Oxyacetylene Welding Fuels - Professional Welding Fuels ... 002-Geary-Chap01.indd 92-Geary-Chap01.indd 9 33/3/2011 5:27:57 ... metals into various shapes and heat treating metals in

C H A P T E R

9

1Oxyace t y l ene W e ld i ng Fue l s

Performance ObjectivesAfter reading this chapter you should be able to:

n Identify oxygen tanks by their color.

n Understand how acetylene is produced.

n Understand the process used to purify oxygen.

n Know how to store acetylene and oxygen tanks properly.

n Know how to safely handle acetylene and oxygen tanks.

n Know how acetone is used with acetylene.

n Know how to keep gas cylinders properly positioned.

n Know at what temperature an acetylene tank’s safety plug melts.

Welding is a method used to join two or more pieces of metal in such a way as to make the finished piece as strong as the original

metal. The oldest type of welding, oxyacetylene welding, was devel-oped about 100 years ago. There have been many developments in metal joining processes since then.

02-Geary-Chap01.indd 902-Geary-Chap01.indd 9 3/3/2011 5:27:57 PM3/3/2011 5:27:57 PM

1 0 CHAPTER ONE

Metal joining can be broken into three rather broad categories: gas welding, electric welding, and gas-electric welding. The home welder or farmer is not interested in production work or plasma welding.

History of Gas WeldingGas welding is the oldest of all types of welding. It is very simple, in principle. Oxygen and acetylene are burned to produce a flame that is hotter than the melting point of most metals. The temperature of an oxyacetylene flame is generally accepted to be around 6,000°F.

Oxyacetylene is widely used and it is almost unbelievable that this process did not come into existence until the beginning of the 20th century. Oxyacetylene welding was first made possible through the experiments and discoveries of a French chemist, Henri Le Chatelier, in 1895. He was the first to discover that burning oxygen and acetylene produced a flame with a temperature far higher than that of any other flame in existence.

Once the capabilities of oxyacetylene became known to the indus-trial world, it was quickly put to use. After a workable way to store and transport oxygen and acetylene was developed, the road was cleared for widespread use of this new method of joining metals.

During World War I, the use of oxyacetylene welding accelerated. The pressures to supply an army and to repair existing heavy equip-ment brought worldwide attention to oxyacetylene welding. After the war, a need for greater controls over the welding process arose, and machines that could weld were developed.

The oxyacetylene welding-cutting process is a most versatile means of working with metals. No other equipment or process in use by the metal industries is capable of performing such a wide variety of work on most types and thicknesses of metals. Oxyacetylene welding is also the easiest to master and probably the most versatile for the farmer or other do-it-yourself welder. This book is primarily concerned with this type of welding.

The oxyacetylene process can be used for joining, heating, and cut-ting metals. Joining, or fusion, welding is an important application of the oxyacetylene process. Here, the two edges of a metal are heated to their melting points and fused together (Fig. 1.1).


OXYACET YLENE WELDING FUEL S 1 1

Heating with the oxyacetylene process is often used for forming metals into various shapes and heat treating metals in operations such as annealing, flame hardening, tempering, case hardening, and stress relieving (Fig. 1.2).

One last important use of oxyacetylene is to cut metals. In this application, a stream of pure oxygen is directed against an area of heated metal. This action causes the metal to oxidize, or burn, and thus be cut (Fig. 1.3).

It is obvious from the name “oxyacetylene” that this type of weld-ing uses a combination of oxygen and acetylene. To understand these basic components, it may be helpful to discuss these two substances and explain their significance to the welding process.

F I G U R E 1 . 1

Welding is a metalworking process. The joint metal is heated to the melting point and

the pieces are fused together.


1 2 CHAPTER ONE

OxygenOxygen is present in small amounts in the air we breathe. About one-fifth of our atmosphere is oxygen. Oxygen used in the welding process is about as pure as possible—over 99 percent pure. The method used to produce pure oxygen for welding and medical purposes is called the liquid-air process.

