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SVM105-B
User Manual
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Lincoln Electric V300-PRO, SVM105-B User Manual

INVERTEC V300-PRO
SVM105-B
April, 2007
Safety Depends on You
Lincoln arc welding and cutting equipment is designed and built with safety in mind. However, your overall safety can be increased by proper installation . . . and thoughtful operation on your part. DO NOT INSTALL,
OPERATE OR REPAIR THIS EQUIPMENT WITHOUT READ­ING THIS MANUAL AND THE SAFETY PRECAUTIONS CON­TAINED THROUGHOUT. And,
most importantly, think before you act and be careful.
SERVICE MANUAL
For use with machines having Code Number : 9825 THRU 10450
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• Sales and Service through Subsidiaries and Distributors Worldwide •
Cleveland, Ohio 44117-1199 U.S.A. TEL: 216.481.8100 FAX: 216.486.1751 WEB SITE: www.lincolnelectric.com
• World's Leader in Welding and Cutting Products •
Copyright © 2007 Lincoln Global Inc.
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i

SAFETY

i
FOR ENGINE powered equipment.
1.a. Turn the engine off before troubleshooting and maintenance work unless the maintenance work requires it to be running.
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1.b.Operate engines in open, well-ventilated areas or vent the engine exhaust fumes outdoors.
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1.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.
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1.d. Keep all equipment safety guards, covers and devices in posi­tion and in good repair.Keep hands, hair, clothing and tools away from V-belts, gears, fans and all other moving parts when starting, operating or repairing equipment.
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1.e. In some cases it may be necessary to remove safety
guards to perform 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.
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1.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.
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1.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.
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 information, 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 W117.2-1974. AFree copy of “Arc Welding Safety” booklet E205 is available from the Lincoln Electric Company, 22801 St. Clair Avenue, Cleveland, Ohio 44117-1199.
BE SURE THAT ALL INSTALLATION, OPERATION, MAINTENANCE AND REPAIR PROCEDURES ARE PERFORMED ONLY BY QUALIFIED INDIVIDUALS.
WARNING
Mar ‘95
ELECTRIC AND MAGNETIC FIELDS may be dangerous
2.a. Electric current flowing through any conductor causes localized Electric and Magnetic Fields (EMF). Welding current creates EMF fields around welding cables and welding machines
2.b. EMF fields may interfere with some pacemakers, and welders having a pacemaker should consult their physician before welding.
2.c. Exposure to EMF fields in welding may have other health effects which are now not known.
2.d. All welders should use the following procedures in order to minimize exposure to EMF fields from the welding circuit:
2.d.1.
Route the electrode and work cables together - Secure them with tape when possible.
2.d.2. Never coil the electrode lead around your body.
2.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.
2.d.4. Connect the work cable to the workpiece as close as
possible to the area being welded.
2.d.5. Do not work next to welding power source.
1.h. To avoid scalding, do not remove the radiator pressure cap when the engine is hot.
CALIFORNIA PROPOSITION 65 WARNINGS
Diesel engine exhaust and some of its constituents are known to the State of California to cause can­cer, birth defects, and other reproductive harm.
The engine exhaust from this product contains chemicals known to the State of California to cause cancer, birth defects, or other reproductive harm.
The Above For Diesel Engines
The Above For Gasoline Engines
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ARC RAYS can burn.
4.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.
4.b. Use suitable clothing made from durable flame-resistant material to protect your skin and that of your helpers from the arc rays.
4.c. Protect other nearby personnel with suitable, non-flammable screening and/or warn them not to watch the arc nor expose themselves to the arc rays or to hot spatter or metal.
ELECTRIC SHOCK can kill.
3.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, hole-free gloves to insulate hands.
3.b. Insulate yourself from work and ground using dry insulation. 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 performed 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.
3.c. In semiautomatic or automatic wire welding, the electrode, electrode reel, welding head, nozzle or semiautomatic welding gun are also electrically “hot”.
3.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.
3.e. Ground the work or metal to be welded to a good electrical (earth) ground.
3.f.
Maintain the electrode holder, work clamp, welding cable and welding machine in good, safe operating condition. Replace damaged insulation.
3.g. Never dip the electrode in water for cooling.
3.h. Never simultaneously touch electrically “hot” parts of electrode holders connected to two welders because voltage between the two can be the total of the open circuit voltage of both welders.
3.i. When working above floor level, use a safety belt to protect yourself from a fall should you get a shock.
3.j. Also see Items 6.c. and 8.
FUMES AND GASES can be dangerous.
5.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 possible and below Threshold Limit Values (TLV) using local exhaust or mechanical ventilation. In confined spaces or in some circumstances, outdoors, a respirator may be required. Additional precautions are also required when welding on galvanized steel.
5. b. The operation of welding fume control equipment is affected by various factors including proper use and positioning of the equipment, maintenance of the equipment and the specific welding procedure and application involved. Worker expo­sure level should be checked upon installation and periodi­cally thereafter to be certain it is within applicable OSHAPEL and ACGIH TLV limits.
5.c.
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.
5.d. 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.
5.e. 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.
5.f. Also see item 1.b.
AUG 06
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SAFETY
ii
SAFETY
iii iii
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FOR ELECTRICALLY powered equipment.
8.a. Turn off input power using the disconnect switch at the fuse box before working on the equipment.
8.b. Install equipment in accordance with the U.S. National Electrical Code, all local codes and the manufacturer’s recommendations.
8.c. Ground the equipment in accordance with the U.S. National Electrical Code and the manufacturer’s recommendations.
CYLINDER may explode if damaged.
7.a. Use only compressed gas cylinders containing the correct shielding gas for the process used and properly operating regulators designed for the gas and
pressure used. All hoses, fittings, etc. should be suitable for the application and maintained in good condition.
7.b. Always keep cylinders in an upright position securely chained to an undercarriage or fixed support.
7.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.
7.d. Never allow the electrode, electrode holder or any other electrically “hot” parts to touch a cylinder.
7.e. Keep your head and face away from the cylinder valve outlet when opening the cylinder valve.
7.f. Valve protection caps should always be in place and hand tight except when the cylinder is in use or connected for use.
7.g. Read and follow the instructions on compressed gas cylinders, associated equipment, and CGA publication P-l, “Precautions for Safe Handling of Compressed Gases in Cylinders,” available from the Compressed Gas Association 1235 Jefferson Davis Highway, Arlington, VA22202.
Mar ‘95
WELDING SPARKS can cause fire or explosion.
6.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.
6.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.
6.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.
6.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).
6.e. Vent hollow castings or containers before heating, cutting or welding. They may explode.
6.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.
6.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 create fire hazards or overheat lifting chains or cables until they fail.
6.h. Also see item 1.c.
