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SMAW Welding Section 8 Unit 26

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1 SMAW Welding Section 8 Unit 26
TECHNICAL EDUCATION AND SKILLS DEVELOPMENT AUTHORITY REGIONAL TRAINING CENTER ILOILO TESDA SMAW Welding Section 8 Unit 26 Ramel T. Dulla

2 Arc Welding Safety Recognize that arc welding produces a lot of heat.
Use equipment according to manufacturers recommendations. Insure fire extinguishers are available Provide a first aid kit Use water filled containers to receive hot metal from cutting operations. Practice good housekeeping Use appropriate PPE

3 Arc Welding Safety-cont.
Insure all wiring is correctly installed and maintained. Remove or shield all combustible materials in work area. Do not use gloves or clothing which contain flammable substances Protect others from arc flash. Protect equipment from hot sparks. Use a fume collector. Never work in damp or wet area. Shutoff power source before making repairs or adjustments, including changing electrode. Don’t overload the welding cables or use cables with damaged insulation.

4 Arc Welding PPE Helmet Clothing Shade 10 or darker Face protection
Always wear safety glasses underneath Auto helmet recommended Clothing Long sleeves Button up shirt Work shoes Protective apron, sleeves, jackets or pants if available. (Fig 26-6) The darkness of the lens in the helmet is determined by the welding process and the amperage being used. SMAW , up to 250 amp GMAW

5 SMAW Process The arc temperature over 9,000 oF melts the base metal, the wire core and the coating on the electrode. The high temperature causes some of the ingredients in the flux to form a gaseous shield. The electric energy is provided by a special power source. As the weld cools slag forms on top of the weld puddle. The slag contains the impurities that were in the weld pool and it retards the cooling rate.

6 SMAW Power Supplies SMAW requires a constant current (CC) of either DC or AC. Some power supplies will supply both DC and AC. Power supply capacity determines the maximum diameter of electrode that can be used.

7 Equipment Polarity Switch Power Power Supply Cord Electrode Holder
Power Switch Electrode Amperage Adjustment Amperage Scale Base Metal (work Piece) Ground Clamp Ground Cable Electrode Cable

8 Open Circuit Voltage (OCV)
Open circuit voltage is the potential between the welding electrode and the base metal when the machine is on, but there is no arc. The higher the OCV a machine has, the easier it will be to strike an arc. Only adjustable of dual control machines.

9 Arc Voltage Arc voltage is the potential between the electrode and the base metal when the arc is present. Arc voltage is less than OCV. Adjustable on dual control machines.

10 Polarity The polarity of an object is its physical alignment of atoms.
The term is often used to describe the positive and negative ends of batteries and magnets. The negative end has an excess of electrons The positive end has a deficiency of electrons.

11 Polarity DCEN(direct current, electrode negative)- This is produced by a negative electrode and positive workpiece that causes the current to flow from the electrode to the workpiece. Note: DCEN was formerly termed DCSP, direct current, straight polarity.

12 DCEN BURNED RATES Higher deposition rates Requires faster travel speed Less penetration

13 Polarity DCEP(direct current, electrode positive)- This is produced by a positive electrode and negative workpiece that causes the current to flow from the workpiece to the electrode. Note: DCEP was formerly termed DCRP, direct current, straight polarity.

14 DCEP BURNED RATES Lower burn-off rates Slower travel speed Deeper penetration

15 DC ADVANTAGES Arc Blow- Wandering of an electric arc from its normal path because of magnetic forces. Lower amperages and smaller electrodes. Easier arc starting Better for out of position welding and sheet metal. Smoother arc and less spatter.

16 Welding machine performance characteristics and their applications
AC transformer -These machines change high-voltage, low-amperage AC to low-voltage, high-amperage AC in machines that usually have a 2220/240 volt current. AC or DC transformer-rectifier – These machines change high voltage, low –amperage, high amperage AC with DC, and these machines are ideal for adjustment to different materials and welding positions.

