STICK ELECTRODE
WELDING GUIDE
Procedures and Techniques
STICK ELECTRODE
WELDING GUIDE
Procedures and Techniques
Customer Assistance Policy
The business of The Lincoln Electric Company is manufacturing and selling high quality welding equipment, consumables, and cutting equipment. Our challenge is to meet the needs of our customers and to exceed their expectations. On occasion, pur- chasers may ask Lincoln Electric for advice or information about their use of our products. We respond to our customers based on the best information in our possession at that time. Lincoln Electric is not in a position to warrant or guarantee such advice, and assumes no liability, with respect to such information or advice. We expressly disclaim any warranty of any kind, includ- ing any warranty of fitness for any customer???s particular purpose, with respect to such information or advice. As a matter of practi- cal consideration, we also cannot assume any responsibility for updating or correcting any such information or advice once it has been given, nor does the provision of information or advice cre- ate, expand or alter any warranty with respect to the sale of our products.
Lincoln Electric is a responsive manufacturer, but the selection and use of specific products sold by Lincoln Electric is solely with- in the control of, and remains the sole responsibility of the cus- tomer. Many variables beyond the control of Lincoln Electric affect the results obtained in applying this type of fabrication methods and service requirements.
Subject to Change ??? This information is accurate to the best of our knowledge at the time of printing. Please refer to www.lincolnelectric.com for any updated information.
Table of Contents
Welding
(Vertical and
High Deposition
Welding Inclined
High Speed Welding (Sheet
Low Hydrogen
Minimum Preheat and Interpass Temperatures . . . .35
Stick Electrode Selection
Welding Safety
WELDING PROCEDURES
When welding
Welding made with
Procedures
Vertical Up Groove Welds . . . . . . . . . . . . . . . page 6 Vertical Down Welds . . . . . . . . . . . . . . . . . . . page 6 Vertical Up Fillet Welds . . . . . . . . . . . . . . . . . . page 7 Overhead Fillet Welds . . . . . . . . . . . . . . . . . . page 7
For vertical up and vertical down pipe welding technique, request Lincoln bulletin C2.420, Welding Pressure Pipelines.
Alternate Electrodes
Vertical, overhead, and horizontal groove welds on plate thicker than 1/2??? are most economically done with low hydrogen electrodes ??? see pages
Vertical Up vs. Vertical Down
Vertical down is recommended for fastest welding of 18 gauge to 3/16??? thick steel. A description of the recommended drag technique along with sheet metal procedures are given in the section
Vertical up techniques provide deeper penetration and lower overall welding costs on plate over 3/16??? thick.
Electrode, Current and Polarity
The vertical up and overhead procedures in this section recommend 3/16??? and smaller Fleetweld 5P or 5P+ (E6010) electrode using electrode positive and currents in the lower portion of the electrode???s range. When only AC otuput is available, use Fleetweld 35 or Fleetweld 180 (E6011) electrode at about 10% higher current.
Vertical Up Techniques for Fillet and Groove Welds
Whip??? first pass
Box weave??? second pass
Straight weave 
1.Make first pass root beads with a whipping technique. Whip the electrode tip out of the molten crater and up for a short time to let the crater cool before returning the electrode tip to the crater area to add more weld metal.
2.Root pass beads, particularly when made with a whipping technique, tend to be humped in the middle.
Therefore, a box weave is often needed for the second pass to assure good fusion along the edge of the first bead. The box weave is similar to the straight weave except a slight upward motion is made at both sides of the weld. Maintain a short arc with no whipping.
3.Employ a straight weave for the final passes. Simply move the electrode tip back and forth across the surface of the weld pausing slightly at both edges to insure penetration and
Overhead Techniques
Weld overhead as a series of root beads using a slight circulation motion in the crater sometimes accompanied by a whip. Weave beads are too fluid and will spill.
3
Vertical Up Groove Welds
1/2??? and thicker plates are more economically welded with low hydrogen electrodes.
Vertical Down Welds
Weld thicker plate with vertical up techniques.