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PRÉCAUTIONS DE SÛRETÉ
Pour votre propre protection lire et observer toutes les instructions et les précautions de sûreté specifiques qui parraissent dans ce manuel aussi bien que les précautions de sûreté générales suiv­antes:
Sûreté Pour Soudage A L’Arc
1. Protegez-vous contre la secousse électrique:
a. Les circuits à l’électrode et à la piéce sont sous tension
quand la machine à souder est en marche. Eviter toujours tout contact entre les parties sous tension et la peau nue ou les vétements mouillés. Porter des gants secs et sans trous pour isoler les mains.
b. Faire trés attention de bien s’isoler de la masse quand on
soude dans des endroits humides, ou sur un plancher met­allique ou des grilles metalliques, principalement dans les positions assis ou couché pour lesquelles une grande partie du corps peut être en contact avec la masse.
c. Maintenir le porte-électrode, la pince de masse, le câble de
soudage et la machine à souder en bon et sûr état defonc­tionnement.
d.Ne jamais plonger le porte-électrode dans l’eau pour le
refroidir.
e. Ne jamais toucher simultanément les parties sous tension
des porte-électrodes connectés à deux machines à souder parce que la tension entre les deux pinces peut être le total de la tension à vide des deux machines.
f. Si on utilise la machine à souder comme une source de
courant pour soudage semi-automatique, ces precautions pour le porte-électrode s’applicuent aussi au pistolet de soudage.
2. Dans le cas de travail au dessus du niveau du sol, se protéger contre les chutes dans le cas ou on recoit un choc. Ne jamais enrouler le câble-électrode autour de n’importe quelle partie du corps.
3. Un coup d’arc peut être plus sévère qu’un coup de soliel, donc:
a. Utiliser un bon masque avec un verre filtrant approprié ainsi
qu’un verre blanc afin de se protéger les yeux du rayon­nement de l’arc et des projections quand on soude ou quand on regarde l’arc.
b. Porter des vêtements convenables afin de protéger la peau
de soudeur et des aides contre le rayonnement de l‘arc.
c. Protéger l’autre personnel travaillant à proximité au
soudage à l’aide d’écrans appropriés et non-inflammables.
4. Des gouttes de laitier en fusion sont émises de l’arc de soudage. Se protéger avec des vêtements de protection libres de l’huile, tels que les gants en cuir, chemise épaisse, pan­talons sans revers, et chaussures montantes.
5. Toujours porter des lunettes de sécurité dans la zone de soudage. Utiliser des lunettes avec écrans lateraux dans les
zones où l’on pique le laitier.
6. Eloigner les matériaux inflammables ou les recouvrir afin de prévenir tout risque d’incendie dû aux étincelles.
7. Quand on ne soude pas, poser la pince à une endroit isolé de la masse. Un court-circuit accidental peut provoquer un échauffement et un risque d’incendie.
8. S’assurer que la masse est connectée le plus prés possible de la zone de travail qu’il est pratique de le faire. Si on place la masse sur la charpente de la construction ou d’autres endroits éloignés de la zone de travail, on augmente le risque de voir passer le courant de soudage par les chaines de levage, câbles de grue, ou autres circuits. Cela peut provoquer des risques d’incendie ou d’echauffement des chaines et des câbles jusqu’à ce qu’ils se rompent.
9. Assurer une ventilation suffisante dans la zone de soudage. Ceci est particuliérement important pour le soudage de tôles galvanisées plombées, ou cadmiées ou tout autre métal qui produit des fumeés toxiques.
10. Ne pas souder en présence de vapeurs de chlore provenant d’opérations de dégraissage, nettoyage ou pistolage. La chaleur ou les rayons de l’arc peuvent réagir avec les vapeurs du solvant pour produire du phosgéne (gas fortement toxique) ou autres produits irritants.
11. Pour obtenir de plus amples renseignements sur la sûreté, voir le code “Code for safety in welding and cutting” CSA Standard W 117.2-1974.
PRÉCAUTIONS DE SÛRETÉ POUR LES MACHINES À SOUDER À TRANSFORMATEUR ET À REDRESSEUR
1. Relier à la terre le chassis du poste conformement au code de l’électricité et aux recommendations du fabricant. Le dispositif de montage ou la piece à souder doit être branché à une bonne mise à la terre.
2. Autant que possible, I’installation et l’entretien du poste seront effectués par un électricien qualifié.
3. Avant de faires des travaux à l’interieur de poste, la debranch­er à l’interrupteur à la boite de fusibles.
4. Garder tous les couvercles et dispositifs de sûreté à leur place.
Mar. ‘93
iv
SAFETY
iv
V300-I
vv
MASTER TABLE OF CONTENTS FOR ALL
SECTIONS
Safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i-iv
Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section A
Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section B
Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section C
Maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section D
Theory of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section E
Troubleshooting and Repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section F
Electrical Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Section G
Parts Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .P243 Series
RETURN TO MAIN MENU
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V300-PRO
Section A-1 Section A-1
TABLE OF CONTENTS
- INSTALLATION SECTION -
Installation ..............................................................................................................Section A
Technical Specifications .........................................................................................A-2
Location..................................................................................................................A-3
Electrical Installation...............................................................................................A-3
Input Connections...................................................................................................A-4
Wire feeder and Accessory Connections........................................................A-4, A-5
Output Connection..................................................................................................A-6
V300-PRO
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A-2
INSTALLATION
A-2
TECHNICAL SPECIFICATIONS - V300-PRO (K1349-3, K1349-4)
Height Width Depth Weight
18.7 in. 10.8 in. 22.2 in. 64 lbs. 475 mm 274 mm 564 mm 29 Kg
PHYSICAL DIMENSIONS
THREE PHASE SINGLE PHASE
Standard Input Current Code
V
oltage at Rated Output
Number
208/230/460/575 48/43/24/20 9825,9834,9965
50/60 10034,10035
10130,10131
Volts at
Rated
Duty Cycle
Amps Amperes
60% Duty Cycle 300 32
100% Duty Cycle 250 30
Welding Constant Open Auxiliary
Current Range
Circuit Voltage Power
5-300 Amps 60-70 VDC 42 VAC, 5.5 Amps
24 VAC, 1 Amp
*115 VAC, 2 Amps
*Not on all codes
Standard Input Current Code
V
oltage at Rated Output Number
208/230/460 69/62/38- 9825,9936,9965
50/60 10034, 10130,
Volts at
Rated
Duty Cycle
Amps Amperes
60% Duty Cycle 200 28
100% Duty Cycle 165 26.5
Welding Constant Open Auxiliary
Current Range
Circuit Voltage Power
5-200 Amps 60-70 VDC 42 VAC, 5.5 Amps
24 VAC, 1 Amp
*115 VAC, 2 Amps
*Not on all codes
INPUT
RECOMMENDED INPUT WIRE AND FUSE SIZES
Type 75°C
Type 75°C Copper
Fuse Input Copper Ground
(Superlag) Ampere Wire in Wire in
Input or Rating Conduit Conduit
Voltage Breaker on AWG (IEC) AWG (IEC)
Frequency
(1)
Size Nameplate Sizes Sizes
208/60 60 48 6 (16mm2) 10 (6mm2) 230/60 60 39 8 (10mm2) 10 (6mm2) 460/60 40 25 10 (6mm2) 10 (6mm2) 575/60 30 25 10 (6mm2) 10 (6mm2)
Type 75°C
Type 75°C Copper
Fuse Input Copper Ground
(Superlag) Ampere Wire in Wire in
Input or Rating Conduit Conduit
Voltage Breaker on AWG (IEC) AWG (IEC)
Frequency
(1)
Size Nameplate Sizes Sizes
208/60 85 69 6 (16mm2) 10 (6mm2) 230/60 80 62 6 (16mm2) 10 (6mm2) 460/60 50 38 8 (10mm2) 10 (6mm2)
THREE PHASE SINGLE PHASE
THREE PHASE SINGLE PHASE
THREE PHASE SINGLE PHASE
OUTPUT
RATED OUTPUT
V300-PRO
INSTALLATION
A-3 A-3
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THE LINCOLN ELECTRIC CO. CLEVELAND, OHIO U.S.A.