17 Continue ▪ DC generator (motor engine) –In these machines, current varies with the speed the armature turns, polarity change may be made by flipping a switch or reversing weld connections, and some of these machines are powered with AC motors while others are powered with gas or diesel engines. ▪ Duty cycle- size of welding machines are rated in accordance with their amperage capacity at 60 percent duty cycle. ▪ Example: A welding machine rated at 200, 250, 300, etc, will only put out rated amperage and rated voltage for six out of every ten minutes. The machine must be idle and allowed to cool for the other four minutes

18 Five (5) Common Power Supplies
Transformer AC only Rectifier DC only Transformer/rectifier AC or DC Generator DC and/or AC Inverter AC and DC

19 Smaw Advantages ▪ Low initial cost ▪ Portable ▪ Easy to use outdoors ▪ All position capabilities ▪ Easy to change between many base materials What safety precautions should be taken by these welders?

20 Limitations of SMAW ▪ Lower consumable efficiency ▪ Difficult to weld very thin materials ▪ Frequent restarts ▪ Lower operating factor ▪ Higher operator skill required for SMAW than some other processes Building a barge in a large shipyard

21 Striking The Arc Select the best electrode Set the welder (Fig 26-8)
Turn on welder Warn bystanders Lower helmet Start arc (two methods) Scratching methods Tapping methods

22 Scratching Method The “scratch method” for starting an arc is the simplest method for most beginners, and the scratch method work according to the ff. A. Move the electrode across the base metal at an angle like you would use to strike a much. B. As the electrode scratches the base metal, an arc starts. C. When the arc starts, raise the electrode slightly to make a long arc, and then return to normal arc length Do not shut off the welder with the electrode stuck to the metal. Recommended method for beginning welders.

23 Tapping Method The tap method for starting an arc is accomplished by moving the electrode downward in a vertical direction until it just taps the base metal, then raising the electrode up slightly to form a long arc, then returning to the normal arc length again. More difficult method to learn

24 Arc Welding Bead Nomenclature
Electrode Flux Gas shield Electrode metal Slag Penetration Molten puddle Bead Base metal

25 Running Beads Practice running stringer beads
No weaving or pattern. Remember the electrode burns off as the weld is made. Speed used should result in a bead 2-3 times wider than the diameter of the electrode. Cool metal between beads. Practice holding a long arc for a couple of seconds after striking the arc. Preheats the weld Practice filling in the crater.

26 Five (5) Factors of Arc Welding
Correct current sitting/ Heat Correct electrode size Correct electrode angle Correct arc length Correct travel speed of travel

27 Five (5) Factors 1. Correct electrodes size
The SMAW process uses a consumable electrode. Electrode must be compatible with base metal. Electrodes are available for different metals. Carbon steels Low alloy steels Corrosion resisting steels Cast irons Aluminum and alloys Copper and alloys Nickel and alloys Another useful group of electrodes is hard surfacing. NEMA color coding System of of colors on the end or dots on the bare wire indicating the class of electrode. Not very common today. AWS numerical coding Most popular method.

28 American Welding Society (AWS) Classification System
The AWS system distinguishes the tensile strength, weld position and, coating and current. Manufactures may and do use there own numbering system and produce electrodes that do not fit in the AWS system.

29 Welding Currents Not all electrodes are designed to work with all currents. Common SMAW currents. Alternating Current (AC) Direct Current straight polarity (DCSP) or (DCEN) Direct Current Reverse polarity (DCRP) or (DCEP)

30 Arc Welding Electrode Flux
Flux: A material used during arc welding, brazing or braze welding to clean the surfaces of the joint chemically, to prevent atmospheric oxidation and to reduce impurities and/or float them to the surface. (British Standard 499) Seven (7) Classifications of Flux constituents Protection from atmospheric contamination Fluxing agents Arc initiators and stabilizers Deoxidizes Physical properties of the flux Fillers and metallic additions Binders and flux strength improvers

31 Electrode Grouping Electrodes are also grouped according to there performance characteristics. Fast-freeze Mild steel Quick solidification of weld pool Deep penetrating Recommended for out of position welds Deep penetrating arc Fast-fill Highest deposition rate Stable arc Thick flux Flat position and horizontal laps only - Fill-freeze General purpose electrodes Characteristics of fast-freeze and fast-fill Low hydrogen Welding characteristics of fill-freeze Designed for medium carbon and alloy steels

32 Selecting Electrode Size
The optimum electrode diameter is determined by the thickness of the base metal, the welding position and the capacity of the welding power supply. A diameter of 3/32 or 1/8 inch can be used on metals up to 1/4 inches thick without joint preparation. ROT: the diameter of the electrode should not exceed the thickness of the metal. A smaller diameter is usually recommended for out of position welding. When completing root passes in V-joints, a smaller diameter maybe used and then a larger diameter is used for the filler passes.

