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Topic 8: Welding terms and symbols
Introduction
This topic enables you to understand and apply welding symbols and welding terms.
All trades use their own unique terminology where words and/or symbols take on
specific meanings that apply specifically to that trade.
The use of standard language eliminates misunderstandings and allows people in the
fabrication and allied engineering industries to communicate effectively with each
other.
Without such communication mistakes will be made due to a lack of understanding
and incorrect interpretation.
To improve communications, the Standards Association of Australia (SAA) issue a
glossary of specialised words for use with all welding operations.
This terminology can be confidently used anywhere in the country and across all
engineering fields to minimise mistakes arising from incorrect interpretation.
These common terms help workplace communications by providing a standardised
trade language.
Welding terms and symbols can be found in two standards:
AS 2812-2005 Welding, brazing and cutting of metals — Glossary of terms
AS 1101.3—2005 Graphical symbols for general engineering — Welding and nondestructive examination.
The terms and definitions used in this topic are commonly used in welding and
fabrication industries and are extracted from the above Standards.
Types of welds
Butt welds: are where weld metal is mostly confined to the thickness of the
parts being joined. Parts may be in the same plane as each other or meet at
an intersection.
Figure: Butt weld
Butt welds are used to join sheet, plate, pipe and other hot rolled sections.
This type of joint has the advantage of strength without changing the profile of the
structure.
Butt weld joints can be designed for full penetration in order to achieve maximum
joint strength.
Fillet welds: are triangular in shape and most of the weld metal is
external to the parent metal. A fillet weld can be found in joint various
configurations including:
Figure: Tee fillet weld
Figure: Corner fillet weld
Figure: Lap fillet weld
Fillet welds, in particular the tee fillet joint, account for the majority of
welds made in fabrication and construction industries.
They suit most weld joints used in structural steel construction.
They require less edge preparation, are cost effective and are quickly
and easily assembled.
Figure: Parts of a weld
Parent metal: the metal being welded together or surfaced.
Weld face: the visible surface of a completed weld.
Figure: Weld face
Weld toe: the junction of the parent metal
and the weld face or weld face to weld face
in a multiple run weld.
Root: the innermost part of a weld directly opposite the weld face.
Figure: Root
Root penetration: the amount by which the weld metal penetrates past the edge
preparation.
Figure: Root penetration
Weld reinforcement: the amount the weld face extends beyond the
parent metal in a flat butt weld or beyond a line joining the toes of a
fillet weld.
Leg length: the distance from the original root of a fillet weld
preparation to the toe of the weld.
Figure: Leg length of a weld
Heat affected zone (HAZ): the area adjacent to the metal melted by the heat of welding which has
become metallurgically changed.
Figure: Heat affected zones of a weld
Throat thickness: the distance from the root of a weld to the face of the weld.
Fusion Zone: area of parent metal that has been fused in the welding process.
Parts of a weld preparation
Fillet welds require very little preparation apart from squaring and cleaning both edges and
fusion faces.
Edge preparation terminology is generally limited to the preparations for butt welds as
indicated in the diagram below.
A welding procedure, when used, will provide guidelines as to the minimum and maximum
included angle, root gap and root face.
Figure: Parts of a single V butt preparation
Weld sizes
Fillet welds
The size of a fillet weld is determined by the finished weld’s leg length.
To comply with normal design requirements, the weld must also have a throat thickness equal
to 70% or 0.7 of the required leg length.
For example, a metre fillet weld of 10 mm leg length should have a throat thickness of 7 mm.
Figure: Leg length and throat thickness
However, for concave and convex bead shapes the size of the weld can change. In the examples
shown below, the leg lengths are the same, but due to the shape of the weld face, their throat
thicknesses are different.
If weld size is specified by leg length then the concave fillet welds throat thickness, as
illustrated above, will be less than 70% of the required leg length.
In this instance the finished weld will be under size and under strength.
However, concave weld shapes are better suited for transmitting stress in loaded structures
because of its gradual change of direction. If this type of profile is permitted on a job then the
throat thickness has to match design specifications and the leg length will need to be greater.
The convex fillet weld, as shown above is more likely to be produced using the GMAW or MMAW
process using hydrogen controlled electrodes.
The extra weld metal outside the mitre line does not contribute to the strength of the weld;
however a small amount of reinforcement is acceptable.
Excessive reinforcement can cause problems with stress concentration along the weld toes.