.
.
.
.
Do not touch electrically live parts.
Only qualified persons should install,
use or service this equipment.
RECONNECT PROCEDURE
REPLACE WITH A 3 AMP SLOW BLOW ONLY.
1. BE SURE POWER SWITCH IS OFF.
200-208V
220-230V
380-415V
440-460V
'A'
INPUT VOLTAGE RANGE.
removed.
Do not operate with wraparound
inspecting or servicing machine.
Disconnect input power before
IF MACHINE CEASES TO OPERATE (NO METER, NO FAN)
2. CONNECT LEAD 'A' TO DESIRED
3. POSITION SWITCH TO DESIRED INPUT VOLTAGE RANGE.
S20324
AND THERE IS NO OTHER KNOWN FAILURE: CHECK FUSE;
VOLTAGE=380-460V
VOLTAGE=200-230V
9-11-92
DO NOT ATTEMPT TO POWER THIS UNIT FROM THE AUXILIARY POWER SUPPLY OF AN ENGINE WELDER.
• Special protection circuits may operate, causing loss of output.
• The supply from engine welders often has exces­sive voltage peaks because the voltage waveform is usually triangular shaped instead of sinusoidal.
• If voltage peaks from the engine welder are too high (380v on 230v setting), the input circuits of this machine protecting the filter capacitors, FETS and other components from damage will not
be ener-
gized.
CAUTION
PRODUCT DESCRIPTION
The Invertec V300-PRO is a 300 amp arc welding power source that utilizes single or three phase input power to produce either constant voltage or constant current outputs. The V300-PRO is designed for 50/60 Hz supply systems. The welding response of the Invertec has been optimized for GMAW, SMAW, TIG and FCAW processes. It is designed to be used with the LN-25 and LN-7 semiautomatic wire feeders.
ELECTRIC SHOCK can kill.
• Have an electrician install and ser­vice this equipment.
• Turn the input power off at the fuse box before working on equipment.
• Do not touch electrically hot parts.
----------------------------------------------------------------------
WARNING
LOCATION
The Invertec has been designed with many features to protect it from harsh environments. Even so, it is important that simple preventative measures are fol­lowed in order to assure long life and reliable opera­tion.
• The machine must be located where there is free cir­culation of clean air such that air movement into the sides and out the bottom and front will not be restricted. Dirt and dust that can be drawn into the machine should be kept to a minimum. Failure to observe these precautions can result in excessive operating temperatures and nuisance shutdown of the Invertec.
• Keep machine dry. Shelter from rain and snow. Do not place on wet ground or in puddles.
ELECTRICAL INSTALLATION
1. The Invertec should be connected only by a quali­fied electrician. Installation should be made in accordance with the U.S. National Electrical Code, all local codes and the information detailed below.
2. When received from the factory, multiple voltage (208/230/460) machines are internally connected for 460 volt input.
3. Single voltage, 575 VAC machines, can only be connected to 575 VAC. No internal reconnection for other input voltages is possible.
4. Initial 208 VAC and 230 VAC operation will require a voltage panel setup, as will later reconnection back to 460 VAC:
a. Open the access panel on the right side of
the machine.
b. For 208 or 230: Position the large switch to
200-230. For 460: Position the large switch to 380-460.
c. Move the “A” lead to the appropriate terminal.
CAUTION: DO NOT CHANGE SWITCH
POSITION WITH INPUT POWER APPLIED. MAJOR DAMAGE WILL RESULT.
INPUT VOLTAGE SETUP
V300-PRO
INSTALLATION
A-4 A-4
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POWER INPUT CONNECTION
Connect terminal marked to earth ground per any existing local or national electrical codes.
Single Phase Input
Connect the supply lines to the upper and lower termi­nals of the line switch. Torque to 27.5in.-lbs.(3.0 Nm). Do not use center terminal of the line switch.
Three Phase Input
Connect the supply lines to the line switch. Torque to
27.5in.-lbs.(3.0 Nm). Install in accordance with all local and national electric
codes. The V300-PRO is supplied with one cord connector to
provide strain relief for the input power cord. It is designed for a cord diameter of .310-1.070” (7.9 -
27.2mm). The jacketed portion of the cord must go through the connector before tightening the connector screws.
CONNECTION OF WIRE FEEDERS TO THE INVERTEC
LN-25 Connection Instructions
1. Turn the Invertec power switch “off”.
2. Connect the electrode cable to the output terminal of polarity required by electrode. Connect the work lead to the other terminal.
3. LN-25 with remote control options K431 and K432. Use K876 adapter with K432 cable or modify K432 cable with K867 universal adapter plug. See con­nection diagram S19899 and S19309 or S19405 in Operator’s Mamual.
4. Place the local-remote switch in the “remote” posi­tion if output control is desired at the wire feeder rather than the Invertec. (LN-25 must have K431 and K432 options for remote output control opera­tion).
LN-7 Connection Instructions (not applicable to IEC machines with only 42V Aux.).
1. Turn the Invertec power switch “off”.
2. Connect the K480 or K1818-10 control cable from
the LN-7 to the Invertec control cable connector. The control cable connector is located at the rear of the Invertec.
3. Connect the electrode cable to the output terminal
of polarity required by electrode. Connect the work lead to the other terminal.
4. Place the local-remote switch in the “local” position
to allow output control at the Invertec. (K864 remote control adapter and K857 remote control are required for remote output control. See con­nection diagram S19901.
5. Set the meter polarity switch on the rear of the
Invertec to coincide with wire feeder polarity used. The wire feeder will now display the welding volt­age.