Liquid-Air Process

The following is a simplified but adequate description of the liquid-air process. Atmospheric air, as mentioned earlier, consists of about 20 percent pure oxygen, 78 percent nitrogen, and 2 per-cent other gases (by volume). Oxygen and nitrogen have different boiling temperatures. In the liquid-air process, the two gases are

F I G U R E 1 . 2

Welding is often used to heat and shape metals, as is being done to this automobile

fender.



separated by heating atmospheric air to a certain temperature and holding it at this temperature until the nitrogen, which has a boiling point of 295°F, boils off. After the nitrogen has been removed from atmospheric air, oxygen and a small amount of other gases remain. These include carbon dioxide, argon, hydro-gen, neon, and helium. Oxygen has the highest boiling point of all these gases; thus to separate it completely, the remaining mix-ture is further heated until only pure oxygen remains. The pure oxygen is then stored as either a gas or liquid, depending on its eventual use. The liquid-air process is probably the most widely used method of producing pure oxygen.

Cylinders

Oxygen is commonly sold in cylinders in three sizes: 244 cubic feet, 122 cubic feet, and 80 cubic feet (Fig. 1.4). There are very strict

F I G U R E 1 . 3

Metal cutting can be accomplished using welding equipment.


1 4 CHAPTER ONE

requirements for oxygen cylinders. They must be able to withstand over 1 ton of pressure per square inch. The Interstate Commerce Commission (ICC) has set up guidelines for oxygen cylinders. No part of the cylinder may be less than 1/4 inch thick. Each cylinder must be made or forged from a single piece of steel. The steel itself must be armor plate, high-carbon steel (Fig. 1.5).

Since the ICC requires periodic inspec-tion of oxygen cylinders, which are ship-ping containers, very few oxygen cylinders are actually owned by private individuals. Oxygen supply houses, which own and lease oxygen cylinders, are responsible for complying with ICC regulations and inspec-tions. This makes using the gases easier on the consumer.

The widely accepted color for oxygen cylinders, lines, and control knobs is green. However, there is no federal regulation that requires oxygen cylinders to be green; thus, many companies paint their oxygen cylinders a special identifying color. It will be to your advantage to become familiar with the color used by your dealer. Often two oxygen supply houses in the same city will have two different colors for their oxy-gen tanks.

Safety Practices

Oxygen cylinders are not dangerous when used and stored according to generally accepted safety precautions. It is best to use only cylinders carrying ICC markings, however. You can be certain that cylinders

F I G U R E 1 . 4The three most popular sizes of portable oxygen

cylinders, left to right, are 244 cubic feet, 122 cubic

feet, and 80 cubic feet.

Removablemetal cap

Bronze valve

Safety device

Pressed steel neck ring

Oxygen capacity ofcylinder 244 cu. ft. at

2,200 lb. per sq. in.pressure at 70°F.

Airco 244 cubic foot oxygen cylinder

9�O.D 51�

8½�I.D.

F I G U R E 1 . 5

A typical oxygen cylinder.



of this type comply with the stringent reg-ulations of the ICC.

Store cylinders only in a safe location, and fasten them in place. This will ensure that the cylinders cannot be knocked over. Keep tanks in an area away from stoves, radi-ators, furnaces, or other overly warm equip-ment or pipes. Oxygen cylinders should also be kept away from all combustible materials or liquids. If cylinders are stored in the open, they should be protected from water, heat, cold, and the sun’s direct rays.

Never use oxygen cylinders for any purpose other than holding oxygen. You should never use oxygen cylinders as roll-ers to help move large or heavy objects, for example. Nor should you use oxygen cyl-inders as supports.

Oxygen cylinders should be stored and used in an upright position. In most cases, a hand truck specifically designed to hold two cylinders (both oxygen and acetylene) is the best means for storing and using oxygen. The cylinders should be securely chained or strapped to the cart to prevent them from falling over, allowing the tanks to be transported safely (Fig. 1.6).

Never use the valve on top of the cyl-inder to lift the cylinder from a horizontal to a vertical position. The best way to lift a cylinder is to make sure that the valve pro-tection cap is secured tightly. Then raise the cylinder by grasping the cap firmly and lifting (Fig.1.7).

Never allow oxygen cylinders to come in contact with live electrical wires or other electrical equipment.

