Wednesday, 7 November 2012

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Tuesday, 6 November 2012

e-Weldone Newsletter - Oct 2012

e-Weldone Newsletter October  2011 Vol. 39
Product Update
SAFETY PRECAUTIONS IN GAS CUTTING AND WELDING
Introduction
Oxy/fuel gas equipment has many uses - welding, cutting, heating, straightening, and descaling. Oxy fuel process may use a variety of fuel gases such as acetylene, LPG, Propane, Nitrogen, natural gas, the most common being acetylene. The equipment is versatile, easy to move and cheap. It is so widely used that sometimes people forget about the dangers. Many people are injured each year by the incorrect or careless use of oxy/fuel gas equipment. Some people die. This paper describes the hazards associated with portable oxy/fuel gas equipment and the precautions for avoiding injury and damage to property.
The Main Hazards are:
  1. Fire caused by heat, sparks, molten metal or direct contact with the flame.
  2. Explosion when cutting up or repairing tanks or drums which contain or may have contained flammable materials.
  3. Explosion caused by gas leaks.
  4. Explosion caused by backfires and flashbacks.
  5. Fumes created during flame cutting.
  6. Fire/burns resulting from misuse of oxygen.
  7. Burns from contact with the flame or hot metal.
  8. Crushing or impact injuries when handling and transporting cylinders.
Figure 1: Standard Oxy-Acetylene Cutting Set up
Some of the precautions to be taken to avoid injury and damage are described below.
1. Preventing fire from heat, sparks, molten metal or direct contact with flame
The flame from an oxy/fuel gas torch (often called a ‘blowpipe’) is a very powerful source of ignition. Careless use of oxy/fuel torches has caused many fires. The flame will quickly set light to combustible material such as wood, paper, cardboard, textiles, rubber, and plastics. Many processes also generate sparks and hot spatter which can also ignite these materials.

The following precautions will help prevent fire:
  • Move the workpiece to a safe location for carrying out hot work.
  • Remove nearby combustible materials (such as flammable liquids, wood, paper, textiles, packaging or plastics).
  • Protect nearby combustible materials that cannot be moved. Use suitable guards or covers such as metal sheeting, mineral fibre boards or fire-retardant blankets.
  • Check that there are no combustible materials hidden behind walls or in partitions, particularly if the welding or cutting will go on for some time. Some wall panels contain flammable insulation materials, e.g. polystyrene.
  • Use flame-resistant sheets or covers to prevent hot particles passing through openings in floors and walls (doorways, windows, cable runs, etc).
  • If the consequences of a fire are severe, eg work inside ships, you may need to appoint a fire watch during and after the work finishes. It is normal to maintain fire watch for 30 minutes after hot work finishes.
  • Prevent flame, heat, sparks or hot spatter from landing on the hoses.
  • Keep fire extinguishers nearby.
2. Explosion when cutting up or repairing tanks, drums and tyres
Figure 2: Cutting up scrap
If a welding blowpipe or burner is used on a tank or drum containing flammable material (solid, liquid or vapour), it can explode. Such explosions have killed people.
As well as flammable liquids such as petrol, diesel and fuel oil, substances such as paints, glue, anti-freeze and cleaning agents may also release flammable vapours.
Tanks and drums that are ‘empty’ usually still have residues in the bottom, and in seams and crevices. Just a teaspoon of flammable liquid in a drum can be enough to cause an explosion.

Never use an oxy/fuel gas blowpipe on a drum or tank that has contained, or may have contained, flammable material, unless you know it is safe. It may be safer for a specialist company to carry out the work. If in doubt, ask.
Tyres
The heat from hot work can generate flammable vapour from any oil or flammable residue on the inner rim of the wheel. The rubber itself can degrade when heated and release flammable materials and toxic emissions. This vapour, confined by the tyre can cause an explosion. These explosions are very violent and can kill. Avoid welding or flame cutting on wheels which have tyres fitted, even if the tyre is deflated.
If you can’t remove the tyre, use cold cutting methods, e.g. a saw or hydraulic shears.
3. Fire/explosion caused by gas leaks
Acetylene, LPG and other fuel gases are highly flammable, and form explosive mixtures with air and oxygen. Even small leaks can cause a flash fire or explosion, particularly if they are leaking into a poorly ventilated room or confined space where the gases can accumulate. Gas leaks are often the result of damaged or poorly maintained equipment, poor connections or not closing valves properly after use.