6. If a K480 or K1818-10 is not available, see con-
nection diagram S19404 for modification of K291 or K404 LN-7 input cable with K867 universal adapter plug..
Recommended Fuse Sizes Based On The U.S.
National Electrical Code And Maximum Machine
Outputs
Fuse Size in Amps
Input Volts
(1)
(Time Delay Fuses)
208 60
3 phase 230 60
50/60 Hz 460 40
575 25
1 phase 208 85
50/60 Hz 230 80
460 50
(1)
Input voltage must be within ±10% of rated value.
V300-PRO
INSTALLATION
A-5 A-5
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LN-9 GMA Connection Instructions (Not applicable to machines with only 42V Aux.)
1. Turn the Invertec power switch “off”.
2. Connect the K596 or K1820-10 control cable assembly from the LN-9 GMAto the Invertec control cable connector. The control cable connector is located at the rear of the Invertec.
3. Connect the electrode cable to the output terminal of polarity required by electrode. Connect the work lead to the other terminal.
4. Place the local-remote switch in the “remote” posi­tion to allow output control at the LN-9 GMA.
5. Set the meter polarity switch on the rear of the Invertec to coincide with wire feeder polarity used. The wire feeder will now display the welding volt­age.
6. K608-1* adapter is required in LN-9 GMA for LN-9 type control. K608-1 is installed in line with P10. See connection diagram S20607.
7. K442-1* Pulse Power Filter Board is also required for GMAW,but should beremoved for FCAW.
8. If K596 is not available, see connection diagram S20608 for modification of K196 LN-9 GMA input cable with K867 universal adapter plug.
* These kits are no longer available.
GENERAL INSTRUCTIONS FOR CONNEC­TION OF WIRE FEEDERS TO INVERTEC
Wire feeders other than LN-7 and LN-25 may be used provided that the auxiliary power supply capacity of the Invertec is not exceeded. K867 universal adapter plug is required. See connection diagram S19406 and S19386 for more information.
Remote Control of Invertec
Remote control K857, hand amptrol K963 and foot amptrol K870 require K864 remote control adapter. See connection diagram S19309.
K954-1 MIG PULSER
The MIG Pulser is a hand-held “pendant” type GMAW Pulsing option for the V300-PRO Power Source. See the Mig Pulser’s IM manual (IM555) for connection information.
K900-1 DC TIG STARTER CONNECTION
This versatile new kit was made to mate with the Invertec
A control cable assembly is supplied with the kit to connect the kit to an Invertec. The cable can be con­nected, either end, at the DC TIG Starter kit and at the Invertec by attaching to the 14-pin Amphenols on the backs of each unit. See diagram S20405.
A negative output cable assembly is also supplied with the DC TIG Starter kit to connect the kit with the Invertec’s negative output terminal.
All Magnum™ one and two piece water-cooled torches with 7/8 left-hand threads and gas-cooled torches with 7/8 and 5/16 right-hand threads can be connected to the starter kit.
To secure the DC TIG Starter kit to the bottom of the Invertec and for more detailed instructions, see the K900-1 (IM465) manual.
PARALLEL OPERATION
The Invertec is operable in parallel in both CC and CV modes. For best results, the currents of each machine should be reasonably well shared. As an example, with two machines set up in parallel for a 400 amp procedure, each machine should be set to deliver approximately 200 amps, not 300 amps from one and 100 amps from the other. This will minimize nuisance shutdown conditions. In general, more than two machines in parallel will not be effective due to the voltage requirements of procedures in that power range.
To set machine outputs, start with output control pots and arc force/pinch pots in identical positions. If run­ning in a CC mode, adjust output and arc force to maintain current sharing while establishing the prop­er output current. In CV modes, set the pots to iden­tical positions. Then switch the machine meters to read amps and adjust one of the output control pots for current balance. Check the voltage and if read­justment is necessary, repeat the current balancing step. Pinch settings should also be kept identical on the machines.
V300-PRO
INSTALLATION
A-6 A-6
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OUTPUT CABLES
Select the output cable size based upon the following chart.
Cable sizes for Combined Length of Electrode and Work Cable (Copper) 75° rated:
Duty Length Up 61-76m
Cycle Current 61m (200 ft.) (200-250 ft.)
100% 250 1/0 1/0
60% 300 1/0 2/0
QUICK DISCONNECT PLUGS (K852-7)
A quick disconnect system is used for the welding cable connections. The welding plug included with the machine is designed to accept a welding cable size of 1/0 to 2/0.
1. Remove 1 inch (25mm) of welding cable insulation.
2. Slide rubber boot on to the cable end. The boot
end may be trimmed to match the cable diameter. Soap or other lubricant will help to slide the boot over the cable.
3. Slide the copper tube into the brass plug.
4. Insert the cable into the copper tube.
5. Tighten set screw to collapse copper tube. The
screw must apply pressure against welding cable. The top of the set screw will be well below the sur­face of the brass plug after tightening.
6. Slide the rubber boot over the brass plug. The rub-
ber boot must be positioned to completely cover all electrical surfaces after the plug is locked into the receptacle.
25 mm
1 in.
WELDING CABLE
BOOT
TRIM
SET SCREW
BRASS PLUG
COPPER TUBE
reverse 25mm & 1in
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V300-PRO
Section B-1 Section B-1
TABLE OF CONTENTS
- OPERATION SECTION -
Operation ................................................................................................................Section B
Operating Instructions ........................................................................................... B-2
Controls and Settings .................................................................................... B-2, B-4
Auxillary Power ..................................................................................................... B-4
V300-PRO
OPERATION
B-2 B-2
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OPERATING INSTRUCTIONS
DUTY CYCLE
The Invertec is rated at 300 amps, 60% duty cycle for 3 phase inputs (based on a 10 minute cycle). It is also rated at 250 amps, 100% duty cycle.
CONTROL FUNCTION / OPERATION
POWER SWITCH - Place the lever in the “ON” position
to energize the machine. When the power is on, the digital meter will activate and the fan will operate.
ELECTRIC SHOCK can kill.
• Do not touch electrically live parts or electrode with skin or wet clothing.
• Insulate yourself from work and ground.
• Always wear dry insulating gloves.
------------------------------------------------------------------------
FUMES AND GASES can be dangerous.
• Keep your head out of fumes.
• Use ventilation or exhaust to remove fumes from breathing zone.
-------------------------------------------------------
-----------------
WELDING SPARKS can cause fire or explosion.
• Keep flammable material away.
• Do not weld on closed containers.
------------------------------------------------------------------------
ARC RAYS can burn eyes and skin.
• Wear eye, ear and body
protection.
------------------------------------------------------------
See additional warning information at
front of this operator’s manual.
-----------------------------------------------------------
WARNING
OUTPUT CONTROL - This controls the output voltage
in the CV modes and output current in the CC modes. Control is provided over the entire output range of the
power source with 1 turn of the control knob. This con­trol may be adjusted while under load to change power source output.
