Oxy-Fuel Gas Cylinders and Equipment Section 5-6 Flashcards by Unknown Unknown

What is the main job of a gas pressure regulator?

a. To make the gas pressure higher
b. To control the torch’s temperature
c. To slow down the gas flow
d. To lower the strong cylinder pressure to the right pressure for the torch

d. To lower the strong cylinder pressure to the right pressure for the torch

A gas pressure regulator is like a control valve for gas. Its main job is to take the high pressure from a gas cylinder and reduce it to a safe and usable pressure for whatever one’s using the gas for, like a torch or a burner. It makes sure that the pressure of the gas coming out is just right for the equipment being used.

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Oxygen has _______ pressure setting compared to acetylene.

a. The same
b. A higher
c. A lower
d. About the same

b. A higher

Oxygen has a higher pressure setting compared to acetylene.

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A recommended operating pressure for the cutting torch falls within the range of:

a. 140 kPa (20 psi) for oxygen and 100 kPa (15 psi) for acetylene
b. 240 kPa (35 psi) for oxygen and 200 kPa (30 psi) for acetylene
c. 275 kPa (40 psi) for oxygen and 69 kPa (10 psi) for acetylene
d. 400 kPa (60 psi) for oxygen and 138 kPa (20 psi) for acetylene

c. 275 kPa (40 psi) for oxygen and 69 kPa (10 psi) for acetylene

The oxygen CYLINDER pressure is typically in the range of 15 MPa (2,200 psi)

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Which device is installed at the cylinder valves for oxygen, acetylene, or other gases to decrease the cylinder pressure to a suitable working pressure at the torch tip?

a. Flow meters
b. Safety valves
c. Pressure regulators
d. Hose connectors

c. Pressure regulators

A pressure regulator is a device that controls the pressure of a gas coming from a high-pressure source, like a cylinder, and lowers it to a safe and consistent level for use. It’s like a valve that adjusts the flow of gas to ensure it’s just right for whatever you’re using it for, like welding or cooking.

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Which of the following is typically used to identify pressure regulators?

a. The colour of the casing
b. The manufacturer’s logo
c. The type of gas for which they are used
d. The size of the pressure gauge

c. The type of gas for which they are used

For example, an oxygen pressure regulator body will have “oxygen” printed on it and will usually be green in colour.

An acetylene pressure regulator body will have “acetylene” printed on it and will usually be red in colour.

Although exact identification and other features vary with different manufacturers,

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Which components make up a pressure regulator?

a. A nozzle, rigid diaphragm, and gears.
b. A cylinder, piston, and levers.
c. A seat, flexible diaphragm, and springs.
d. A valve, gearbox, and bearings.

c. A seat, flexible diaphragm, and springs.

The “seat” is like a tight seal or a stopper where the gas flow is controlled. It’s a fixed part against which the flexible diaphragm presses to regulate the gas pressure.

A “diaphragm” is like a thin, stretchy membrane that moves to control the flow of gas. It acts like a barrier between high-pressure and low-pressure areas, flexing to adjust the gas flow and keep it at the right level.

The “springs” are like little coils that help control the pressure. They push against the diaphragm to keep the pressure steady and just right for what you’re using the gas for.

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What is the range of pressure typically displayed on oxygen cylinder pressure regulator gauges?

a. 0-20,000 kPa (0-2,900 psi)
b. 0-30,000 kPa (0-4,350 psi)
c. 0-25,000 kPa (0-3,625 psi)
d. 0-27,500 kPa (0-4,000 psi)

d. 0-27,500 kPa (0-4000 psi)

This gauge tells you how much gas is left in the cylinder before you start using it.

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Which of the following best describes the range of a working pressure gauge for oxygen?

a. 0-100 kPa (0-15 psi)
b. 0-300 kPa (0-45 psi)
c. 0-200 kPa (0-30 psi)
d. 0-400 kPa (0-60 psi)

c. 0-200 kPa (0-30 psi)

This gauge shows you the pressure of the gas coming out of the cylinder and going into your equipment.

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What is the typical pressure range shown on acetylene cylinder pressure regulator gauges?

a. 0-5 MPa (0-725 psi)
b. 0-3.5 MPa (0-500 psi)
c. 0-2.7 MPa (0-400 psi)
d. 0-1.5 MPa (0-225 psi)

c. 0-2.7 MPa (0-400 psi)

AKA 0-2700 kPa (0-400 psi)

This gauge tells you how much gas is left in the cylinder before you start using it.