The following precautions will help to prevent leaks:
  • Turn the gas supply off at the cylinder when the job is finished or before the cylinders are moved or transported.
  • Isolate and purge or remove hoses and equipment from enclosed or poorly ventilated spaces when there is a break in work.
  • Keep hoses away from sharp edges and abrasive surfaces or where vehicles can run over them.
  • Do not allow hot metal or spatter to fall on hoses.
  • Maintain all equipment and regularly check its condition.
Checking for leaks
Regularly check all connections and equipment for faults and leaks. Equipment used in aggressive conditions such as demolition work or heavy engineering will normally need more frequent checks, e.g. weekly.
  • Use a proprietary leak detecting spray or solution suitable for use with oxy/fuel systems. Do not use soapy water or solutions containing grease or oils on oxygen systems.
  • Never look for gas leaks with a naked flame.
  • Immediately repair or replace leaking components.
Leaking hoses should not be repaired, but they can be shortened to remove a damaged section. Refit hose tails using crimp clips designed for that task. Screw tightened crimps (jubilee clips) are not recommended. There is a risk of leaks due to over tightening or under tightening them.

If a cylinder leaks when the valve is closed
If it is safe to do so, move the cylinder outside and away from sources of ignition (naked flames, sparks, electric motors, etc). Prevent unauthorised access and notify the cylinder supplier immediately.
4. Explosion caused by Backfires and flashbacks
Backfires
A backfire is when the flame burns back into the torch, often with a sharp bang.
This may happen when the torch is held too close to the workpiece, or if the nozzle is partly blocked. The flame may go out or it may reignite at the nozzle. Sometimes the flame burns back into the torch, and burning continues inside it. Backfires do not usually cause injury or damage, but they can indicate a fault in the equipment.
If a backfire does occur:
  • Shut off the torch valves, oxygen first (usually coloured blue) and then the fuel gas (usually coloured red).
  • Shut off the oxygen and fuel gas cylinder valves.
  • Cool the blowpipe with water if necessary.
  • Check the equipment for damage or faults, particularly the nozzle.
Flashbacks
Flashbacks are commonly caused by a reverse flow of oxygen into the fuel gas hose (or fuel into the oxygen hose), producing an explosive mixture within the hose. The flame can then burn back through the torch, into the hose and may even reach the regulator and the cylinder. Flashbacks can result in damage or destruction of equipment, and could even cause the cylinder to explode.

The following precautions will help to prevent flashbacks:
  • Use the correct lighting-up procedure. Purge the hoses before lighting the torch to remove any potentially explosive gas mixtures. Use a spark igniter and light the gas quickly after turning it on.
  • Make sure the blowpipe is fitted with spring-loaded non-return valves.
  • Use the correct gas pressures and nozzle size for the job.
  • Maintain the equipment in good condition.
These measures will reduce the risk of a flashback but will not completely eliminate it. Non-return valves will not stop a flashback once it has occurred.
Protecting cylinders from flashbacks
Fit flashback arresters to both the oxygen and fuel gas hoses near to the regulators. For long lengths of hose, fit arresters on both the torch and the regulator.
Figure 3: Flashback Arrestor
The fitting of a flashback arrester is not a substitute for safe working practice.
If a flashback does occur:
  • If it is safe to do so, close the cylinder valves on both fuel gas and oxygen.
  • If the fire cannot be put out at once, evacuate the area and call the emergency fire services.
  • After a flashback, carefully check for damage to the torch, hoses, regulators, flashback arresters and other components. Replace parts if you need to. If in doubt, consult your supplier.
Acetylene cylinders
You should pay particular attention to any acetylene cylinder which has been involved in a flashback or affected by fire. There is a risk that the acetylene could start to decompose, and the cylinder could explode. If an acetylene cylinder becomes hot or starts to vibrate, you must evacuate immediately and call the emergency fire services.
5. Fumes created during welding and  flame cutting
The fume from welding and flame cutting metals is harmful. You can use fume extraction and/or filtering respirators (respiratory protective equipment or RPE) to reduce the risk of ill health.