(1)First pass only. On later passes adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Vertical Up Fillet Welds
(1)5/32??? electrode can be used to allow better control.
(2)First pass only. On later passes adjust arc speed to obtain proper bead size.
(3)Total for all passes. 100% operating factor.
High deposition applications includes groove, fillet, lap and corner welds in 3/16??? and thicker plate welded with the work level or slightly downhill. These joints are capable of holding a large molten pool of weld metal as it freezes.
These welds are made with Jetweld electrodes because the high iron powder content in the coating produces high deposit rates to fill joints in the shortest time for economical welding.
Procedures
Lap welds . . . . . . . . . . . . . . . . . . . . . . . . . . . page 11 Corner Welds . . . . . . . . . . . . . . . . . . . . . . . . . page 11 Groove Welds . . . . . . . . . . . . . . . . . . . . . . . . page 12 Flat Fillet Welds . . . . . . . . . . . . . . . . . . . . . . . page 14 Horizontal Fillet Welds . . . . . . . . . . . . . . . . . . page 15
Alternate Electrodes
When desired, the following alternate electrodes can be used with similar procedures:
Jetweld Operating Techniques
Polarity and Current ??? Use AC for fast welding speeds, high deposit rates, and good arc characteristics. DC can be used but the resulting arc blow may complicate control of the molten puddle.
Optimum current for most jobs is
Use a Drag Technique ??? Tip the electrode 10 to 30?? in the direc- tion of travel and make stringer beads. Weld with the electrode end lightly dragging on the work to force the molten metal out from under the electrode tip allowing adequate penetration. The smooth welds look almost like automatic welds.
Slow travel
WRONG
Fast Travel
RIGHT
Electrode coating touches plate lightly
Travel fast, but not too fast for good slag coverage. Stay about 1/4??? to 3/8??? ahead of the molten slag. If travel speed is too slow, a small ball of molten slag may form and roll ahead of the arc causing erratic bead shape, spatter, and poor penetration.
Deep Groove Groove Welds ??? To hold the large pool of molten weld metal from Jetweld electrodes, either a weld backing plate or a root pass made with deep penetrating electrode (usually E6010 or E6011) is required. Deposit Jetweld beads with a stringer technique or a slight weave to obtain fusion to both plates. Split weave welds are better than a wide weave near the top of deep grooves. Size the second to last layer so the last layer will not exceed a 1/16??? buildup.
Fillet and Lap Welds ??? The ideal fillet or lap weld has equal legs and a flat or slightly convex bead. Excess convexity wastes weld metal. A concave bead is susceptible to shrinkage cracks.
Flat fillet and lap welds are made with the same general techniques as groove welds.
Weld single pass fillets using a drag technique with the tip of the electrode touching both plates. Usually weld with the electrode at a 45?? angle (end view) from the horizontal plate. However, adjust this angle from as little as 30?? to as much as 60?? when required to maintain equal leg sizes on both plates.
When two passes are needed, deposit the first bead mostly on the bottom plate. To weld the second pass hold the electrode at about 45?? angle fusing into the vertical plate and the first bead.
4
2
3
1 2
1
Make multiple pass horizontal fillets as shown in the sketch. Put the first bead in the corner with fairly high current even though there may be slight undercut, succeeding passes will burn it out. Deposit the second bead on the horizontal plate fusing into the first bead. Hold the electrode angle needed to deposit the filter beads as shown, putting the final bead against the vertical plate.
Use fillet weld procedures for laps on 3/8??? and thicker plate.
Corner Welds
L
L = 1/2 T
T
Note: Maximum strength, full size corner welds, as illustrated, can be made using the next smaller E7024 electrode, lower currents, slower arc speed and slower travel speed. Use 2 passes on 1/2??? plate when making full size corner weld.
(1) 100% operating factor.
Groove Welds
T 
1/16"?? 1/32"
Do not use for code quality work
This square edge groove joint requires the deep penetration of Fleetweld 5P or 5P+.