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Which of the following best describes the range of a working pressure gauge for acetylene?

a. 0-100 kPa (0-15 psi)
b. 0-150 kPa (0-22 psi)
c. 0-200 kPa (0-30 psi)
d. 0-250 kPa (0-36 psi)

c. 0-200 kPa (0-30 psi)

Although acetylene working pressure must be kept below 103 kPa (15 psi)

This gauge shows you the pressure of the gas coming out of the cylinder and going into your equipment.

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Which of the following statements accurately describes the recommended working pressure for acetylene?

a. The acetylene working pressure should exceed 100 kPa (14.5 psi).
b. The acetylene working pressure should be precisely 130 kPa (19 psi).
c. The acetylene working pressure must be kept below 103 kPa (15 psi).
d. The acetylene working pressure is irrelevant for safe usage.

c. The acetylene working pressure must be kept below 103 kPa (15 psi).

This is to prevent the unstable acetylene gas from exploding.

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Which feature distinguishes the hex nut on an acetylene pressure regulator from that on an oxygen pressure regulator?

a. The acetylene hex nut is larger in size.
b. The acetylene hex nut is smooth.
c. The acetylene hex nut is grooved.
d. The acetylene hex nut is painted red.

c. The acetylene hex nut is grooved.

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Which feature distinguishes the hex nut on an oxygen pressure regulator from that on an acetylene pressure regulator?

a. The oxygen hex nut is larger in size.
b. The oxygen hex nut is grooved.
c. The oxygen hex nut is painted blue.
d. The oxygen hex nut is smooth.

d. The oxygen hex nut is smooth.

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Which statement accurately describes the threading of connections for gas pressure regulators?

a. Both oxygen and fuel gas pressure regulators have right-hand threads.
b. Both oxygen and fuel gas pressure regulators have left-hand threads.
c. The connections of oxygen pressure regulators have right-hand threads, while fuel gas pressure regulators have left-hand threads.
d. The connections of oxygen pressure regulators have left-hand threads, while fuel gas pressure regulators have right-hand threads.

c. The connections of oxygen pressure regulators have right-hand threads, while fuel gas pressure regulators have left-hand threads.

This makes it impossible to connect a pressure regulator or hoses to the wrong cylinder.

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Which classification system is used to categorize gas cylinder pressure regulators based on the number of pressure regulation steps?

a. Primary and Secondary regulators
b. Low and High-pressure regulators
c. Single-stage and Two-stage regulators
d. Initial and Final regulators

c. Single-stage and Two-stage regulators

Gas cylinder pressure regulators are categorized based on how many steps they use to control the pressure of the gas.

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Which type of regulator typically provides a more stable and smooth working pressure for high pressure cylinders?

a. Single-stage regulator
b. Two-stage regulator
c. Both types provide equally stable working pressure
d. None of the above

b. Two-stage regulator

a two-stage regulator provides a more stable and smooth working pressure because it reduces the pressure in two steps instead of just one. This means it can handle variations in pressure from the cylinder better, giving you a steadier flow of gas for your work.

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Which of the following statements accurately describes the characteristics of a single-stage pressure regulator?

a. It provides finer control over pressure compared to two-stage regulators.
b. It is typically used with individual cylinders.
c. It is more expensive and complex in construction than a two-stage regulator.
d. Working pressure tends to drift downward as the cylinder pressure diminishes, requiring periodic adjustments.

d. Working pressure tends to drift downward as the cylinder pressure diminishes, requiring periodic adjustments.

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What distinguishes a single-stage pressure regulator from a two-stage regulator?

a. Single-stage regulators are more commonly used in industrial applications.
b. Two-stage regulators are typically used with individual cylinders.
c. Single-stage regulators provide more precise control over pressure.
d. Two-stage regulators maintain a more constant working pressure as cylinder pressure decreases.

d. Two-stage regulators maintain a more constant working pressure as cylinder pressure decreases.

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Which type of system is a single-stage pressure regulator typically used with?

a. Bulk system or manifold system
b. Individual cylinder
c. High-pressure system
d. Low-pressure system

a. Bulk system or manifold system

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What are the characteristics of a single-stage pressure regulator?

a. It provides finer control over pressure compared to two-stage regulators.
b. It is typically used with individual cylinders.
c. It is less expensive and simpler in construction than two-stage regulators.
d. It maintains constant working pressure regardless of cylinder pressure.

c. It is less expensive and simpler in construction than two-stage regulators.

