô =0.7, k r=1.0 Weld size (mm)
t w 2 3 4 5
tt 1.41 2.12 2.83 3.54
Design Capacity per unit length of longitudinal fillet weld in RHS/ SHS with t < 3mm (kN/mm) E41XX/W40X E48XX/W50X
0.244 0.365 0.487 0.609 f uw=410 MPa
0.285 0.428 0.570 0.713 fuw =480 MPa
Table 21 Category GP, Ô =0.6, k r=1.0 Weld size (mm) t w 2 3 4 5 6 8 10 12
tt 1.41 2.12 2.83 3.54 4.24 5.66 7.07 8.49
Design Capacity per unit length of fillet weld (kN/mm) E41XX/W40X E48XX/W50X 0.209 0.244 0.313 0.367 0.417 0.489 0.522 0.611 0.626 0.733 0.835 0.978 1.04 1.22 1.25 1.47 f uw=410 MPa f uw=480 MPa
Bolt Size
Axial Tension ÔNtf (kN)
M12
Shear (single shear) Threads included in shear plane N ÔVfn (kN)
Threads excluded from shear plane X ÔVfx (kN)
27.0
15.1
22.4
M16
50.1
28.6
39.9
M20
78.3
44.7
62.3
M24
113
64.3
89.8
M30
179
103
140
M36
261
151
202
4.6N/S
4.6X/S
Table 24 Design Capacities High Strength Structural Bolts 8.8/S, 8.8/TB, 8.8/TF Bolting Categorys, Ô =0.8 Bolt Size
Min. Tensile Strength of Bolt f uf (MPa)
Axial Tension ÔNtf (kN)
M12
800
M16
Shear (single shear) Threads included in shear plane N ÔVfn (kN)
Threads excluded from shear plane X ÔVfx (kN)
53.9
30.3
44.9
830
104
59.3
82.8
M20
830
163
92.7
129
M24
830
234
133
186
M30
830
372
214
291
8.8N/S
8.8X/S
Table 22 Minimum Fillet Weld Sizes Thickness of thickest part t (mm) t ≤ 7 7 < t ≤ 10
53
Minimum size of a fillet weld t w (mm) 3 4
10 < t ≤ 15
5
15 < t
6
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
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54
STEEL CONSTRUCTION VOLUME 36 NUMBER 2 SEPT 2002
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Casa Engineering (Qld) Pty Ltd PO Box Ge 80 Garbutt East 4814 07 4774 4666
ASI Members -- The best in Steel Fabrication Tasmania Dowling Constructions Pty Ltd 46 Formby Road Devonport 7310 03 6423 1099 Haywards Steel Fabrication & Construction PO Box 47 Kings Meadows 7249 03 6391 8508
Monks Harper Fabrications P/L 25 Tatterson Road, Dandenong South 3164 Preston Structural Steel 140--146 Barry Road, Campbellfield 3061
Victoria Alfasi Steel Constructions 12--16 Fowler Road, Dandenong 3175
GVP Fabrications Pty Ltd 25--35 Japaddy Street, Mordialloc 3195
03 9794 9207
AMS Fabrications Pty Ltd 18 Healey Road Dandenong 3175 03 9706 5988 Bahcon Steel Pty Ltd PO Box 950 Morwell 3840
03 5134 2877
Downer PTR 195 Wellington Rd Clayton 3168
03 9560 9944
03 9587 2172
03 9794 0888
03 9357 0011
Riband Steel (Wangaratta) Pty Ltd 69--81 Garden Road Clayton 3168 03 9547 9144 Rosebud Engineering 13 Henry Wilson Drive, Rosebud 3939
Devaugh Pty Ltd 12 Hale St Bunbury 6230
08 9721 3433
Fremantle Steel Fabrication Co PO Box 3005 Jandakot 6964
08 9417 9111
Highline Building Constructions 9 Felspar Street Welshpool 6106
08 9451 5366
H’var Steel Services Pty Ltd 56 Cooper Rd Jandakot 6164
08 9414 9422
Italsteel W.A. PO Box 206 Bentley 6102
08 9356 1566
JV Engineering (WA) Pty Ltd 159 Mcdowell Street Kewdale 6105 08 9353 3377 03 5986 6666