Dirt, grease and other contamination increases the amount of fume generated and can introduce very toxic substances to it. Hot work on items with lead paint, chromium (chromate) paint or cadmium plating is particularly hazardous.
  • If you flame cut outdoors and the metal is clean and unpainted you will not normally need RPE. Try to work in a position where the wind blows the fume cloud away from you and other people.
  • If you flame cut indoors or in conditions were there is little air movement, the need for extraction and/or RPE depends on how much cutting you are going to do.
  • Automated flame cutting machines, particularly multi-head machines need fume extraction fitted to them.
  • Work on materials coated with lead or chromate paints, galvanised or cadmium  plated or metal contaminated with oil, grease etc are likely to require fume control such as extraction and/or RPE.
6. Fire/burns from misuse of oxygen
Oxygen leaks also increase the fire risk. Clothing contaminated with oxygen, even fire-retardant clothing, will catch fire easily and burn very fiercely. Oxygen can cause explosions if used with incompatible materials. In particular, oxygen reacts explosively with oil and grease.

You must take the following precautions:
  • Never use oxygen to blow dust off clothing.
  • Never attempt to improve air quality inside confined spaces by releasing oxygen in the space.
  • Never allow oil or grease to come into contact with oxygen valves or cylinder  fittings.
  • Only use equipment designed for use with oxygen. In particular, check that the regulator is safe for oxygen and for the cylinder pressure.
7. Contact burns
The following precautions will help to prevent burns from contact with the flame, hot metal, sparks and molten slag:
  • Work in a safe location away from other people.
  • Wear protective clothing, boots, gauntlets and eye protection.
  • Shut off the torch when not in use. Do not leave a lighted torch on a bench or the floor as the force of the flame may cause it to move.
  • Clamp the workpiece, avoid holding it by hand.
8. Crushing or impact injury
The following precautions will help prevent injury when handling and transporting cylinders:
  • Prevent cylinders from falling or being knocked over by securing them with a stout chain or strap. It is normal to chain them to a wheeled trolley or against a wall.
  • If a cylinder falls over and its valve strikes something and is knocked off, the cylinder will become a deadly missile.
  • Avoid moving a cylinder by tilting it on its base and rolling it. It is better to use a trolley.
  • If transported in a road vehicle, the cylinders should be secured so they don’t come loose in an accident.
 Training
Oxy/fuel equipment is relatively easy to use but users may still need some instruction or training in:
  • The safe use of the equipment, including the correct methods to purge the gas, light and shut down.
  • General safe working practices and the precautions to take.
  • Ensure personal safety by wearing eye goggles and protective work clothing during operation.
  • Hose pipes have a colour code. Use the right colour hose pipe for the particular gas eg LPG should not be used in pipe coded for acetylene. 
  • Use genuine spares when replacing/ repairing equipment.
  • When and how to use the fire extinguishers.
  • Information about escape routes, how to raise the fire alarm and emergency procedures.
Permit-to-work
The potential for injury and property damage are such that many companies want to control hot work very closely. One way to achieve this is to operate a written permit system for welding and flame cutting work. Sometimes called hot work permits, they aim to ensure that welding and flame cutting does not start until after the risks for that particular task are identified and measures to eliminate or control risk are in place.

 A permit should specify:
  • What work will be done.
  • How and when it is to be done.
  • What safety and health precautions are needed.
  • Who is responsible for checking it is safe to start.
  • Who will check the work is done safely.
  • Who is responsible for confirming that work is complete and there is no longer a  risk from, or to, the people doing the work.
Preventing fire or explosion when storing and transporting cylinders
Small leaks may not be detected immediately. If they leak into a poorly ventilated room, a van or confined space, a dangerous concentration of gas may accumulate.