LOCAL/REMOTE SWITCH - Place in the “LOCAL” position to allow output adjustment at the machine. Place in the “REMOTE” position to allow output adjust­ment at the wire feeder or with a remote control option package.
DIGITAL METER SWITCH - Select either “A” for amps or “V” for volts to display welding current or voltage on the meter.
When welding current is not present, the meter will dis­play the set current for the CC modes or the set volt­age for the CV modes. This set reading is an indication of machine control setting. For a more precise process reading, read meter during actual welding.
.
OUTPUT
OFF
V300-PRO
OPERATION
B-3 B-3
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MODE SWITCH
GTAW Optimized for both scratch start and Hi-
Freq kit use.
CC SOFT Best for EXX18 thru EXX28 stick elec-
trodes.
CC Crisp Use this mode for stick welding with
EXX10 thru EXX14 electrodes. Non­welding applications such as resistive heating or output tests with resistive loads should be done in this mode with Arc Force Control set to minimum.
CV FCAW This setting has been optimized for
Innershield
®
and Outershield®flux-cored
electrodes.
CV GMAW Short circuit, glob and spray transfer
solid wire and gas welding are done in this mode. Low end procedures, less than 16V, may operate better in the FCAW mode.
OUTPUT TERMINALS SWITCH
For processes and equipment that require energized machine terminals (stick, TIG, air-carbon arc cutting or hot tip LN-25), set the Output Terminals Switch to “ON” position.
Set to the REMOTE (OFF) position when using LN-25 with K431/K432 or K624-1 options or other wirefeeders which allow the gun trigger to energize the welding ter­minals.
ARC FORCE/INDUCTANCE CONTROL
This control functions in all modes except GTAW. For CC modes, this control acts as an Arc Force adjust­ment. The arc is soft at the minimum settings and more forceful or driving at the maximum settings. Higher spatter levels may be present at the maximum set­tings.
For CV modes, this control will set the degree of “pinch effect” which predominantly affects short circuit trans­fer. In FCAW, the maximum setting is generally pre­ferred. With GMAW, the upper half of the range is pre­ferred with CO2or high content CO2mixed gas. The
lower
half is for inert gas mixes.
GMAW
FCAW
SMAW SOFT
GTAW
OUTPUT
ON
REMOTE
Nominal Recommended
Mode Process Setting Adjustment Range
CC SMAW 1 EXX18 thru 5 1 (gentle, may stick) to 9
EXX28 stick (forceful, more spatter)
CC SMAW 2 EXX10 thru 6 3 to 10
EXX14 stick
Air Carbon Arc 1 None
Cutting
CV FCAW Innershield or 10 None
Outershield
Air Carbon Arc 1 None
Cutting
CV GMAW* CO2or 25% CO27.5 5 to 10
or similar
gas mixes
98% Ar-2% O2Ar, 5 1 to 10
90% He-7.5% Ar
2.5% CO2and other
predominantly
inert gases
RECOMMENDED SETTINGS FOR SELECTED
APPLICATIONS
Full Range Is 1-10,
1 Is Very Soft, 10 Is Very Crisp
* 1 = Lowest pinch, highest inductance and least spatter.
10 = Highest pinch, lowest inductance and most spatter.
V300-PRO
OPERATION
B-4 B-4
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METER POLARITY SWITCH
The wire feeder polarity switch is located at the rear of the machine. The switch provides a work connection for wire feeder voltmeters. Place the switch in the posi­tion of the electrode polarity indicated by the decal. The switch does not change the welding polarity.
AUXILIARY POWER
A24 VAC @ 1 amp supply is included for use with the LN-25 wire feeder (24 volts needed for K431 and K432 options). This supply is protected by a self­resetting current limiter.
A 42 VAC @ 5.5 amp supply is included for use with other wire feeders. This supply is protected by a 6 amp breaker located on the rear of the machine.
A110/115 VAC @ 2 amp supply is included for use with the LN-7 or LN-9 GMA wire feeders. This supply is protected by a 2.5 amp breaker located on the rear of the machine. It is NOT
available on IEC units.
All three supplies are not to be loaded simultaneous­ly
-
+
OUTPUT TERMINALS
LINCOLN
T13086-84
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V300-PRO
Section C-1 Section C-1
TABLE OF CONTENTS
- ACCESSORIES SECTION -
Accessories ............................................................................................................Section C
Options/Accessories...............................................................................................C-2
V300-PRO
ACCESSORIES
C-2 C-2
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OPTIONS / ACCESSORIES
CABLE PLUGS
Cable Plug Kit for 1/0-2/0 cable (K852-70) attaches to welding cable to provide quick disconnect from machine.
Cable Plug Kit for 2.0-3/0 cable (K852-95).
NOTE: Two K852-70 plugs are included with the V300-I.
K864 REMOTE CONTROL ADAPTER
Plugs into the 14-pin receptacle on the rear panel of the Invertec. Adapter splits remote control circuitry to a 6­pin receptacle and to a 14-pin receptacle. Adapter per­mits remote output control of Invertec by means of K857 Remote Control, K812 Hand Amptrol or K870 Foot Amptrol. Allows remote while using LN-7 K480-7 control cable.
K867 UNIVERSAL ADAPTER PLUG
Consisting of a 14-pin plug connected to labeled wires, the adapter allows user connection of any suitable accessory or wire feeder to the remote control, contac­tor, and auxiliary power circuitry of the Invertec.
K876 REMOTE CONTROL ADAPTER
For operating an LN-25 wire feeder. The adapter connects to the 14-pin receptacle of Invertec power sources and to the 6-pin connector of the LN-25 K432 remote control cable.
K900-1 DC TIG STARTER
Solid state GTAW starting unit. Rated 300 A, 60%.
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V300-PRO
Section D-1 Section D-1
TABLE OF CONTENTS
- MAINTENANCE SECTION -
Maintenance ...........................................................................................................Section D
Input Filter Capacitor Discharge Procedure.......................................................... D-2
Preventive maintenance ........................................................................................ D-3
Overload/Thermal Protection ................................................................................ D-3
Printed Circuit Board Replacement ....................................................................... D-3
V300-PRO
MAINTENANCE
D-2 D-2
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5. Locate the two capacitor terminals (large hex head capscrews)shown in Figure D.1.
6. Use electrically insulated gloves and insulated pli­ers. Hold body of the resistor and connect resistor leads across the two capacitor terminals. Hold resistor in place for 10 seconds. DO NOT TOUCH CAPACITOR TERMINALS WITH YOUR BARE HANDS.
7. Repeat discharge procedure for capacitor on
other side of machine. If you are working on a 575 VAC machine, repeat discharge procedure for second capacitor on each side of machine.
8. Check voltage across terminals of all capacitors with a DC voltmeter. Polarity of capacitor termi­nals is marked on PC board above terminals. Voltage should be zero. If any voltage remains, repeat this capacitor discharge procedure.
