Jib Foundation Preliminary Design

Project Name: Jib Foundation Design Doc Title: Sizing and Stability Check

By : JEY Checked: CCO

Revision: A Date: 12.04.17

1.0 General 1.1 REFERENCE 1) Civil/Structural Civil/Stru ctural Design Philosophy 2) BS 8110: Structural Use of Concrete 3) BS 8004: Code of Practice for Foundation 4) Jib Foundation Drawings

Fig. 1 - Jib Crane GA 1.2 Desig Desig n Data Reaction Loading 10 mT Crane base rxn moment 10 mT Crane Vertical Rxn Base Size Base length Base width Base Depth Depth u/s foundation Soil/Material Data Allowable Allowable soil beari bearing ng capacity capacity Unit weight of soil Unit weight of concrete Unit weight of water Unit weight of fill (submerged) Coefficient of friction μ Unit weight of concrete (submerged) Concrete strength f cu cu Steel strength Min overall FOS for stability Ultimate Limit State FOS

41kNm 17kN

1.70m 1.70m 1.00m 1.00m

120kN/m2 19kN/m3 24kN/m3 10kN/m3 9kN/m3 0.3 14kN/m3 25N/mm2 460N/mm2 1.67 1.6

Fig. 2: Section




2.0 Geotechnical Stability 2.1 Preliminary Foundation sizing Ar ea of b ase 2 (m ) 0.80 2.89

Required Adopted

Base Length L (m) 0.89 1.70

Base Width W (m) 0.89 1.70

Base Depth H (m) 0.5 1.00

Crane Rxn Loads Load Type Vertical Rxn Moment Horizontal Rxn

Value (kN,kNm) 57.20 40.50 0.00

2.2 Final Foundation Size and Weight Item Base

L 1.70m

B 1.70m

H 1.00m

Self Weight of Foundation Item Base Total

Dry 69.36 69.36

Submerged 40.46 40.46

2.3 STABILITY CHECK Case I: 1.0 (Dry ) Overturning Overturning Moment, Mo = Total Axial Load, W t = W t (dry) + D =

41kNm 127kN

Eccentricity, e = Mo X sin45/W t =

0.23m

Factor of Safety against overturning =(Wt X L/2)/Mo =

2.66 > 1.5

O.K

Bearing 2

Equivalent uniform pressure = W t/(L-2e) =

81 kN/m2 < 120

O.K

Horizontal Sliding Horizontal Force S f

0kN

Frictional Force Fr = μ X (SW tSub + D)

N/A

Factor of Safety against sliding = F r / Sf

N/A 1.50

Max. Allowoable FOS against sliding

N/A

Bearing 2 Pressure (kN/m ) 120.00 33.05 O.K




Case II: 1.0 (Submerg ed) Overturning Overturning Moment, M o =

41kNm

Total Axial Load, W t = W t (Sub) + D =

98kN

Eccentricity, e = Mo X sin45/W t =

0.29m

Factor of Safety against overturning =(W t X L/2)/Mo = M ax. A llowoable FOS against overturning =

2.05 >1.5 1.50

O.K

Bearing 2

Equivalent uniform pressure = W t/(L-2e) =

63 kN/m2 < 120

O.K

Horizontal Sliding Sliding Force Sf = Wk =

0kN

Frictional Force Fr = μ X (SW tSub + D) =

N/A

Factor of Safety against sliding = F r / Sf =

N/A 1.50

Max. Allowoable FOS against sliding =

N/A



3.0 Structur al Design Bolt array Diameter =

0.67m

Unit Self Weight of foundation w =

f =

1.60

Mu =

f X Mo =

65kNm

Wu =

f X Wt =

156kN ``

Parftial FOS, For ULS

e = Mu X sin45/Wu = 2

0.29m

Equivalent uniform pressure P eq = Wt/(L-2e) =

126kN/m2

3.1 Reinforcement Designing for ULS Bottom rei nforcement 2 Design Ult. Moment M = (Peq - (H*24))*(L/2-D/2) /2 =

14kNm/m

Cover to reinforcement c =

50.00mm

=

16.00mm

Effective depth d = H-c- -0.5  =

926.00mm

Take d =

925.00mm

Allow for Y16 bars

2

K = M/fcubd 0.000632482 La = 0.5+(0.25-K/0.9) 1.00 Z = la X d 879.70mm Area of reinforcement As =M/0.95*fy*Z = 35mm2/m Minimum reinforcement = 0.13%bd =

120mm2/m

Provide norminal Reinorcement Y16@200cc both ways for ease of construction Top reinforcement 2 Design Ult. Moment M = 1.4*(H*24)*(L/2-D/2) /2 =

4kNm/m

Provide norminal Reinorcement Y16@200cc both ways Shear 2 2 Shear Force V = (Peq*(L/2-D/2) /2)-(H*24*(L/2-D/2) /2) =

14kN/m width

<0.8*f cu = 3.92N/mm2 Norminal shear stress v = V/bvd = 0.01N/mm2 100As/bvd =

<0.8*f cu

0.00

From table 3.8 BS8110 v c = 0.36N/mm2 vc>v hence depth provided is adequate; hence no shear reinforcement required


Jib Foundation Preliminary Design

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