ME538-2-Joint & Weld Types, Selection & Symbols

2009/01/14

Weld Joints

ME 538 – Welding Design, Fabrication & Quality Control

Weld Types

[Cary: Modern Welding Technology, 1998]

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Fillet Welds

correction


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Groove Welds Directing electrode at side wall of the joint will help ensure good sidewall fusion in deep welds

Provide base metal for root and prevent blow through Ensure full penetration


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Examples of Groove Welds

Edge Weld ME 538 – Welding Design, Fabrication & Quality Control

CWA W59 Appendix E

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Butt Joint & Applicable Weld Types

[AWS Handbook, 9th ed., Vol.1, Chap.5, and CSA W59-M1989 Standard] ME 538 – Welding Design, Fabrication & Quality Control

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Corner Joint & Applicable Weld Types


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T – Joint & Applicable Weld Types


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Lap Joint & Applicable Weld Types


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Edge Joint & Applicable Weld Types


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2009/01/15

Standard Locations of Elements of a Welding Symbol


[AWS Handbook, Vol. 1, also ANSI/AWS Standard A2.4-98]

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5

The Weld Joint & Reference Line



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Groove Weld Symbols


[AWS Handbook, Vol. 1, also ANSI/AWS Standard A2.4-98] 12

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Fillet and Other Weld Symbols



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Supplementary Symbols

Finishing Codes ME 538 – Welding Design, Fabrication & Quality Control


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Welding, Brazing & Soldering Process Designations


[AWS Handbook, Vol. 1, Chap. 8]

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Example: Welding Symbols with Multiple Reference Lines



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Example: Welding Symbols for Intermittent Fillet Welds 1/4 1/4

1/4 1/4

All units are Inches ME 538 – Welding Design, Fabrication & Quality Control


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Example: Brazing & Soldering Symbols

FS



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Selection of the Joint Type The most appropriate joint type for an application will depend on: 1. 2. 3. 4.

The required part geometry The ability of the joint to transfer the load The welding position Accessibility of the joint for welding and inspection 5. Joint preparation and welding costs 6. Governing code and qualification requirements (Fabrication) ME 538 – Welding Design, Fabrication & Quality Control

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Selection of Weld Types Selection of the most appropriate weld type for a joint is based on the ability of the weld to safely transfer the load in service and on the cost of making the weld. The designer can choose: 1. Plug or slot welds 2. Fillet welds for jjoints subject j to lower stress or less demanding service conditions 3. Full penetration groove welds for joints in critical service conditions, e.g., high stress or cyclic loading ME 538 – Welding Design, Fabrication & Quality Control

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Prohibited Applications of One One--sided Fillet Welds

F



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Example: CSA W59 Required Fillet Lap Joints in Tension

F F


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Welding Positions

More Favored

Less Favored

Easier, Faster, Higher Deposition Rates, L Less Cost

Harder, Slower, Lower Deposition Rates, More Cost



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Groove & Fillet Welds Positions


[CSA W59-M1989 Standard]

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Pipe Welding Positions



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Examples of Poor Weld Accessibility POOR

POOR

POOR

BETTER

POOR BETTER

POOR ME 538 – Welding Design, Fabrication & Quality Control

[J. Hicks, A Guide to Designing Welds, 1989]

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More Examples of Weld Accessibility


[J. Hicks, A Guide to Designing Welds, 1989]

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Economics of Groove Welds • Square groove welds: Lowest Cost but thickness is limited – From one side 1/4” to 3/8” (6 to 10 mm) max. – From both sides 1/4 1/4” to 1/2” 1/2 (6 to 12 mm) max.