Leblanc Comm\ Aust P/L PO Box 40 Belmont 6984
08 9277 8866
Stanley Welding 23 Attenborough Street, Dandenong 3175
03 9555 5611
Pacific Industrial Company PO Box 263 Kwinana 6966
08 9410 2566
F & B Skrobar Engineering Pty Ltd PO Box 1578 Moorabbin 3189 03 9555 4556
Stilcon Holdings Pty Ltd PO Box 263 Altona North 3025
03 9314 1611
Park Engineers Pty Ltd PO Box 130 Bentley 6102
08 9458 1437
Fairbairn Steel Pty Ltd PO Box 2057 Seaford 3198
Vale Engineering Co Pty Ltd 170 Gaffney Street Coburg 3058
03 9350 5655
Scenna Constructions 43 Spencer Street Jandakot 6164 08 9417 4447
G F C Industries Pty Ltd 42 Glenbarry Road, Campbellfield 3061 Geelong Fabrications Pty Ltd 5/19 Madden Avenue, North Shore Geelong 3214
03 9786 2866
United KG PO Box 219 Kwinana 6167
Western Australia 03 9357 9900
C Bellotti & Co PO Box 1284 Bibra Lake 6965
03 5275 7255
Cays Engineering Lot 21 Thornborough Road, Mandurah 6210
08 9434 1442
08 9581 6611
08 9499 0499
Uniweld Structural Co Pty Ltd 61A Coast Road Beechboro 6063 08 9377 6666 Wenco Pty Ltd 1 Ladner Street Oconnor 6163
08 9337 7600
ASI Manufacturing Members -- The best quality steel BHP Steel BHP Tower, 600 Bourke Street, Melbourne VIC 3000 (GPO Box 86A, Melbourne 3001)
03 9609 3756
Bisalloy Steels Pty Ltd Resolution Drive, Unanderra NSW 2526 (PO Box 1246, Unanderra 2526) 02 4272 0444 Commonwealth Steel Company Limited Maud Street, Waratah NSW 2298 (PO Box 14) 02 4967 0457
OneSteel Pty Ltd Level 23, 1 York Street, Sydney NSW 2000 (GPO Box 536) 02 9239 6666
G A M Steel Pty Ltd Lynch Road, Brooklyn VIC 3025 (PO Box 159, Altona North 3025)
Palmer Tube Mills (Aust) Pty Ltd 46 Ingram Road, Acacia Ridge QLD 4110 (PO Box 246, Sunnybank 4109) 07 3246 2600
Midala Steel Pty Ltd 49 Pilbara Street, Welshpool WA 6106 (PO Box 228, Welshpool 6986) 08 9458 7911
Smorgon Steel Group Ltd Ground Floor, 650 Lorimer Street, Port Melbourne VIC 3207
Southern Steel Group 319 Horsley Road, Milperra NSW 2214 (PO Box 342, Panania 2213) 02 9792 2099
03 9673 0400
Graham Group 117--151 Rookwood Road, Yagoona NSW 2199 (PO Box 57) 02 9709 3777
Stramit Industries 6--8 Thomas Street, Chatswood NSW 2067 (PO Box 295, Chatswood 2057) 02 9928 3600
Industrial Galvanizers Corporation Pty Ltd 20--22 Amax Avenue, Girraween NSW 2145 (PO Box 576, Toongabbie 2146) 02 9636 8244
J Blackwood & Son Steels and Metals Pty Ltd 165--169 Newton Road, Wetherill Park NSW 2164 (PO Box 6427) 02 9203 1100
Martin Bright Steels Cliffords Road, Somerton VIC 3062 (PO Box 39 MDC) 03 9305 4144
Coil Steels Group Pty Ltd 16 Harbord Street, Granville NSW 2142 (PO Box 166) 02 9682 1266
03 9314 0855
Smorgon Steel Distribution 88 Ricketts Road, Mount Waverley VIC 3149 (PO Box 537) 03 9239 1844 Metalcorp Steel 103 Ingram Road, Acacia Ridge QLD 4110
07 3345 9488
OneSteel Distribution Cnr Blackwall Point & Parkview Roads, Five Dock NSW 2046 (PO Box 55) 02 9713 0350