You can rent oxygen (as well as acetylene) cylinders for a fixed period of time. When you require more oxygen, you simply return the empty cyl-inder to the dealer, who replaces it with a full one. All you pay for is the oxygen. The oxygen itself is what you use. In most parts of the country a 20-year lease is available and quite reasonable. In our case, the cost of a cylinder for oxygen and a cylinder for acetylene costs about $10 a year. You can buy oxygen and acetylene to fill the tanks as you need them. In different parts of the country the price may vary.

F I G U R E 1 . 6

Both oxygen and acetylene tanks should be chained

to prevent their accidental falling.

QUICK>>>TIP


1 6 CHAPTER ONE

Keep cylinders away from welding and cutting work. Make certain that the hoses containing oxygen and acetylene do not lie under the work.

Open cylinder valves all the way when working, and always close cylinder valves when you have completed working. Never leave the cylinder valve open when you are not in the immediate vicinity. Cylinder valves should always be tightly closed when not in use—whether they are empty or full. If you stop working for lunch, for example, turn off the valves and bleed the lines. This procedure is explained later (see Fig.1.8).

Never use oxygen around oil or grease as these substances burn violently in the presence of pure oxygen under pressure. Do not use any oil or grease on the regula-tor fitting.

Never use oxygen for anything other than welding and cutting. Pure oxygen is not in itself flammable, but is an accelerant that can cause intense heat when added to a flame of even very small nature. There is a very real danger if it is used to “dust off” work or clothing. Similarly, oxygen should never be used for ventilation, pressure tests of any kind, or for any other similar purpose.

AcetyleneAcetylene is produced by combining cal-

cium carbide and water. When calcium carbide, commonly called carbide in the trade, is dropped into water, a reaction occurs that causes gas bubbles to rise. The gas is acetylene. It has a peculiar

F I G U R E 1 . 7

Whenever you pick up a cylinder of oxygen or acetylene,

always lift it by the protective cap.

F I G U R E 1 . 8

Always turn off the flow of both oxygen and acetylene

at the tank when you stop work for more than 10

minutes.



odor, and, if lighted, it burns with a black, smoky flame. After the action of the carbide has ceased, a whitish residue remains in the water. This end product is hydrated, or slaked, lime (calcium hydroxide), and it has many uses in the fertilizer industry.

It is interesting, as a side note, to men-tion that old-time miners’ headlamps are called carbide lamps, and they work sim-ply by adding water to carbide pellets. A gas is formed in a special container and is forced out of a jet. This gas is ignited in front of a reflector plate, which throws a bright beam of light (Fig. 1.9).

Carbide-to-Water Generators

Acetylene is produced commercially by basically the same pro-cess as used in a miner’s headlamp, only on a much larger scale. Companies that use great amounts of acetylene will usu-ally have their own generator that supplies them with all of the acetylene they can use. These generators are called carbide-to-water generators, and they are almost totally automated. In these types of generators, small amounts of calcium carbide are fed into a large sealed container of water. The heat given off as the reaction occurs is absorbed by the water. The acetylene gas is captured when it rises to the top of the tank. This gas is then either used directly or stored for future use (Fig. 1.10).

Containers

For the beginner welder, the only practical way to obtain acetylene is in a special tank, which is similar to but much smaller than a standard oxygen cylinder. The three common sizes of acetylene cylinders are 300 cubic feet, 100 cubic feet, and 60 cubic feet. A full tank of acety-lene will register approximately 225 psi (pounds per square inch) on a pressure gauge (Fig. 1.11).

F I G U R E 1 . 9

A miner’s carbide lamp works on the same basic

principle as does an acetylene generator.


1 8 CHAPTER ONE

As with oxygen, the ICC has set up guidelines and regulations for acetylene containers. One ICC regulation is that free acetylene may not be stored at pressures over 15 pounds per square inch. It is not a prob-lem to stay within this amount because all welding and cutting with oxyacetylene can be performed at pressures of less than 15 psi.