33 Electrode Storage Electrodes are damaged by rough treatment, temperature extremes and moisture. The should be kept in their original container until used. They should be stored in a heated cabinet that maintains them at a constant temperature. The storage of low hydrogen electrodes is very critical. Designed to reduce under bead cracking in alloy and medium carbon steels by reducing the the amount of hydrogen in the weld pool. The flux is hydroscopic--attracts moisture (H2O). Moisture in the flux also causes excessive gasses to develop in the weld pool and causes a defect in the weld caused worm holes.

34 Five (5) Factors 2. Correct current sitting/ Heat
The arc welder must produce sufficient heat (electric arc) to melt the electrode and the base metal to the desired depth. The amount of heat produced is determined by the amperage. Amperage is limited by the diameter of the electrode and the capacity of the welder. The amount of heat needed to complete the weld is determined by several factors: Insufficient heat. Hard to start Reduced penetration Narrow bead Coarse ripples Excessive heat. Electrode easier to start Excessive penetration (burn through) Excessive bead width Excessive splatter Electrode overheating Thickness of the metal Type of joint, Electrode type Electrode diameter Weld position

35 Five (5) Factors 3. Correct arc Length
The arc length is the distance from the metal part of the electrode to the weld puddle. The best arc length is not a fixed distance, but should be approximately equal to the diameter of the electrode. • Arc length can be adjusted slightly to change the welding position. Excessive length Excessive spatter Reduced penetration Poor quality weld Insufficient length Electrode sticks Narrow weld Poor quality weld

36 Five (5) Factors 5.Correct travel speed
The speed of travel (inches per minute) is an important factor when arc welding. The best speed of travel (welding speed) is determined by several factors: The size of the joint, The type of electrode The size of the electrode The amperage setting on the machine Deposition rate of the electrode (cubic inches per minute) The deposition rate of an electrode will change with the welding amperage.

37 Five (5) Factors 5. Speed-cont.
The ideal speed can be calculated using the volume of the joint and the deposition rate of the electrode. Step one: determine the area of the weld. (Assuming 1/16 inch penetration.) Step Two: knowing the deposition rate of the electrode, determine the welding speed. (Deposition rate = 2.5 in3/min.)

38 Five (5) Factors 5. Speed-cont.
The correct welding speed is indicated by the shape of the ripples. Too slow = excessive width, excessive penetration Too fast = narrower width, elongated ripple pattern, shallow penetration. Recommended = width 2-3 times diameter of electrode, uniform ripple pattern, full penetration.

39 Five (5) Factors 3.Correct electrode Angle
The electrode angle influences the placement of the heat. Two angles are important: Travel Work The travel angle is the angle of the electrode parallel to the joint. The correct travel angle must be used for each joint. Beads = 15o from vertical or 75o from the work. Butt joint = 15o from vertical or 75o from the work. Lap joint = 45o. T joint = 45o. Corner = 15o from vertical or 75o from the work

40 Five (5) Factors Electrode Angle-cont.
The work angle is the angle of the electrode perpendicular to the joint. The appropriate angle must be used for each joint. Beads = 90o Butt joint = 90o Lap joint = 45o T joint = 45o Corner = 90o The work angle may need to be modified for some situations. For example, a butt joint with two different thickness of metal.

41 SMAW Joints

42 Information Sheet Parts of Butt Joint
There are 5 pieces to each Butt weld known as the Root, Toe, Face, Leg and Throat Information Sheet The root of the weld is the part of deepest penetration which is the opposite angle of the Hypotenuse. The toes of the weld are essentially the edges or the points of the hypotenuse. The face of the weld is the outer visual or hypotenuse that you see when looking at a fillet weld. The legs are the opposite and adjacent sides to the triangular fillet weld. The leg length is usually designated as the size of the weld. 5 . The throat of the weld is the distance from the center of the face to the root of the weld. Typically the depth of the throat should be at least as thick as the thickness of metal you are welding. Parts of Butt Joint FACE OF WELD TOE OF WELD THEORETICAL THROAT ACTUAL THROAT ROOT PENETRATION PENETRATION

43 Square Groove A butt joint can be completed with a groove welded on metal up to 1/8 inch thick with a single pass on one side, with no root opening. Electrode manipulation should only be used to prevent burning through.