(1)Both passes.
(2)Total for all passes. 100% operating factor.
Groove Welds
First Pass
30??
3/16??? Jetweld 2 E6027
T
300 amps. AC at 14???/Min.
(1)First pass only. On later passes adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
(3)Plus .228 lbs. of 3/16??? E6027/ft. of weld for first pass.
Deep Groove Welds
Root passes - Joints A, B & C - 3/16 Fleetweld 35 (E6011),
(1)Total for all passes. 100% operating factor.
(2)Plus .160 lbs. of 3/16??? E6011/ft. of weld for each root pass.
Over E6011 Root Passes
(1)Total for all passes. 100% operating factor.
(2)Plus .160 lbs. of 3/16??? E6011/ft. of weld for each root pass.
Flat Fillet Welds
Also see Low Hydrogen Procedures.
T
L
(1)First pass only. On later passes adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
For
1.Use low hydrogen procedures, pages
(or)
2.Weld 3/16??? to 5/16??? fillets with E6027 electrodes at the E7024 procedures. Weld 3/8??? and larger fillets with 1/4??? E6027 at about 400 amps. Travel speed will be slower.
(1)First pass only. On later passes adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
For
1.Use low hydrogen procedures, pages
(or)
2.Weld 3/16??? to 1/2??? plate, use E6027 at slightly lower currents and arc speeds.
T
T 
5
3
2
1
Welding Inclined Plate
These procedures are used when:
1.The work cannot be positioned in the level position for high speed welding with High Deposition Jetweld electrodes.
2.The weld is made partly in the level position and partly downhill.
Fleetweld 47 electrodes have a fairly high iron powder content in the coating, which provides a good deposition rate consistent with downhill welding ability.
Using a drag technique, maintain about a 5/32??? distance between the end of the electrode and the molten slag. If the distance is too great, skips occur in the weld. If the distance is too short, the slag will flow under the arc causing slag holes.
L 
(1)Maximum downhill angle for full size welds.
(2)Welds made at the maximum downhill angles listed for each electrode size tend to be concave and undersized.
(3)100% operating factor.
Plate Inclined Welding
High Speed Welding (Sheet Metal)
Welding sheet steel (18 through12 gauge) requires electrodes that weld at high travel speeds with minimum skips, misses, slag entrapment, and undercut.
Procedures
Groove welds . . . . . . . . . . . . . . . . . . . . . . . . . page 20 Edge Welds . . . . . . . . . . . . . . . . . . . . . . . . . . page 20 Fillet Welds . . . . . . . . . . . . . . . . . . . . . . . . . . page 21 Lap Welds . . . . . . . . . . . . . . . . . . . . . . . . . . . page 21 Corner Welds . . . . . . . . . . . . . . . . . . . . . . . . . page 22 Burnthrough Spot Welds . . . . . . . . . . . . . . . . page 23
Alternate Electrodes
When the recommended electrodes are not available, or if preferred, the following electrodes can be substituted using approximately the same procedures:
Welding Techniques
Generally, use the highest current possible that will not burn- through, undercut, or melt the edges of lap, corner, or edge welds. Fast welding depends upon the operators skill at staying on the joint and traveling at a uniform speed. A few days practice may be needed by good welders when first starting sheet metal welding.
For maximum welding speed, minimum distortion and flat welds generally position joints for welding 45?? to 75?? downhill.
The procedure tables assume tight
1.Reduce the current.
2.Increase the drag angle.
3.With E6010 or E6011 electrodes use a quick whip technique with a slight circular motion in the crater to bridge the gap.
4.With E6012 or E6013 electrodes, use a small quick weave technique to bridge the gap.
When welding with High Speed electrodes (E6012 and E6013) deposit the entire weld in one pass using
When welding with
Weld overhead joints using E6010 or E6011 electrodes with a whip technique and a slight circular motion in the crater. Do not weave. Point the electrode directly into the joint and slightly for- ward into the direction of travel. Use a fairly short arc and travel fast enough to avoid spilling. Use currents in the lower portion of the electrode???s range. Overhead welding of 18 gauge and thinner is not recommended.