To store acetylene below the 15-psi requirement, special tanks have been developed. A tank made of heavy-gauge steel is packed with a porous substance such as pith from cornstalks, fuller’s earth, lime silica, or other materials. Next, the tank is filled with acetone, a liquid chemical that can absorb about 25 times its own volume of acetylene. When the

Control valve

Calciumcarbide

(granules)

Water filler

Valve

DrainCalcium chloride

Agitator lever

Acetylene gas(bubbles)

Water

Acetylene gasthrough water

Water filler

Acetylene gas

Reliefvalve

Calciumcarbide

F I G U R E 1 . 1 0

A cutaway view of an acetylene generator.



cylinder is filled to about 225 psi with acety-lene, the acetone dissolves the acetylene and makes it safe because the acetylene is not free (Fig. 1.12).

Acetylene cylinders have a valve on top to which the regulator is attached. This valve is similar to the valve on oxygen cylinders except that it has left-handed threads. You must turn the valve counterclockwise to open it and clockwise to close it. This turn-ing action is the opposite of a standard control valve.

All acetylene tanks have safety plugs on the top or bottom of the cylinder. These plugs are designed to melt, in the event of a fire, at around 212°F. Needless to say, the cylinders should be stored and used away from any heat source. Once these safety plugs melt, all of the acetylene and ace-tone in the cylinder is allowed to escape (Fig. 1.14).

Precautions

As with oxygen cylinders, there are a few general safety precautions that should always be followed. These include the fol-lowing guidelines for safe operation and storage of acetylene.

Always call acetylene by its proper name: “acetylene.” It should never be called “gas” as it is very different from the type of gas used in a kitchen, furnace, or automobile.

Acetylene should be stored away from all heat sources and other fuels. An ideal storage location is a cool, dry area away from all combustible materials.

F I G U R E 1 . 1 1

The three most popular sizes of portable acetylene

cylinders, left to right, are 300 cubic feet, 100 cubic

feet, and 60 cubic feet. Cylinders of other shapes are

also available.

Filler

F I G U R E 1 . 1 2

A cutaway view of a typical acetylene cylinder showing

the filler material.

Note that all acetylene connections on the cylinder, hoses, and torch handle are left-handed. Each brass fitting has a groove cut around its circumference for quick identification (Fig. 1.13).

QUICK>>>TIP


2 0 CHAPTER ONE

Handle acetylene cylinders with special care. The safety plugs melt at about the same temperature as boiling water, and they can “blow out” as a result of rough handling. As with oxygen, cylinders of acety-lene should be secured while being used to eliminate the possibility of the cylinder falling over. A specially designed hand truck is the best way of moving and storing acetylene and oxygen.

Do not open the valve on an acetylene cylinder more than 11⁄2 turns as this may cause some of the acetone in the tank to escape with the acetylene. Acetone will damage all rubber and plastic parts in the system, including the hose and regula-tor. Therefore, it should not be allowed to escape.

Always use an acetylene cylinder in an upright position. Never use it when the cylinder is in any position other than vertical.

Review Questions

1. What is the oldest type of welding?

2. How hot is the oxyacetylene flame?

3. Who was the French chemist who discovered acetylene welding?

4. What type of welding was used in World War I?

5. Oxyacetylene is also used to __________ metals.

6. How pure is the oxygen used in welding?

7. What is the name of the process used to purify oxygen?

8. Pure oxygen can be stored as a gas or __________.

9. What are the three sizes of oxygen cylinders?

10. Which government agency regulates oxygen cylinders?

Nut

F I G U R E 1 . 1 3

A fitting for an acetylene regulator. Notice that the

nut has grooves around the middle. All left-handed-

threaded fittings have these grooves.



11. Oxygen cylinders should always be kept away from __________ __________ or __________.

12. Both oxygen and acetylene tanks should be __________ to keep them from accidentally falling.

13. Acetylene is produced by using water and __________.

14. What are the three sizes of acetylene cylinders?

15. Which type of welding tank has a regulator with left-handed threads?

16. At what temperature does the acetylene cylinder plug melt?

Safety plug

F I G U R E 1 . 1 4

The safety plug on an acetylene cylinder is specially

designed to melt at temperatures in excess of 212°F.



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Oxyacetylene Welding Fuels - Professional Welding Fuels ... 002-Geary-Chap01.indd 92-Geary-Chap01.indd 9 33/3/2011 5:27:57 ... metals into various shapes and heat treating metals in