To prevent gas accumulating:
  • Close the cylinder valves when the equipment is not in use.
  • Always provide adequate ventilation during welding and cutting operations.
  • Store gas cylinders outside whenever possible, or in a well-ventilated place.
  • Avoid taking gas cylinders into poorly ventilated rooms or confined spaces.
The most important safety measure when transporting cylinders in vehicles is to close the cylinder valve. It is preferable to carry cylinders in an open-backed, pick-up style van. Fitting cages to the load bed may help prevent theft of the equipment. If cylinders are carried in enclosed load spaces then there should be additional ventilation fitted. Cabin ventilation is not sufficient.
For further information on safety precautions and to know more about AWL range of Gas Cutting Products and Accessories, please do write on cmo@adorians.com or visit us www.adorwelding.com
  • KING TIGER
    Portable Gas Cutting Machine
  • KING JOIN - AGWT / HT-1
    Gas Heating Torch
  • KING PANTHER
    Portable Gas Cutting Machine
read more
  • KING COOL - 600 AMPS - Medium Duty - PART NO .S12.06.001.0201
  • KING SWORD - 600 AMPS - Heavy Duty - PART NO .S12.06.001.0202
  • HEAVY DUTY EARTHING CLAMP - 600 AMPS
    PART NO. .S12.06.001.0203
  • KING SHIELD- HAND (83 X 108mm)
    PART NO. .S12.06.001.0204
  • KING SHIELD - HEAD
    PART NO. .S12.06.001.0205
  • KING SHIELD - AUTO
    PART NO. .S12.06.001.0206
  • ADOR Welding HAND GLOVES
    PART NO. .S12.06.001.0207
  • ADOR SAFETY FOOTWEAR
read more
Visit our Stand No. 6B01
at
INDIA ESSEN WELDING
& CUTTING 2012
(5th International Trade Fair Joining Cutting Surfacing)
at Mumbai, INDIA
during 30th/31st Oct & 1st Nov. 2012.
Service Clinics
During the Month of
September2012
  • M/s ONSHORE CONSTRUCTION COMPANY  KALAMBOLI –  MUMBAI AREA - 22 Nos.
  • M/s  WMI CRANES JEJURI – PUNE AREA - 17 Nos.
 
Ador Welding Academy (AWA)
 
 
 
Welding ConsumablesWelding & Cutting EquipmentWelding AutomationProject Engineering
 
 
www.adorwelding.com
 
cmo@adorians.com

e-Weldone Newsletter - Sept 2012

e-Weldone Newsletter October  2011 Vol. 39
Product Update
ALUMINUM ALLOYS IN SHIPBUILDING INDUSTRY
Introduction
Steel has an extensive account of providing superior mechanical properties to the ship building industry, but with one major disadvantage: weight. Increasing demands for size have forced ship designers to search for alternative materials which will reduce the weight of the ship without compromising strength. When properly designed, aluminum typically reduces the weight of small structures made of low-carbon steel by over 50%. Weight issues have become increasingly important as advanced technology allows us to build larger ships. Since 1910, the maximum weight of ships has more than doubled, increasing from 46,000 tons to 109,000 tons. Increasing demands for size have forced ship designers to search for alternative materials to reduce the weight of the ship without compromising strength. Dramatic technological advances have allowed aluminum to meet or exceed the minimum strength requirements for normal strength steels currently used in the shipbuilding industry. Another advantage of aluminum is its resistance to corrosion, which is superior to steel - it corrodes over 100 times slower than conventional structural carbon steel used to build ships.