Groove Welds
Edge Welds
(1)45 to 75?? downhill position recommended for easy operation and fast speeds.
(2)AC can be used ??? see page 22.
(3)For ft. of weld/hr. multiply in./min. by 5. 100% operating factor.
Fillet Welds
FlatHorizontal Vertical (welded down)
Also see High Deposition Procedures on page 28 for 14 to 10 gauge fillet welds with Jetweld electrodes.
Lap Welds
(4)Faster arc speeds can be obtained with Fleetweld 7 using DC- polarity and these currents.
Corner Welds
(1)45 to 75?? downhill position is recommended for easy welding and fast speeds. Corner welds on 10 gauge steel can be welded
(2)For AC welding use:
a.E6011 in place of E6010 or E6013 in place of E6012
b.The same electrode diameters.
c.About 10% higher current.
d.The following arc speeds:
Arc Speed (inch/min)
(3) For ft. of weld/hr. multiply in./min. by 5. 100% operating factor.
Burnthrough Spot Welds (Roof Decking to Beam)
Roof Deck
Roof Beam Flange
Low Hydrogen Welding
Low hydrogen electrodes are recommended for three broad areas of application:
1.On low alloy, high carbon, high sulfur, or other steels where cracking is a problem.
2.When specified by governing codes.
3.For lowest costs on vertical, overhead and horizontal groove welds on heavy (over 1/2???) plate.
Procedures
Vertical Up Groove Welds . . . . . . . . . . . . . . . page 27 Overhead Groove Welds . . . . . . . . . . . . . . . . page 27 Vertical Up Fillet Welds . . . . . . . . . . . . . . . . . . page 28 Overhead Fillet Welds . . . . . . . . . . . . . . . . . . page 28 Horizontal Groove Welds . . . . . . . . . . . . . . . . pages
Jetweld
Employ the same techniques for this
EXX18 Welding Techniques
Procedures and techniques for E7018 electrodes can be used for E8018, E9018, or E11018 Lincoln electrodes.
Polarity - Whenever possible use electrode positive for 5/32??? and smaller electrodes. AC can be used at about 10% higher currents.
Use AC on 3/16??? and larger diameter electrodes to minimize arc blow for best operating characteristics. DC+ can also be used at about 10% lower currents.
Drag the electrode lightly. Since low hydrogen electrodes rely on the molten slag for shielding, never hold a long arc, whip, leave the crater, or move rapidly in any direction. Failure to follow these techniques may result in porosity and/or reduce mechani- cal properties.
For Clean
Multiple Pass Welds ??? Clean the slag after each bead. When welding in the downhand position, use stringer beads or small weaves rather than wide weaves to avoid slag inclusions.
Vertical Techniques
Use 5/32??? or smaller electrodes and currents in the lower portion of the electrode???s range. Techniques are as follows:
1. Use a triangular weave for heavy single pass welds.
Heavy Single Pass
Triangular weave 
Multipass
Stringer bead 
Straight weave
2.For multipass welds, deposit a first pass bead using a slight weave. We emphasize the importance of moving into the corner to assure penetration into the corner. Weld additional layers with a
3.With this technique, slag spills down the weld. As long as no metal spills, operation is normal. Once welders are familiar with the EXX18 techniques, they will quickly learn to make sound welds of excellent appearance.
Horizontal Groove and Overhead Weld Techniques
Weld with a series of first pass beads using a slight circular motion in the crater. Do not whip. Use 5/32??? or smaller electrodes and currents in the lower portion of the electrode???s range.
3
Vertical Up Groove Welds
Also see
First Pass
3/16" Fleetweld 5P (E6010), 150 amps DC+,
Last Pass - back gouge before welding.
60??
T
1/8"
T
1/8"
Overhead Groove Welds
(1)First low hydrogen pass only. On later passes adjust Arc Speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
(3)Plus .280 lbs. of 3/16??? E6010/ft. of weld for first pass.