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How does the control over pressure of a single-stage regulator compare to that of a two-stage regulator?
a. It provides more precise control.
b. It provides less precise control.
c. It provides equal control.
d. It provides no control over pressure.

b. It provides less precise control

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Which type of regulator provides more precise regulation over a wide range of varying inlet pressures?

a. Single-stage pressure regulator
b. Double-stage pressure regulator
c. Three-stage pressure regulator
d. Variable-stage pressure regulator

b. Double-stage pressure regulator

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Which type of pressure regulator is utilized when the cylinder pressure is reduced to working pressure in two steps?

a. Single-stage pressure regulator
b. Multi-stage pressure regulator
c. Dual-action pressure regulator
d. Two-stage pressure regulator

d. Two-stage pressure regulator

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What is the primary function of the first stage in a two-stage pressure regulator?

a. To maintain the cylinder pressure at its maximum level
b. To reduce the gas pressure to a safe level for immediate use
c. To decrease the gas pressure to intermediate levels
d. To regulate the gas flow to the desired rate

c. To decrease the gas pressure to intermediate levels

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What pressure range does the first stage of a two-stage pressure regulator typically drop the cylinder pressure to? a. Less than 100 kPa (15 psi) b. Between 500 and 800 kPa (75 and 115 psi) c. Between 1,200 and 2,800 kPa (180 and 400 psi) d. More than 5,000 kPa (725 psi)

c. Between 1,200 and 2,800 kPa (180 and 400 psi)

Which function does the second stage perform in a two-stage pressure regulator? a. It increases the intermediate pressure. b. It maintains the intermediate pressure constant. c. It reduces the intermediate pressure to the desired working pressure. d. It switches between different working pressures.

c. It reduces the intermediate pressure to the desired working pressure.

Why are two-stage cylinder pressure regulators preferred over single-stage regulators? a. They are cheaper. b. They have a simpler design. c. They deliver a more constant pressure with finer control. d. They require less maintenance.

c. They deliver a more constant pressure with finer control.

What happens to the gas flow rate in single-stage cylinder pressure regulators as the cylinder pressure drops? a. It increases. b. It decreases. c. It remains constant. d. It fluctuates unpredictably.

d. It fluctuates unpredictably.

Why are two-stage cylinder pressure regulators recommended for precise cutting jobs? a. They are cheaper than single-stage regulators. b. They require frequent readjustment. c. They offer more stable gas flow. d. They are easier to install.

c. They offer more stable gas flow.

In which types of cutting operations are two-stage pressure regulators commonly used? a. Only in manual cutting operations. b. Only in automatic cutting operations. c. Only in machine cutting operations. d. In both automatic and machine cutting operations

d. In both automatic and machine cutting operations

Why are two-stage pressure regulators more common in automatic and machine cutting applications? a. They are less precise compared to single-stage regulators. b. They are easier to operate manually. c. They can handle higher gas pressures. d. They provide finer control, which is crucial for automated processes.

d. They provide finer control, which is crucial for automated processes.

Which type of pressure regulator is recommended for accurate cutting and welding operations? a. Single-stage pressure regulators b. Two-stage pressure regulators c. Variable pressure regulators d. Fixed pressure regulators

b. Two-stage pressure regulators

What precaution should be taken with the pressure-adjusting screw in cylinder pressure regulators? a. Tighten it firmly before opening the cylinder valve. b. Keep it at the maximum setting to ensure proper gas flow. c. Back it out until it moves freely before opening the cylinder valve. d. Leave it untouched, as it does not affect the gas flow.

c. Back it out until it moves freely before opening the cylinder valve.

Why is it important to back out the pressure-adjusting screw in cylinder pressure regulators? a. To increase the gas flow rate. b. To prevent damage to the regulator mechanism. c. To decrease the gas pressure in the cylinder. d. To make it easier to open the cylinder valve.

b. To prevent damage to the regulator mechanism.

What risk is associated with allowing a sudden surge of cylinder gas into the pressure regulator? a. Decreased gas pressure at the torch tip. b. Damage to the cylinder valve. c. Potential damage to the regulator mechanism. d. Improved performance of the pressure regulator.

c. Potential damage to the regulator mechanism.

What is the potential consequence of a damaged pressure regulator due to a sudden surge of cylinder gas? a. Reduced gas consumption. b. Increased safety during operation. c. Risk of personal injury. d. Enhanced gas flow control.

c. Risk of personal injury.

What should you check for after attaching hoses and a torch to cylinder pressure regulators? a. The colour of the hoses b. The length of the hoses c. An increase or "creep" in the working-pressure gauge d. The temperature of the regulator

c. An increase or "creep" in the working-pressure gauge

What is the possible cause of an increase or "creep" in the working-pressure gauge after attaching hoses and a torch to cylinder pressure regulators? a. Faulty torch valves b. Loose hose connections c. Faulty seat valve in the regulator d. Insufficient gas pressure

c. Faulty seat valve in the regulator

What action should be taken if there is an increase or "creep" in the working-pressure gauge after attaching hoses and a torch to cylinder pressure regulators? a. Continue using the equipment as usual b. Tighten the hose connections c. Adjust the torch valves d. Repair the faulty seat valve in the regulator before further use

d. Repair the faulty seat valve in the regulator before further use

What is the recommended precaution when connecting a pressure regulator to a gas cylinder? a. Use pliers or a pipe wrench to tighten connections. b. Always check for the correct pressure regulator before connecting. c. Force connections if they don't fit properly. d. Connect the regulator without using a cylinder wrench.

b. Always check for the correct pressure regulator before connecting.