This report elaborates the weight reduction, strength, corrosion resistance, and cost of replacing conventional structural steel with lighter-weight aluminum alloys in the shipbuilding industry.
Advantages:
  • The structural design of a ship should seek to minimize weight. This will reduce cost and minimize the loss of cargo dead-weight due to structure.
  • The weight reduction not also increases fuel efficiency. As a ship gets larger it becomes increasingly difficult to design for fuel efficiency without sacrificing other aspects. In addition, larger ships require larger power plants, which require more fuel. The larger engines and massive quantities of fuel add weight to the already bulky ships. Storage of the fuel also becomes a question. Weight issues have become increasingly important as advanced technology allows us to build larger and larger ships.
  • Aluminum has higher corrosion resistance over steel; this results in increased ship life.
Weight:
Impressive technological advances in strength have allowed aluminum to emerge as a possible replacement for ocean-going ships. With a density of 2.70 g/cm3, aluminum is roughly one-third the weight of steel (r = 7.83 g/cm3). The following table gives the strength to weight ratio of different aluminum alloy and carbon steel.
ASTM material codeMaterial typeTypical Ultimate Tensile Strength, ksiDensity, g/cm3Strength-to-Weight Ratio
7075-T6Aluminum832.80822
2024-T361Aluminum722.80713
5056-H18Aluminum632.66656
6061-T6Aluminum452.71459
3004-H38Aluminum412.71418
FiberglassFiber191.43367
6063-T5Aluminum272.74273
1020 Carbon SteelSteel607.86211
Corrosion:
Aluminum, as indicated by its position in the electromotive force series, is a thermodynamically reactive metal. Among structural metals, only beryllium and magnesium are more reactive. However, aluminum has excellent corrosion resistance due to an extremely adherent oxide film that forms on the surface whenever it is exposed to air or water. This oxide film is highly protective and because it is more thermodynamically inactive, prevents aluminum from corroding further. When exposed to extremely corrosive materials, such as salt water, the oxide film may break down and further corrosion or pitting may occur but at a much lower rate than carbon steel (please see table given below). In contrast, steel’s oxide layer, rust, does not provide a highly protective layer, and as a result, steel continues to corrode. Corrosion behavior of various aluminum and steel alloys in seawater is shown in the table below.
Aluminum AlloyCorrosion Rate, µm/yr% Change in Tensile StrengthSteel AlloyCorrosion Rate, µm/yr
5083-O0.90.0%Structural Carbon Steel (depending on chemistry & temperature)120
5086-O0.9-2.7%105
5454-H341.0-0.7%85
5456-H3211.6-1.170
5456-O0.4-0.4%
Aluminum can be formed through either casting or wrought processes. The designation “wrought” indicates that the alloys are available primarily in the form of worked products, such as sheet, foil, plate, extrusions, tube, forgings, rod, bar, and wire. The working operations and thermal treatments transform the cast ingot structure into a wrought structure. The structure influences the strength, corrosion resistance, and other properties of an aluminum alloy. This study deals only with wrought aluminum alloys because they possess superior strength and corrosion resistance properties to cast aluminum alloys.
Disadvantages:
Two disadvantages of Aluminum are,
  1. The Aluminum alloys cannot meet the maximum yield strengths required in certain Ship building applications—only high-strength, low-alloy steels meet these strength requirements.
  2. Aluminum, at about Rs 102.37 per Kg, costs roughly five times more than steel, at about Rs 22.9 per Kg.
 Developments in High-Strength Aluminum Alloys for Marine Applications
In recent years, progress has been achieved by aluminum producers in the development of improved aluminum alloys specifically targeted at the shipbuilding industry. In 1995 the aluminum manufacturer Pechiney of France registered thealuminum Alloy 5383 and promoted this material to the shipbuilding industry as having improvements over 5083 alloy. These improvements provided potential for significant weight savings in the design of aluminum vessels and included a minimum of 15% increase in the postweld yield strength, improvements in corrosion properties, and a 10% increase in fatigue strength. These developments, coupled with formability, bending, cutting, and weldability characteristics at least equal to that of 5083, made the 5383 alloy very attractive to designers and manufacturers who were pushing the limits to produce bigger and faster aluminum ships.   In 1999, the aluminum manufacturer Corus Aluminum, Germany, came out with the aluminum base Alloy 5059 (Alustar). This alloy was also developed as an advanced material for the shipbuilding industry, providing significant improvements in strength over the traditional 5083 alloy. The 5059 alloy is promoted by Corus as providing improvements in minimum mechanical properties over Alloy 5083. These improvements are referenced as being a 26% increase in yield strength before welding and a 28% increase in yield strength (with respect to Alloy 5083) after welding.

Early testing on the 5059 (Alustar) base alloy indicated that problems could be encountered relating to the weld metal not being capable of obtaining the minimum tensile strength of the base material in the heat-affected zone. One method used to improve the weld tensile strength was to increase the amount of alloying elements drawn from the plate material into the weld. This was assisted by the use of helium additions to the shielding gas during TIG welding, which produces a broader penetration profile that incorporates more of the base material. The use of 5556 filler metal rather than the 5183 filler metal can also help increase the strength of the deposited weld material.

Obviously these high-performance vessels require high-quality welding. The training of welders, development of appropriate welding procedures, and implementation of suitable testing techniques are essential in producing such a high- performance product.
The Future
With the increasing demand to create larger and faster ships, particularly for military service and the development of new, improved, high-performance aluminum base materials, it is apparent that aluminum welding has acquired an interesting and important place in ship building industry.