• Single V or single bevel welds: – Thickness is equal or less than 3/4” (18 mm)

• Double V or double bevel welds: – Up to 40 mm gives lowest distortion

• Single and double J groove welds: – Less weld metal is required, but requires machining operation

• Single and double U groove welds: – Less weld metal is required, but requires machining operation ME 538 – Welding Design, Fabrication & Quality Control

Welding & Metal Fabrication, Mar. 1977, pp. 85-91

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Rule of Thumb for Fillet Welds Weld strength is proportional to the weld throat area Throat Area = 0.707 S x L To double the strength:

Weld Throat

1) Double the size, S, but the volume of weld metal required increases in proportion to S2, i.e., the volume of weld metal required increases by 4 times! 2) Double the length and the volume only doubles

Rule of Thumb for Fillet Welds: Always make a fillet weld small and long Note: there are usually minimum allowed fillet weld sizes in codes due to metallurgical limitations ME 538 – Welding Design, Fabrication & Quality Control


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Minimum weld sizes in steel welding codes are to avoid formation of martensite at the fusion boundary due to high cooling rates in small welds on large plates.

2009/01/21

Volume of Weld Metal for TT-Joints


[AWS Welding Handbook, Vol. 1 (9th Ed.)]

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Equal Throat/Strength TT-Joint Welds



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Typical Corner Joint Designs


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Corner Welds => D&E groove welds used for larger plates *E can be a problem with structural steel due to lamilar tearing

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Deposition Rates



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Deposition Rates SMAW

GMAW

FCAW

SAW



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EXXXX

UTS

Additives Position

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Operator Factor



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2009/01/22

Some General Weld Joint Design Guidelines 1. Designed weld strength must be greater than or equal to the required joint strength 2. Use standardized jjoints whenever p possible 3. Use complete penetration welds for joints in tension or fatigue (CP) 4. Always choose a joint preparation that minimizes machining costs and the amount of weld metal and welding time required 5. Always use the smallest fillet or partial penetration weld ld size i allowed ll d 6. Use intermittent fillet welds whenever possible, but be aware of minimum length & pitch requirements 7. Always try to reduce the number of welds required 8. Avoid overwelding ME 538 – Welding Design, Fabrication & Quality Control

[Cary & Helzer: Modern Welding Technology, 2005]

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Some General Weld Joint Design Guidelines 9. Remove material in butt joints between different thicknesses for better transition (don’t add material) 10. Try to avoid using double T or cruciform joints 11. Always bevel the thinner member of corner joints 12. Avoid plug or slot welds in highly stressed members 13. Use flat welding position whenever possible 14 Welding in an enclosed area must be well ventilated 14. 15. Always ensure accessibility 16. Weld symbols must be clear and unambiguous



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Practical Welding Design Principles 1. Secondary Member: There is no secondary member in a welded structure 2. Transverse Forces: Always provide a path so that a transverse load can enter part/parts of the weldment that lie parallel to the load 3. Force Redirection: Always provide a component p when a force changes g direction 4. Weld Details vs. Welder’s skill: Always avoid a joint design where the skills of the welder determine the weld’s integrity ME 538 – Welding Design, Fabrication & Quality Control


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Examples: CSA W59 Minimum Allowed Weld Sizes for Welded Steel Construction


[CSA W59-M1989 Welded Steel Construction] 39

Examples: Secondary Members Backing bars butted together => Incipient crack Discontinuous Backing Bar

Solution: Weld backing bars together or use continuous length ME 538 – Welding Design, Fabrication & Quality Control

Keep weld away from joint 40

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Examples: Transverse Forces A force applied transverse to a member will ultimately enter a p portion of the section that lies p parallel to the applied force



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Provision for Transverse Force

Poor Design Better Design ME 538 – Welding Design, Fabrication & Quality Control


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Example: Attachments with Transverse Loads



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Example: Designing for Transverse Forces

Poor Design

Better: Add External Gusset Plates ME 538 – Welding Design, Fabrication & Quality Control

Best: Add Internal Stiffener Plates [Blodgett, Eng. J. - AISC, 1980, 17(4), pp. 106-119]

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Force Redirection


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Weld Details vs. Welder’s Skill

Poor Design ME 538 – Welding Design, Fabrication & Quality Control

Better Design O.W. Blodgett, Eng. J.-AISC, 17(4),1980,106-119

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Weld Details vs. Welder’s Skill

A weld must start and stop so no crater is left at points of high stress (AWS Standard D1.1 and CSA W59 Welded Steel Construction)


O.W. Blodgett, Eng. J.-AISC, 17(4),1980,106-119

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ME538-2-Joint & Weld Types, Selection & Symbols

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