(4)Plus .160 lbs. of 1/8??? E6010/ft. of weld for first pass.
Vertical Up Fillet Welds
L
Overhead Fillet Welds
Also see
After first bead, the sequence of bead placement starts on vertical plate for each layer.
1/16" max. root opening
L
(1)First low hydrogen pass only. On later passes adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Horizontal Groove Welds
T
5/8"3/4"
45??
1/4"
(1)Arc speed for first pass approximately 5 in./min.
(2)Total for all passes. 100% operating factor.
Horizontal Groove Welds
T 
T/2
45??
Use steel backing (as on page 29).
(1)Arc speed for first pass approximately 5 in./min.
(2)Total for all passes. 100% operating factor.
With E7028 Electrode
(1)First pass only. On later passes, adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Note: E7028 can produce code quality welds. E7028 is recommended for making high speed low cost welds using
5
With E7018 Electrode
(1)First pass only. On later passes, adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Note: E7018 can produce code quality welds. E7018 procedures are used when E7028 is not available and for electrodes E8018 and E11018.
With E7028 Electrode
(1)First pass only. On later passes, adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Note: E7028 can produce code quality welds. E7028 is recommended for making high speed low cost welds using
L
With E7018 Electrode
(1)First pass only. On later passes, adjust arc speed to obtain proper bead size.
(2)Total for all passes. 100% operating factor.
Note: E7018 can produce code quality welds. E7018 procedures are used when E7028 is not available and for electrodes E8018 and E11018.
L
Minimum Preheat and Interpass Temperature(1)
For stick electrode welding only
Based on AWS Specification D1.1
Definitions
T ??? Thickness of the thickest part at point of welding.
Col. 1 ??? For the following steels when welded with other than low hydrogen electrodes ASTM A36; A53 Grade B; A106 Grade B; A131 Grades A, B, CS, D, DS, E; A139 Grade B; A381 Grade Y35; A500 Grades A, B; A501; A516; A524 Grades I & II; A570 All grades; A573 Grade 65; A709 Grade 36 (??? 3/4 in. [20mm]); AP15L Grades B, X42; ABS Grades A, B, C, D, CS, DS, E.
Col. 2 ??? For the following steels: All steels listed in Column 1, and additionally: ASTM A36 (>3/4 in. [20mm]); A53 Grade B; A106 Grade B; A131 Grades A, B, CS, D, DS, E, AH32 & 36, DH 32 & 36, EH 32 & 36; A139 Grade B; A381 Grade Y35; A441; A500 Grade A, Grade B; A501; A516 Grades 55 & 60, Grades 65 & 70, A524 Grades 1 & 2; A529 Grades 50 & 55; A537 Classes I & II; A570 All Grades; A572 Grades 42, 50, 55; A573 Grade 60; A588, A595 Grades A, B, C; A606; A607 Grades 45, 50, 55; A618 Grades Ib, II, III; A633 Grades A, B, Grades C, D; A709 Grades 36 (??? 3/4 in. [20mm]), 50, 50W; A710 Grade A, Class 2 (??? 2 in. [50mm]); A808; A913 Grade 50; A992; API 5L Grade B, Grade X42; API Spec. 2H Grades 42, 50; API 2W Grades 42, 50, 50T; API 2Y Grades 42, 50, 50T; ABS Grades AH 32 & 36, DH 32 & 36, EH 32 & 36; ABS Grades A, B, D, CS, DS, Grade E
Col. 3 ??? For steels ASTM A572 Grades 60 and 65, A633 Grade E; API 5L Grade X52; ASTM A913 Grades 60, 65; A710 Grade A, Class 2 (??? 2 in. [50mm]); A710 Class 3 (??? 2 in. [50mm]); A709 Grade 70W; A852, API 2W Grade 60; API 2Y Grade 60
Col. 4 ??? All thicknesses ??? 1/8 in. [3mm]. ASTM A710 Grade A (all classes); ASTM A913 Grades 50, 60, 65. SMAW electrodes capable of depositing weld metal with a maximum diffusible hydrogen content of 8 ml/100g (H8), when tested according to AWS A4.3.