The most popular welding process for Aluminum is TIG. MIG process also is picking up due to increased productivity angle. But in MIG process, the wire feeding is a critical aspect. The preferred method for feeding soft aluminum wire long distances is the push-pull method. Specially designed drive rolls are needed. Drive-roll tension has to be set in such a way to deliver an even wire-feed rate. Excessive tension will deform the wire and cause rough and erratic feeding; too-little tension results in uneven feeding. Both conditions can lead to an unstable arc and weld porosity.
AWL aluminum welding consumables:
ProcessAWS classificationAWL brandApplication
GTAWER5183Tigfil 5183For total aluminum ships
GTAWER5356Tigfil 5356For total aluminum ships
GTAWER5556Tigfil 5556For total aluminum high speed ships
Tigfil 5356
Magnesium Aluminum Alloy filler metal that is used to weld Aluminum Alloys 5050,
5052, 5083, 5356, 5454, and 5456. The post-anodizing color tint is white  making it a good choice for anodizing applications. The Salt Water  corrosion resistance is very good, making it an ideal choice for many  marine applications. Average tensile strength of weld is 38,000 psi.
Tigfil 5183
5183 is an aluminum filler that has improved strengths on alloys sush as 5086 compared to 5356 that may not meet the needed tensile. Commonly used for welding of marine components, drilling rigs, cryogenics, railroad cars, storage tanks - base metals of 5083, 5086, 5456, to each other or to 5052, 5652 and 5056.
Tigfil 5556
5556 is an aluminum filler that has good ductility and improved crack resistance due to the content of manganese, magnesium and zinc. Commonly used for welding of base materials  5154, 5254, 5454 and 5456.
Conclusion:
The feasibility of replacing steel with aluminum in the shipbuilding industry depends primarily on the application and cost constraints. Demands for greater ship size have forced designers to search for alternative materials to reduce ship weight while maintaining strength. Aluminum alloys meet or exceed the minimum yield strength requirements for normal strength steels and have superior corrosion resistance (steel corroded at a rate of 120 micrometer per year, while in a similar study, aluminum corroded at a rate of only 1 micrometer per year).  However, because of higher costs, aluminum may not be always economical. For high-strength applications, ship builders sacrifice corrosion resistance and weight reduction in favor of the greater strength provided by HSLA steels. When normal strength materials are adequate, ship builders are going in for using aluminum alloys to reduce ship weight and improve corrosion resistance.

Please contact cmo@adorians.com or visit our website www.adorwelding.com for assistance in selection of suitable processes, consumables and training of welders for defect free welding of Aluminum alloys.
 
  • Inverter (IGBT) based, energy efficient TIG welding outfit with built-in HF, for medium and heavy duty welding applications
  • High power factor, high efficiency power soources, resulting over 30% energy savings compared to thyristorised power
    sources
read more
  • Inverter (IGBT) based, energy efficient TIG welding outfit with built-in HF, for medium and heavy duty welding applications
  • High power factor, high efficiency power soources, resulting over 30% energy savings compared to conventional inverter power sources
read more
  • Three phase inverter based, high efficiency and high power factor DC Welder
  • Enhanced Reliability due to SMD technology
read more
The MIGPAC series is a special purpose packaging design for MIG/MAG welding wires aimed at enhancing shop-floor productivity. The MIGPAC significantly reduces downtime caused by spool changeover. This innovative product has gained favourable repute for its enhanced efficiency, excellent feedability and optimal quality.
read more
Service Clinics
During the Month of 
July2012
  • M/S MODERN INDUSTRIES GHAZIABAD- DELHI AREA -
    117 Nos.
  • M/S MAURIA UDYOG BALLABGARH -FARIDABAD – DELHI AREA -
    42 Nos.
 
Ador Welding Academy (AWA)
Certification Course for
Welding Inspector (QC-1)
From: 24th to 28th Sept.2012
Skill Courses
 
Welding ConsumablesWelding & Cutting EquipmentWelding AutomationProject Engineering
 
 
www.adorwelding.com
 
cmo@adorians.com

e-Weldone Newsletter - July 2012

e-Weldone Newsletter October  2011 Vol. 39
Product Update
PRECISION WELDING BY GTAW OR TIG WELDING
Introduction
GTAW or more frequently called as TIG welding process is a process, which is normally used for good quality and precision welding. It is very neat and clean welding process where localized heat is produced by narrow and concentrated arc. The appearance of bead is uniform   with good weld finish. This process is used for welding of steel, copper, aluminium and magnesium material. This welding process is inherently less productive and costlier.
Benefits of TIG welding
  • Narrow arc, resulting into concentrated heat
  • Less heat affected zone
  • No slag formation
  • No molten globule therefore no spatter
  • No flying spark as there is no transfer of metal in the arc
  • No buzzing sound of arc
  • Arc is stable, smooth and quiet
  • No smoke or fumes
  • High quality and low distortion weld
  • Process is easy to mechanise and automate
  • It can weld all  metals
  • It can weld thin sheets
  • Good looking weld bead
Limitations of process
  1. Comparatively lower deposition rates
  2. Good skill of welder is required
  3. To acquire skill lot of practice is required.
  4. Sensitive to cleanliness and contamination
Arc starting
HF start
To ignite the arc we have to superimpose high voltage with high frequency in series with main welding circuit. This voltage produces strong electric field which ionises the argon gas and creates conductive path for current to start. Thoriated tungsten electrode assists in igniting the arc by emitting more free electrons. Once arc is established, main welding current increases to set value. Thus arc is started without touching the electrode to work piece.