44 Square Groove Thicker Metal
A groove weld on metal up to 1/4 inch thick can be welded with a single pass on one side but, if possible, it should be completed with a single pass on both sides. Metal this thick requires a root opening to achieve adequate penetration. Electrode manipulation will reduce penetration.

45 Single V Groove Weld Butt joints on metal greater than 1/4 inch thick require joint preparation. Note that the groove does not extend all the way. A short distance, called the root face, is left undisturbed. The amount of joint preparation is dependent on the diameter of the electrode and the amperage capacity of the power supply. Several different combinations of passes can be used to complete this joint. The purpose of the joint preparation is to compensate for not having sufficient amperage and electrode diameter. Note: this is the principle use of pattern beads.

46 T-Joints

47 Information Sheet PARTS OF FILLET WELD LEG
There are 5 pieces to each Fillet weld known as the Root, Toe, Face, Leg and Throat PARTS OF FILLET WELD The root of the weld is the part of deepest penetration which is the opposite angle of the Hypotenuse. The toes of the weld are essentially the edges or the points of the hypotenuse. The face of the weld is the outer visual or hypotenuse that you see when looking at a fillet weld. The legs are the opposite and adjacent sides to the triangular fillet weld. The leg length is usually designated as the size of the weld. 5. . The throat of the weld is the distance from the center of the face to the root of the weld. Typically the depth of the throat should be at least as thick as the thickness of metal you are welding. PENETRATION ACTUAL THROAT TOE OF WELD FACE OF WELD LEG THEORETICAL THROAT ROOT PENETRATION LEG

48 Information In a T-joint the two welding surfaces are at an angle close to 90 degrees from each other. The welding side and number of passes uses depends on the thickness of the metal, the welding access and capacity of the power supply. Common joints include. Plane T T with joint gap Single preparation Double preparation

49 Plane T-Joint The plane T joint is very useful for thin metal.
Can be completed at angles other than 90 degrees. Can be completed with metal of different thickness. The work angle must be changed to direct more heat to the thicker piece.

50 T-joint Thicker Metal When the metal thickness exceeds 1/8 inch the recommendation is to gap the joint. Improves penetration May not be necessary if larger diameter electrode is used and sufficient amperage is available. The need for a joint gap varies with the type of electrode, but should not exceed 1/8 inch.

51 T-joint Single Single Bevel
As with other joints, thicker metal must have joint preparation to achieve full penetration with smaller diameter electrodes. Several different preparations can be used. A popular one is the bevel. A bevel can be completed by grinding or cutting. The bevel joint can be completed with electrode manipulation or no electrode manipulation. When when electrode manipulation is used to fill the joint, the first pass should be a straight bead with no manipulation.

52 T-joint Double Bevel The double bevel T-joint is recommended for metal 1/2 inch thick and thicker. The root passes should be with not manipulation, but the filler passes can be completed with either straight beads or patterns beads. Alternating sides reduces distortion.

53 Weld Defects

54 Common SMAW Defects Hot cracks Undercutting Porosity Slag inclusions
Caused by excessive contraction of the metal as it cools. Excessive bead size May also be found at the root of the weld. Slag inclusions Long arc Incomplete removal of slag on multipass welds. Undercutting improper welding parameters; particularly the travel speed and arc voltage. Porosity Atmospheric contamination or excess gas in the weld pool.

55 SMAW Weld Defects-cont.
Incomplete fusion Toe cracks Microcracks Underbead cracks Toe Cracks Excessive heat and rapid cooling. Underbead cracks Excessive hydrogen in weld pool Microcracks Caused by stresses as weld cools. Incomplete fusion Incorrect welding parameters or welding techniques.

56 End of presentation God Bless Us


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