Minimum Preheat and Interpass Temperature(1) Continued
For stick electrode welding only
Based on AWS Specification D1.1
Notes
(1)Welding shall not be done when ambient temp. is lower than 0??F. Parts on which metal is being deposited shall be at or above the specified temperature for a distance equal to the thickness of the part being welded, but not less than 3???, in all directions from the point of welding. Preheat and interpass temperature must be sufficient to prevent cracking. Temperature above the minimum may be required for highly restrained welds. For ASTM A709 Grade 70W and ASTM A852 Grade 70, the maximum preheat and interpass tem- perature shall not exceed 400??F for thicknesses thru
(2)When the base metal temperature is below 32??F, preheat to at least 70??F and maintain this minimum temperature during welding.
Stick Electrode Typical Operating Procedures
???High Deposition??? Group
Highest deposition rates of all electrodes. Flat, horizontal and slightly downhill (15?? maximum) position only. Easy slag removal and smooth,
(1) Range for 3/32??? is
???High Speed??? Group
Operates in all positions, but most widely use downhill, horizontal or in the flat posi- tion. Ideal for irregular or short welds that change direction or position. Medium deposit rates and medium penetration. Appearance ranges from smooth and ripple- free to even with distinct ripples.
(1)Range for 5/64??? Fleetweld 37 is 50 - 80 amps AC or
Low Hydrogen Group
For welding carbon and low alloy steels that require 70,000 psi tensile strength deposits. These low hydrogen electrodes can produce dense,
Low Hydrogen, Low Alloy Steel Group
Made for welding low alloy steels that require specific mechanical or chemical properties of one of these electrodes. Specifically for use in cryogenics, high temperature applications, and for
NOTE1: Joining Electrodes,
These electrodes (see below) and others of the same AWS classification, are not required to deposit weld metal capable of delivering any minimum specified Charpy
Fleetweld 7
Fleetweld 22
Fleetweld 37
Fleetweld 47
Jetweld 3
NOTE 2: Joining Electrodes,
These electrodes (see below) and others of the same AWS classification, are not required to deposit weld metal that is low in diffusible hydrogen. Therefore, these electrodes should not be used in applications where the hydrogen content of the weld metal is required to be controlled, such as applications that involve steels with higher carbon and alloy content, and higher strength.
WARNING
ARC WELDING can be hazardous.
PROTECT YOURSELF AND OTHERS FROM POSSIBLE SERIOUS
INJURY OR DEATH. KEEP CHILDREN AWAY. PACEMAKER
WEARERS SHOULD CONSULT WITH THEIR DOCTOR BEFORE
OPERATING.
Read and understand the following safety highlights. For additional safety infor- mation it is strongly recommended that you purchase a copy of ???Safety in Welding & Cutting - ANSI Standard Z49.1??? from the American Welding Society, P.O. Box 351040, Miami, Florida 33135 or CSA Standard
BE SURE THAT ALL INSTALLATION, OPERATION, MAINTENANCE,
AND REPAIR PROCEDURES ARE PERFORMED ONLY BY
QUALIFIED INDIVIDUALS.
ELECTRIC SHOCK can kill.
1.a. The electrode and work (or ground) circuits are electrically ???hot??? when the welder is on. Do not touch these ???hot??? parts with your bare skin or wet clothing. Wear dry,
1.b. Insulate yourself from work and ground using dry insula- tion. Make certain the insulation is large enough to cover your
full area of physical contact with work and ground.
In addition to the normal safety precautions, if welding must be per- formed under electrically hazardous conditions (in damp locations or while wearing wet clothing; on metal structures such as floors, gratings or scaffolds; when in cramped positions such as sitting, kneeling or lying, if there is a high risk of unavoidable or accidental contact with the workpiece or ground) use the following equipment:
???Semiautomatic DC Constant Voltage (Wire) Welder.