In DC TIG welding once the arc is established, HF is cut off and welding is performed. However in AC TIG welding HF superimposition is required continuously.
Touch start or lift arc start
Electrode is touched to work piece and then lifted to initiate the arc.
When electrode is in contact with parent metal, power source reduces the voltage and current. Arc is ignited with lower voltage and current to avoid contamination and burn through. After arc is established, the current increases to set value. This method of arc ignition is used when high voltage is injurious to other circuits of job to be welded and not permitted. (For example welding directly on automobile body)
TIG welding process requires welding equipment with Constant Current (or CC) characteristics and all metals except Aluminum, Magnesium and their alloys can be welded by DC TIG process; Aluminum, Magnesium and their alloys can be welded by AC TIG process.
The relation between Arc voltage (V) and welding current (I) is given by    
 V= 10+0.04*I
Power source with true constant current characteristics gives excellent arc stability and very goon bead shape.
Main components of GTAW process
  1. Constant current power source (DC or AC)
  2. High frequency unit
  3. Torch
  4. Shielding gas
  5. Water circulation unit for high current welding.
  6. Accessories
Power source
There are various types of power sources to meet CC requirement.
DC type: 
     -      Diode type with transductor current control.
     -      Thyristrrised with phase angle control.
     -      Inverter type with PWM control.
AC type:
  • AC Arc Welders with sine wave.
  • Inverter type with square wave AC
Power source provides basic welding power required for heat input. Depending on type of welding (DC or AC TIG), power sources are either DC or AC with CC type voltage and current characteristics. Inverter type power sources are energy efficient and save energy by up to 30% to 35% over diode or thyristor type power sources. Also these energy efficient power sources are light weight and compact. The lower current rating power sources up to 200 amps rating can be single phase machine where as power sources with higher current ratings are three phase machines. The inbuilt or composite TIG welding units have high frequency units built within the power sources.
 
In DC TIG process, basic power source is either static type such as diode, Thyristor or Inverter based DC rectifiers or rotary type such as motor or engine driven generators. The torch is connected to the –ve terminal of the power source. Heat distribution in DC TIG process is 33% at the electrode and 67 % at the job.
  
In AC TIG process, welding power source is AC (for example – Transformer or inverter with square wave AC) which provides alternating current and thus polarity of electrode gets reversed. In positive half cycle oxide cleaning action takes place with 67 % heat distribution at the electrode and 33 % at the job. In negative half cycle there is more penetration with 33 % heat distribution at the electrode and 67 % at the job.
High frequency unit
This is available either as separate unit or built inside the power source. If it is separate unit, then this unit has to connect at the output terminals of power source and TIG torch and earth cables should be connected to this unit.
High frequency units basically provide following in a TIG welding outfit
  • High frequency/high voltage supply which is superimposed on the TIG welding power given from the power source unit
  • Controls for gas pre-flow and post-flow time adjustments, Automatic HF cutoff ,  once the arc is struck and automatic HF start if arc breaks, in case of DC TIG welding
  • Providing HF continuously, gas pre-flow and post-flow controls in case of AC TIG welding
  • Gas pre-flow control helps to remove the air available in the torch, before the arc strikes, thus ensuring positive shielding of weld even during arc striking. The gas post-flow control helps to ensure the shielding of weld puddle until it gets cooled at the end of welding and thus avoids any weld contamination due to atmospheric oxygen/nitrogen etc. It also help to cool down the tungsten electrode, avoiding  oxidation and finally increasing it’s life      
  • Current upslope and down slope controls. Upslope control avoids sudden initial current surge and down slope control avoids/minimizes the crater formation at the end of welding
TIG welding torches
TIG welding Torches form an important part of TIG welding outfit. The gas cooled TIG welding torches have (unlike GMAW or MIG torches) a Tungsten electrode which does not get consumed. TIG torches comprise current carrying cable, gas hose (to carry the shielding gas), torch switch, switch cables and torch head which holds the tungsten electrode. Water cooled torches have additionally water circulating arrangements/pipes ,over and above other components mentioned above.