Butt welds
On full penetration butt welds, the depth of weld should at least be equal to the thickness of the
metal being joined.
On partial penetration welds the depth of the weld may be stated on the weld procedure specification.
Reinforcement height does not form part of a butt welds size.
Reinforcement should not extend more than 2 mm beyond either side of the edge preparation
for a 10 mm plate thickness.
Figure: Full and partial penetration butt welds
Weld positions
The type of weld is indicated by a letter:
•G—signifies a grooved or butt weld
•F—signifies a fillet weld.
The position of weld is indicated by a numeral:
•1—signifies a flat or downhand weld
•2—signifies a horizontal weld
•3—signifies a vertical weld
•4—signifies an overhead weld
•5—signifies fixed position pipe axis horizontal
•6—signifies fixed position pipe axis 45o to the horizontal.
Examples of weld types and positions include:
Figure: 1G or flat butt weld
Figure: 1F or flat fillet weld
Figure: 2F or horizontal fillet weld
Figure: 2G or horizontal butt;
Figure: 3F or vertical fillet weld
Figure: 3G or vertical butt weld
Figure: 4G or overhead butt weld
Figure: 4F or overhead fillet weld
Figure: 5G or vertical butt, pipe in horizontal axis
Figure: 6G or vertical butt, pipe in 45o axis
Welding symbols
Engineering drawings must convey all information needed to fabricate metal products. Since space is
limited on drawings, a system of symbols has been devised to provide weld joint information.
For example, welding symbols provide details relating to the side of the joint to be prepared and
welded, as well as the type of joint preparation and weld size can be clearly indicated by the use of
welding symbols.
In general, a welding symbol is the combination of an arrow and reference line. The type of weld is
depicted as a stylised drawing and is located on the reference line.
Further information such as location, shape, edge preparation, size and length of the weld can also be
added.
A basic welding symbol consists of an arrow line, horizontal reference line and a symbol
depicting the type of weld and its location.
Figure: A basic welding symbol
Use of symbols on engineering and fabrication drawings
The following diagrams indicate how symbols are used on engineering and fabrication drawings.
•Weld symbol positioned under the reference line
Figure: Weld symbol positioned under the reference line and completed weld
The triangular weld symbol positioned under the reference line indicates a fillet weld is required on
the side of the joint the arrow is pointing towards.
The diagram above shows how the completed joint would look after welding.
•Weld symbol positioned above the reference line
This example below shows the weld symbol is located above the reference line. This indicates
a fillet weld is required on the other side of the joint the arrow is pointing towards.
The diagram on the right shows how the completed joint would look after welding.
Figure: Weld symbol positioned above the reference line and completed weld
•Weld symbol positioned above and below the reference line
In this example the weld symbol is positioned above and below the reference line.
This indicates a fillet weld is required on both sides of the joint.
The diagram on the right shows how the completed joint would look after welding.
Figure: Weld symbol positioned above and below reference line and completed weld
•Weld size symbol
The numeral six (6) shown next to the fillet weld symbol indicates a 6 mm leg length fillet
weld is required on the arrow side of the joint.
This method of advising weld leg length size may be necessary if other welds on a fabricated
structure are to be a different size.
Figure: Welding size symbol
Site weld symbol
The flag located at the junction of the arrow line and reference line is the field weld symbol and
indicates the weld is to be completed.
Figure: Site weld symbol
A tail at the end of the reference line is used when important information needs to be added to the welding
symbol. Information may include:
•
the welding process to be used
•
weld procedure specification data.
Figure: Tail symbol with important information for welding process
Weld all round symbols
The circle located at the junction of the arrow line and the reference line is the weld-all-round symbol.
It indicates the weld is to be made all around the vertical member as shown in the diagram below.
The diagrams on the right show how the completed joint would look after welding.
Figure: Weld all round symbols
completed weld
Butt weld symbol
The inverted vee shape positioned under the reference line indicates a single vee butt weld is
required on the side of the joint the arrow is pointing towards.
This configuration informs the operator the butt weld is to be done in the 1G position (flat butt
weld).
Supplementary symbols used in association with this butt weld symbol may include the type of
weld face finish required, or back-gouging and welding of the root run.
Figure: Butt weld symbol
Common butt weld symbols
The following table summarises the weld symbols used on various types of preparation.
Table: Common butt weld symbols
Welding symbol summary
The following diagram summarise the various symbols used in engineering and fabrication drawings.
Figure: Summary of welding symbols