???DC Manual (Stick) Welder.
???AC Welder with Reduced Voltage Control.
1.c. In semiautomatic or automatic wire welding, the electrode, electrode reel, welding head, nozzle or semiautomatic welding gun are also electrically ???hot???.
1.d. Always be sure the work cable makes a good electrical connection with the metal being welded. The connection should be as close as possible to the area being welded.
1.e. Ground the work or metal to be welded to a good electrical (earth) ground.
1.f. Maintain the electrode holder, work clamp, welding cable and welding machine in good, safe operating condition. Replace damaged insulation.
1.g. Never dip the electrode in water for cooling.
1.h. Never simultaneously touch electrically ???hot??? parts of electrode holders con- nected to two welders because voltage between the two can be the total of the open circuit voltage of both welders.
1.i. When working above floor level, use a safety belt to protect yourself from a fall should you get a shock.
1.j. Also see Items 4.c. and 6.
ARC RAYS can burn.
2.a. Use a shield with the proper filter and cover plates to protect your eyes from sparks and the rays of the arc when welding or observing open arc welding. Headshield and filter lens should conform to ANSI Z87. I standards.
2.b. Use suitable clothing made from durable
2.c. Protect other nearby personnel with suitable
FUMES AND GASES can be
dangerous.
3.a. Welding may produce fumes and gases hazardous to health. Avoid breathing these fumes and gases.When welding, keep your head out of the fume. Use enough ventilation and/or exhaust at the arc to keep fumes and
gases away from the breathing zone.When welding with electrodes which require special ventilation such as stainless or hard facing (see instructions on container or MSDS) or
on lead or cadmium plated steel and other metals or coatings which produce highly toxic fumes, keep exposure as low as possi- ble and below Threshold Limit Values (TLV) using local exhaust or mechanical ventilation. In confined spaces or in some circum- stances, outdoors, a respirator may be required. Additional precau- tions are also required when welding on galvanized steel.
3.b. Do not weld in locations near chlorinated hydrocarbon vapors coming from degreasing, cleaning or spraying operations. The heat and rays of the arc can react with solvent vapors to form phosgene, a highly toxic gas, and other irritating products.
3.c. Shielding gases used for arc welding can displace air and cause injury or death. Always use enough ventilation, especially in confined areas, to insure breathing air is safe.
3.d. Read and understand the manufacturer???s instructions for this equipment and the consumables to be used, including the material safety data sheet (MSDS) and follow your employer???s safety practices. MSDS forms are available from your welding distributor or from the manufacturer.
3.e. Also see item 7b.
WELDING SPARKS can cause
fire or explosion.
4.a..Remove fire hazards from the welding area. If this is not possible, cover them to prevent the welding sparks from starting a fire. Remember that welding sparks and hot materials from welding can easily go through small cracks and openings to adjacent areas. Avoid welding near hydraulic lines. Have a fire extinguisher readily available.
4.b. Where compressed gases are to be used at the job site, special precautions should be used to prevent hazardous situations. Refer to ???Safety in Welding and Cutting??? (ANSI Standard Z49.1) and the operating information for the equipment being used.
4.c. When not welding, make certain no part of the electrode circuit is touching the work or ground. Accidental contact can cause overheating and create a fire hazard.
4.d. Do not heat, cut or weld tanks, drums or containers until the proper steps have been taken to insure that such procedures will not cause flammable or toxic vapors from substances inside. They can cause an explosion even though they have been ???cleaned.??? For information purchase ???Recommended Safe Practices for the Preparation for Welding and Cutting of Containers and Piping That Have Held Hazardous Substances???, AWS F4.1 from the American Welding Society (see address above).
4.e. Vent hollow castings or containers before heating, cutting or welding. They may explode.
4.f. Sparks and spatter are thrown from the welding arc. Wear oil free protective garments such as leather gloves, heavy shirt, cuffless trousers, high shoes and a cap over your hair. Wear ear plugs when welding out of position or in confined places. Always wear safety glasses with side shields when in a welding area.