These torches are normally available with 4 mtr and 8 mtr length cables. AWL offers HIPROTIG series of torches for different current capacities
Tungsten Electrodes used for TIG welding process
Tungsten electrode type and size play very important role in arc stability, particularly in AC TIG welding. Following types of electrodes are generally used in different applications and requirements
  • Pure Tungsten
  • Thoriated Tungsten
  • Zirconiated  Tungsten
Pure tungsten electrodes are generally used for less critical applications and have relatively lesser current carrying capacity.
Thoriated Tungsten electrodes ( 1% to 3% ) have higher current capacity and give better arc starting and arc stability due to their higher electron emission property. They have generally longer life and greater resistance to contamination.
Zirconiated tungsten electrodes (0.3 to 0.5%) have greater resistance to contamination and retain clean balled tip which is preferable, especially for aluminum welding
Appropriate size of electrode must be used and electrodes must be ground properly to maintain a good welding arc.
Water cooled outfits
TIG welding outfits are provided with water cooling units for the cooling of the torch when TIG welding is used for regular production jobs for the full shift with welding currents more than 150A to 200A. The interlocking is provided in such a way that the power source and thus the TIG welding starts only when the required water pressure and flow is available from the water cooling unit. The TIG torch does not get heated up and the welder can continue the welding quite comfortably without any fatigue which is generally due to overheating of torch. 
Pulsed TIG welding
Pulsed TIG welding is normally used when precision TIG welding is to be done, particularly for thin sheet or tube preferably using automation. The problem of excessive heat build up, like joint fit up distortions, widening of weld bead, burn through in extra thin jobs, and bigger HAZ in case of normal TIG welding , can be completely avoided by using pulsed TIG welding process. In pulsed TIG welding heat is applied in a controlled and periodic manner, using pulsing of set welding current.
The aim of pulsing is to achieve maximum penetration without excessive heat build up by allowing high heat during peak current and cooling down the weld pool during background current by maintaining the arc.
Pulse TIG welding offers many advantages when applications call for welding of thin sheets where heat control is required. Pulse TIG controls heat input and reduces distortion of job and improves quality of welding.
Main parameters are
- Peak current
- Peak time
- Background current
- Background time
A power source with pulsing facility will have all controls necessary to fulfill process requirements.
Inverter type DC power source 
  1. Gas pre flow and post flow:
    Starting and stopping the welding operation without pre flow and post flow will cause instant damage to tungston electrode. Observe tip at start and at the end of welding. If colour is grey or black then pre flow and post flow times are less and gas flow is less.
              
    Gas pre-flow control helps to remove the air available in the torch, before the arc strikes, thus ensuring positive shielding of weld even during arc striking. The gas post-flow control helps to ensure the shielding of weld puddle until it gets cooled at the end of welding and thus avoids any weld contamination due to atmospheric oxygen/nitrogen etc. It also help to cool down the tungsten electrode, avoiding oxidation and finally increasing life of electrode.    
  2. Current up slope and down slope:
    Upslope control avoids sudden initial current surge and down slope control avoids/minimizes the crater formation at the end of welding
  3. Peak current:
    To control required heat input as per thickness of sheet  
  4. Back ground current: 
    It is to be set with proportion to peak current to ensure that arc is maintained and job is also cooled.
  5. Peak time and back ground time:
    To be decided by sheet thickness and %overlap required for weld bead. 
Advantages of Pulsed TIG welding
  1. Joint fit up distortions are minimized due to controlled heat input.
  2. Better bead shape, penetration is achieved with relatively less skill of welder
  3. Heat Affected Zone (HAZ) is reduced.
  4. Positional welding is possible without any difficulty of dropping down of molten metal.
  5. Process can be automated.
Applications of TIG process
Welding of aluminum, copper, magnesium nickel and their alloys
Welding of mild steel, stainless steel, inconel and titanium
Welding of bellows
Welding of thin sheets
Application in chemical industry, aircraft industry, manufacturing of food cans
Copper tubes
Stainless steel tubes
Nuclear power plant
Welds can be done with or without filler material depending on thickness of material
Ador Welding Ltd. (AWL) range of TIG and Pulse TIG machines are as follows:
In addition to above TIG outfit with inbuilt HF units, AWL offers separate HF units which can be used along with SMAW Power source. Following combination of models make up TIG outfits of various current ratings.
For more information, Please write to us cmo@adorians.com or visit www.adorwelding.com
 
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cmo@adorians.com