INPUT FILTER CAPACITOR DISCHARGE PROCEDURE
1. Turn off input power or disconnect input power lines.
2. Remove 14 5/16” hex head screws from side and top of machine (6 screws on each side and 2 screws on top) and remove wrap-around machine cover.
3. Be careful not to make contact with the capacitor terminals that are located in the center of the Switch Boards.
4. Obtain a high resistance and high wattage resis­tor (25-1000 ohms and 25 watts minimum). This resistor is not supplied with machine. NEVER USE A SHORTING STRAP FOR THIS PROCE­DURE. .
FIGURE D.1 — LOCATION OF INPUT FILTER CAPACITOR TERMINALS.
Failure to follow this capacitor discharge procedure can result in electric shock.
WARNING
V300-PRO
MAINTENANCE
D-3 D-3
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OVERLOAD PROTECTION
The machine is electrically protected from producing high output currents. Should the output current exceed 340-360A, an electronic protection circuit will reduce the current (“Fold Back”) to approximately 150A. The machine will continue to produce this low current until the protection circuit is reset. Reset occurs when the output load is removed.
THERMAL PROTECTION
Thermostats protect the machine from excessive operating temperatures. Excessive temperatures may be caused by a lack of cooling air or operating the machine beyond the duty cycle and output rat­ing. If excessive operating temperature should occur, the thermostat will prevent output voltage or current. The meter will remain energized during this time.
PC BOARD REPLACEMENT
1. Handle PC Boards by edges only.
2. Store PC Boards only in the bags that disperse static charges.
3. Inspect PC Board for burned conductors or com­ponents. If damage is visible, inspect the machine wiring for grounds or shorts to avoid damaging a new PC Board.
4. If there is no visible damage to the PC Board, install a new PC Board and see if the problem is fixed. If the problem is fixed by the new board, reinstall the old board and see if the problem reoccurs. If the problem does not reoccur, check the wiring harness and plugs for loose connec­tions.
PREVENTIVE MAINTENANCE
1. Perform the following preventive maintenance procedures at least once every six months. It is good practice to keep a preventive maintenance record; a record tag attached to the machine works best.
2. Remove the machine wrap-around cover and per­form the input filter capacitor discharge procedure (detail at the beginning of this chapter).
3. Clean the inside of the machine with a low pres­sure airstream. Be sure to clean the following components thoroughly. See Figure D.2 for loca­tion of these components.
• Power Switch, Driver, Protection, and Control
printed circuit boards
• Power Switch
• Main Transformer
• Input Rectifier
• Heat Sink Fins
• Input Filter Capacitors
• Output Terminals
4. Examine capacitors for leakage or oozing. Replace if needed.
5. Examine wrap-around cover for dents or break­age. Repair as needed. Cover must be kept in good condition to assure high voltage parts are protected and correct spacings are maintained.
6. Check electrical ground continuity. Using an ohm­meter, measure resistance between either output stud and an unpainted surface of the machine case. (See Figure D.2 for locations.) Meter read­ing should be 500,000 ohms or more. If meter reading is less than 500,000 ohms, check for electrical components that are not properly insu­lated from the case. Correct insulation if needed.
7. Replace machine cover and screws.
V300-PRO
MAINTENANCE
D-4 D-4
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FIGURE D.2 — LOCATION OF MAINTENANCE COMPONENTS.
ITEM
COMPONENT QTY, NO.
PC BOARDS
CONTROL 1 1 DRIVER 1 2 PROTECTION 1 3 SWITCH 2 7
POWER 1 10 INPUT RECTIFIER 1 4 POWER SWITCH 1 5 HEAT SINK FINS 2 6 MAIN TRANSFORMER 1 8 OUTPUT STUDS 1 9 INPUT FILTER CAPACITORS 2 11
1
6
2
7
3
8
4
9
5
10
11
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V300-PRO
Section E-1 Section E-1
Theory of Operation ...............................................................................................Section E
Power Supply Operation......................................................................................E-2
Pre Charge and Protection Circuitry....................................................................E-3
Switch Board and Main Transformer....................................................................E-4
Control and Output Circuitry ................................................................................E-5
Field Effect Transistor (FET) Operation ...............................................................E-6
Pulse Width Modulation .......................................................................................E-7
Protective Circuits................................................................................................E-8
TABLE OF CONTENTS
- THEORY OF OPERATION SECTION -
FIGURE E.1 – V300-PRO BLOCK LOGIC DIAGRAM
1ø OR 3ø DETETCTION (H5)
LINE SWITCH
INPUT RECTIFIER
AC1 AC2 AC3
A-LEAD
AUXILIARY TRANSFORMER
TO WIREFEEDER
18VAC
24VAC
POWERBOARD
24VDC
PULSE TRAIN
DRIVER BOARD
PRE-CHARGE
PRE-CHARGE
2ND STEP PWM
1ST STEP PWM VOLTAGE
15VDC-CONTROL BOARD FUNCTION VOLTAGE
24VAC-THERMOSTATS-GUN TRIGGERING
LOCAL REMOTE
METER
MODE
POT
POT
PROTECTION BOARD
<1 VDC
RIGHT SWITCH BOARD
FET MODULES
CAP
FET MODULES
FAN
1 2 3
CONTROL BOARD
Y-Y FE EDBACK
CR1
CR2
3A
POWER SWITCH SECTIONS 20KHZ
LEFT SWITCH BOARD
FET MODULES
CAP
FET MODULES
CURRENT TRANSFORMER
MAIN TRANSFORMER
CHOKE
RECTIFIER HEATSINK
BOTTOM
1 DIODE
5 DIODES
5 DIODES
TOP
TOP
1 DIODE
CHOKE
CHOKE
SHUNT
CURRENT FEEDBACK-PROTECTION
VOLTA GE FEEDBACK
V300-PRO
THEORY OF OPERATION
INPUT LINE VOLTAGE & AUXILIARY TRANSFORMER
The V300-PRO can be connected for a variety of three phase or single phase input voltages. Power is applied through the Line Switch to the Input Rectifier and the Auxiliary Transformer.
The Reconnect Panel has switches to select high or low operating voltage. The “A” lead must then be set for the proper input voltage. It is important to set the switches and “A” lead to the proper positions before applying input power. Changing the switch position
with the power applied will result in major damage to the machine
The auxiliary transformer provides 18v.a.c. and 24v.a.c. supplies to the Control and Power Boards. It also provides 115v.a.c., 42v.a.c. and 24v.a.c. supplies to the wirefeeder amphenol. (CE machines do not have 115v.a.c. supply)
The Power Board provides a 15v.d.c. supply to the Control Board and a 24v.d.c.supply to the Driver Board to operate the Pre-charge Relays.