4.g. Connect the work cable to the work as close to the welding area as practical. Work cables connected to the building framework or other locations away from the welding area increase the possibility of the welding current passing through lifting chains, crane cables or other alternate circuits. This can cre- ate fire hazards or overheat lifting chains or cables until they fail.
4.h. Also see item 7c.
CYLINDER may explode if damaged.
5.a. Use only compressed gas cylinders containing the correct
shielding gas for the process used and properly operating reg-
ulators designed for the gas and pressure used. All hoses, fit-
tings, etc. should be suitable for the application and main- tained in good condition.
5.b. Always keep cylinders in an upright position securely chained to an undercarriage or fixed support.
5.c. Cylinders should be located:
???Away from areas where they may be struck or subjected to physical damage.
???A safe distance from arc welding or cutting operations and
any other source of heat, sparks, or flame.
5.d. Never allow the electrode, electrode holder or any other electrically ???hot??? parts to touch a cylinder.
5.e. Keep your head and face away from the cylinder valve outlet when opening the cylinder valve.
5.f. Valve protection caps should always be in place and hand tight except when the cylinder is in use or connected for use.
5.g. Read and follow the instructions on compressed gas cylinders, associated equipment, and CGA publication
FOR ELECTRICALLY powered
equipment.
6.a. Turn off input power using the disconnect switch at the fuse box before working on the equipment.
6.b. Install equipment in accordance with the U.S. National Electrical Code, all local codes and the
manufacturer???s recommendations.
6.c. Ground the equipment in accordance with the U.S. National Electrical Code and the manufacturer???s recommendations.
FOR ENGINE powered equipment.
7.a Turn the engine off before troubleshooting and maintenance work unless the maintenance work requires it to be running.
7.b. Operate engines in open,
7.c.Do not add the fuel near an open flame welding arc or when the engine is running. Stop the engine and allow it to cool before refueling to prevent spilled fuel from vaporizing on contact with hot engine parts and igniting. Do not spill fuel when filling tank. If fuel is spilled, wipe it up and do not start engine until fumes have been eliminated.
7.d. Keep all equipment safety guards, covers and devices in position and in good repair. Keep hands, hair, clothing and tools away from
7.e. In some cases it may be necessary to remove safety guards to per- form required maintenance. Remove guards only when necessary and replace them when the maintenance requiring their removal is complete. Always use the greatest care when working near moving parts.
7.f. Do not put your hands near the engine fan. Do not attempt to override the governor or idler by pushing on the throttle control rods while the engine is running.
7.g. To prevent accidentally starting gasoline engines while turning the engine or welding generator during maintenance work, disconnect the spark plug wires, distributor cap or magneto wire as appropriate.
7.h. To avoid scalding, do not remove the radiator pressure cap when the engine is hot.
ELECTRIC AND MAGNETIC FIELDS
may be dangerous
8.a. Electric current flowing through any conductor caus- es localized Electric and Magnetic Fields (EMF). Welding current creates EMF fields around welding cables and welding machines.
8.b. EMF fields may interfere with some pacemakers, and welders having a pacemaker should consult their physician before welding.
8.c. Exposure to EMF fields in welding may have other health effects which are now not known.
8d. All welders should use the following procedures in order to minimize expo- sure to EMF fields from the welding circuit:
8.d.1. Route the electrode and work cables together - Secure them with tape when possible.
8.d.2. Never coil the electrode lead around your body.
8.d.3. Do not place your body between the electrode and work cables. If the electrode cable is on your right side, the work cable should also be on your right side.
8.d.4. Connect the work cable to the workpiece as close as possible to the area being welded.
8.d.5. Do not work next to welding power source.
THE
LINCOLN ELECTRIC
COMPANY
Local Sales and Service through Global Subsidiaries and Distributors
Cleveland, Ohio
TEL (216)
FAX (216)
WEB SITE www.lincolnelectric.com
Stick
C2.410 12/04