E-2 E-2
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1ø OR 3ø DETETCTION (H5)
LINE SWITCH
INPUT RECTIFIER
AC1 AC2 AC3
A-LEAD
AUXILIARY TRANSFORMER
TO WIREFEEDER
18VAC
24VAC
POWERBOARD
24VDC
PULSE TRAIN
DRIVER BOARD
PRE-CHARGE
PRE-CHARGE
2ND STEP PWM
1ST STEP PWM VOLTAGE
15VDC-CONTROL BOARD FUNCTION VOLTAGE
24VAC-THERMOSTATS-GUN TRIGGERING
LOCAL REMOTE
METER
MODE
POT
POT
PROTECTION BOARD
<1 VDC
RIGHT SWITCH BOARD
FET MODULES
CAP
FET MODULES
FAN
1 2 3
CONTROL BOARD
Y-Y FEEDBACK
CR1
CR2
3A
POWER SWITCH SECTIONS 20KHZ
LEFT SWITCH BOARD
FET MODULES
CAP
FET MODULES
CURRENT TRANSFORMER
MAIN TRANSFORMER
CHOKE
RECTIFIER HEATSINK
BOTTOM
1 DIODE
5 DIODES
5 DIODES
TOP
TOP
1 DIODE
CHOKE
CHOKE
SHUNT
CURRENT FEEDBACK-PROTECTION
VOLTA GE FEEDBACK
FIGURE E-2 --- INPUT CIRCUITS
NOTE: Unshaded areas of block logic diagram are the subject of discussion
V300-PRO
THEORY OF OPERATION
PRECHARGE & PROTECTION CIRCUITS
The DC voltage from the Input Rectifier is applied to the Driver Board to begin charging the Switch Board capacitors at a slow rate. When the pre-charge level is achieved, the input relays close, applying the full DC voltage to the capacitors. Depending on the Code Number of the machine, there will be either two or four relays and they may or may not be mounted on the Driver Board.
The Driver Board is also responsible for gating the Field Effect Transistors (FETs) on the Switch Boards, as directed by the pulse width modulated (PWM) signal from the Control Board.
The Protection Board monitors the capacitors for prop­er balance and voltage level. If an imbalance or over­voltage condition is detected, the Protection Circuit will de-energize the relays, removing the power from the switch circuits. The machine output will also be dis­abled.
Another function of the Protection Board is to detect whether the input voltage is single phase or three phase and pass that information to the Control Board. The maximum output of the machine will be limited to approximately 250 amps with single phase input and 360 amps with 3 phase input.
E-3 E-3
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FIGURE E-3 ---PRECHARGE & PROTECTION CIRCUITS
1ø OR 3ø DETETCTION (H5)
LINE SWITCH
INPUT RECTIFIER
AC1 AC2 AC3
A-LEAD
AUXILIARY TRANSFORMER
TO WIREFEEDER
18VAC
24VAC
POWERBOARD
24VDC
PRE-CHARGE
2ND STEP PWM
1ST STEP PWM VOLTAGE
15VDC-CONTROL BOARD FUNCTION VOLTAGE
24VAC-THERMOSTATS-GUN TRIGGERING
LOCAL REMOTE
METER
MODE
POT
POT
<1 VDC
FAN
1 2 3
CONTROL BOARD
Y-Y FEEDBACK
3A
POWER SWITCH SECTIONS 20KHZ
CURRENT TRANSFORMER
MAIN TRANSFORMER
CHOKE
RECTIFIER HEATSINK
BOTTOM
1 DIODE
5 DIODES
5 DIODES
TOP
TOP
1 DIODE
CHOKE
CHOKE
SHUNT
CURRENT FEEDBACK-PROTECTION
VOLTA GE FEEDBACK
PULSE TRAIN
DRIVER BOARD
PRE-CHARGE
CR1
CR2
LEFT SWITCH BOARD
FET MODULES
CAP
FET MODULES
RIGHT SWITCH BOARD
FET MODULES
CAP
FET MODULES
PROTECTION BOARD
NOTE: Unshaded areas of block logic diagram are the subject of discussion
V300-PRO
THEORY OF OPERATION
SWITCH BOARDS
The Switch Boards contain the the Field Effect Transistors (FETs) which, when switched ON, supply power to the primary windings of the main transformer. Each Switch Board powers a separate, oppositely wound primary winding. The opposite direction of cur­rent flow in those windings and a slight offset in of the FET switching produces a square wave AC signal in the secondary of the transformer.
The DC current of the primaries is clamped back to the respective capacitors through diodes on the board when the FETs turn off. This protects against inductive voltage spikes due to the inductance of the windings and also helps maintain capacitor balance.
The boards are fired during a 50 microsecond interval with respect to a Pulse Width Modulated (PWM) signal from the Control Board through the Driver Board. This creates a constant 20Khz output in the secondary.
Along with ease of control, the 20Khz operating fre­quency allows for a much smaller and lighter trans­former
Signals from the Current Transformer insure that one switch circuit is turned off before the other is gated on.
Field Effect Transistor operation and Pulse Width Modulation are discussed in more detail later in this section.
E-4 E-4
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NOTE: Unshaded areas of block logic diagram are the subject of discussion
FIGURE E-4 ---SWITCH CIRCUITS & TRANSFORMER
1ø OR 3ø DETETCTION (H5)
LINE SWITCH
INPUT RECTIFIER
AC1 AC2 AC3
A-LEAD
AUXILIARY TRANSFORMER
TO WIREFEEDER
18VAC
24VAC
POWERBOARD
24VDC
PRE-CHARGE
2ND STEP PWM
1ST STEP PWM VOLTAGE
15VDC-CONTROL BOARD FUNCTION VOLTAGE
24VAC-THERMOSTATS-GUN TRIGGERING
LOCAL REMOTE
METER
MODE
POT
POT
<1 VDC
FAN
1 2 3
CONTROL BOARD
Y-Y FEEDBACK
3A
POWER SWITCH SECTIONS 20KHZ
CHOKE
RECTIFIER HEATSINK
1 DIODE
5 DIODES
5 DIODES
1 DIODE
CHOKE
CHOKE
SHUNT
CURRENT FEEDBACK-PROTECTION
VOLTA GE FEEDBACK
PULSE TRAIN
DRIVER BOARD
PRE-CHARGE
CR1
CR2
PROTECTION BOARD
TOP
TOP
CURRENT TRANSFORMER
LEFT SWITCH BOARD
FET MODULES
CAP
FET MODULES
MAIN TRANSFORMER
RIGHT SWITCH BOARD
FET MODULES
CAP
FET MODULES
BOTTOM
V300-PRO
THEORY OF OPERATION
OUTPUT AND CONTROL CIRCUITS
The AC output of the transformer is changed to DC by the Output Rectifier. The Output Choke between the negative side of the rectifier and the negative output stud provides the necessary filtering for DC welding. The two smaller chokes and their series diodes are the OCV boost circuit used to help provide good weld starts.
Current feedback to the Control Board is provided by the shunt in the negative output circuit. It is used for weld control, overcurrent protection and actual amme­ter readings. The V oltage feedback lead at the positive output stud also provides information for weld control and actual voltmeter readings.
The Control Board monitors input from the front panel controls (output, arc control, mode switch, etc..). The software on the board processes these inputs, sets up the proper weld information and sends the “set” para­meter information to the meter.
When weld output is requested, the Control Board compares the input information to the feedback signals and provides the correct PWM signals to the Switch Boards for optimum welding. The Mode Switch setting determines which feedback signal (voltage or current) will have the most relevance. However, both signals are used in all modes.
The Control Board also monitors signals from the ther­mostats and the Protection Board and if necessary, shuts off the weld output. The protection circuit infor­mation is discussed in more detail later in this section.
E-5 E-5
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1˘ OR 3˘ DETETCTION (H5)
LINE SWITCH
INPUT RECTIFIER
AC1 AC2 AC3
A-LEAD
AUXILIARY TRANSFORMER
TO WIREFEEDER
18VAC
24VAC
POWERBOARD
24VDC
PRE-CHARGE
2ND STEP PWM
1ST STEP PWM VOLTAGE
15VDC-CONTROL BOARD FUNCTION VOLTAGE
24VAC-THERMOSTATS-GUN TRIGGERING
<1 VDC
FAN
1 2 3
3A
POWER SWITCH SECTIONS 20KHZ
PULSE TRAIN
DRIVER BOARD
PRE-CHARGE
CR1
CR2
PROTECTION BOARD
TOP
TOP
LEFT SWITCH BOARD
FET MODULES
CAP
FET MODULES
MAIN TRANSFORMER
RIGHT SWITCH BOARD
FET MODULES
CAP
FET MODULES
BOTTOM
1 DIODE
5 DIODES
5 DIODES
1 DIODE
CHOKE
SHUNT
RECTIFIER HEATSINK
CHOKE
CHOKE
CURRENT TRANSFORMER
VOLTA GE FEEDBACK
CURRENT FEEDBACK-PROTECTION
CONTROL BOARD
Y-Y FEEDBACK
LOCAL REMOTE
METER
MODE
POT
POT
FIGURE E-5 --OUTPUT & CONTROL CIRCUITS
NOTE: Unshaded areas of block logic diagram are the subject of discussion
V300-PRO
THEORY OF OPERATION
An FET is a type of transistor. FETs are semiconduc­tors well suited for high-frequency switching because they are capable of going from full off to full on much more quicklfy than other types of semi-conductors.
Drawing A above shows an FET in a passive mode. There is no gate signal, zero volts relative to the source and, therefore, no current flow. The drain terminal of the FET may be connected to a voltage supply; but since there is no conduction, the circuit will not supply current to downstream components connected to the source. The circuit is turned off like a light switch in the OFF position.
Drawing B above shows the FET in an active mode. When the gate signal, a positive DC voltage relative to the source, is applied to the gate terminal of the FET, it is capable of conducting current. Avoltage supply con­nected to the drain terminal will allow the FET to con­duct and henceforth supply current to downstream components. Current will flow through the conducting FET to downstream components as long as the gate signal is present. This is similar to turning on a light switch
E-6 E-6
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SOURCE TERMINAL
GATE TERMINAL
DRAIN TERMINAL
DRAIN (N)
N CHANNELSUBSTRATE (P)
SOURCE (N)
(0 VOLTS)
GATE TERMINAL (+ 6 VOLTS)
DRAIN (N)
ELECTRONS
SOURCE (N)
B. ACTIVE
A. PASSIVE
FIELD EFFECT TRANSISTOR OPERATION
V300-PRO
THEORY OF OPERATION
E-7 E-7
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Since only 2 microseconds of the 50-microsecond time period is devoted to conducting, the output power is minimized.
MAXIMUM OUTPUT
By holding the gate signals on for 24 microseconds each and allowing only 2 microseconds of dwell time (off time) during the 50-microsecond cycle, the output is maximized. The darkened area under the top curve can be compared to the area under the bottom curve. The more dark area under the curve, the more power is present.
The term PULSE WIDTH MODULATION is used to describe how much time is devoted to conduction in the positive and negative portions of the cycle. Changing the pulse width is known as MODULA­TION. Pulse Width Modulation (PWM) is the varying of the pulse width over the allowed range of a cycle to affect the output of the machine.
MINIMUM OUTPUT
By controlling the duration of the gate signal, the FET is turned on and off for different durations during a cycle. The top drawing above shows the minimum output signal possible over a 50-microsecond time period.
The positive portion of the signal represents one FET group1conducting for 1 microsecond. The negative portion is the other FET group1. The dwell time (off time) is 48 microseconds (both FET groups off).
FIGURE E.6 — TYPICAL FET OUTPUTS.
MINIMUM OUTPUT
MAXIMUM OUTPUT
24
50
24
2
48 50
sec sec
sec
sec
sec
sec
sec
sec
PULSE WIDTH MODULATION
1
An FET group consists of the sets of FET modules grouped onto one switch board.
V300-PRO
THEORY OF OPERATION
E-8 E-8
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THERMAL PROTECTION
Thermostats protect the machine from excessive operating temperatures. Excessive temperatures may be caused by a lack of cooling air or by operat­ing the machine beyond it’s duty cycle or output rat­ing. If excessive operating temperature should occur, the thermostat will open and prevent output. The meter will remain on during this time. Thermostats will normally self-reset once the machine cools suffi­ciently.
If the thermal shutdown was caused by excessive output or duty cycle and the fan is operating normal­ly, the Power Switch may be left on and the reset should occur within a 15-minute period. If the fan is not turning or the air intake louvers were obstructed, then the power must be switched off for 15 minutes in order to reset. The fan problem or air obstruction must also be corrected.
PROTECTIVE CIRCUITS
Protective circuits are designed into the Invertec machine to sense trouble and shut down the machine before the trouble damages the internal machine components. Both overload and thermal protection circuits are included.
OVERLOAD PROTECTION
The machine is electronically protected from produc­ing excessive output current. Should the output cur­rent exceed 340 to 360 amps, an electronic protec­tion circuit will reduce the current to approximately 150 amps. Lincoln Electric refers to this current reduction as “Fold Back.” The machine will continue to produce this low current until the protection circuit is reset by removing the load.
Another protection circuit is included to monitor the voltage across input filter capacitors. In the event that the capacitor voltage is too high, the protection circuit will signal the Control Board to prevent output. The protection circuit may prevent output, if any of these circumstances occur:
1. Capacitor conditioning is required (Required if machine has been off for prolonged periods of time.)
2. Line surges over 500 VAC
3. Internal Component damage
4. Improper connections
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