Why is it important to verify the correct pressure regulator before connecting it to a gas cylinder? a. To save time during the connection process. b. To ensure proper functionality and safety. c. To increase gas pressure. d. To avoid using a cylinder wrench.

b. To ensure proper functionality and safety.

What tool should be used to tighten connections when attaching a pressure regulator to a gas cylinder? a. Pliers b. Pipe wrench c. Cylinder wrench d. Screwdriver

c. Cylinder wrench

What should you avoid using on the connections of cylinder pressure regulators? a. Grease b. Oil-based pipe compound c. Teflon tape d. All of the above

d. All of the above

Who should repair pressure regulators according to safety guidelines? a. Any experienced individual b. Any individual with basic mechanical skills c. A trained technician d. The user themselves

c. A trained technician

What should you never attempt to do with a faulty pressure regulator? a. Label it as faulty b. Place it in an area where it will not be used c. Repair it d. Order a replacement

c. Repair it

What precaution should be taken when handling cylinder pressure regulators? a. Drop them gently to ensure they are securely in place. b. Misuse them to test their durability. c. Handle them with care and never drop or misuse them. d. Handle them loosely to avoid crushing them.

c. Handle them with care and never drop or misuse them.

Why is it important to handle cylinder pressure regulators with care? a. To test their durability. b. To ensure they are securely in place. c. They have precise internal mechanisms. d. None of the above.

c. They have precise internal mechanisms.

What action should be taken when transporting or removing pressure regulators from service? a. Turn the working pre-adjusting screw as much as possible. b. Leave the pressure regulators as they are. c. Turn the working pre-adjusting screw just enough to take the pressure off the inlet seat valves. d. Completely disassemble the pressure regulators for transportation.

c. Turn the working pre-adjusting screw just enough to take the pressure off the inlet seat valves.

What is the purpose of turning the working pre-adjusting screw when transporting or removing pressure regulators from service? a. To increase pressure on the inlet seat valves. b. To ensure the pressure regulators are tightly secured. c. To prevent sticking and corrosion of the seat. d. None of the above.

c. To prevent sticking and corrosion of the seat.

Which statement accurately describes the threading of Compressed Gas Association (CGA) fittings on cylinder pressure regulators? a. CGA fittings always have right-hand threads. b. CGA fittings always have left-hand threads. c. CGA fittings can have either right-hand or left-hand threads. d. CGA fittings have reverse threads compared to standard fittings.

c. CGA fittings can have either right-hand or left-hand threads.

What precaution should be taken when replacing fittings on a cylinder pressure regulator? a. Use any available fitting for replacement. b. Tighten the fitting as much as possible. c. Always use an exact replacement fitting. d. Only use fittings with left-hand threads.

c. Always use an exact replacement fitting.

What is the consequence of replacing a CGA 580 fitting with a CGA 680 fitting on a regulator? a. It will not affect the regulator's performance. b. It will decrease the pressure in the regulator. c. It will over-pressurize the regulator. d. It will cause the regulator to leak gas.

c. It will over-pressurize the regulator. This can cause serious injury and damage.

What is a crucial requirement for hoses used in cylinder pressure regulators? a. Rigidity for stability b. Stiffness for less risk of mobility c. Flexibility for mobility and manipulation

c. Flexibility for mobility and manipulation

Why must hoses used in cylinder pressure regulators be able to withstand high line pressures? a. To minimize gas leakage b. To increase gas flow rate c. To reduce equipment weight d. To enhance portability

a. To minimize gas leakage

What utility and safety requirements must hoses for cylinder pressure regulators meet? a. They must be resistant to extreme temperatures b. They must be able to conduct electricity c. They must be flexible and durable d. They must be transparent for visual inspection

c. They must be flexible and durable

What is the structure of the hoses used in cylinder pressure regulators for fuel gases and oxygen? a. Single-layer rubber with fabric reinforcement b. Two or three rubber layers, each separated by a layer of strong fabric c. Three rubber layers without any fabric reinforcement d. A single rubber layer without any fabric reinforcement

b. Two or three rubber layers, each separated by a layer of strong fabric

What colour is typically used for the oxygen hose in cylinder pressure regulators? a. Red or Yellow b. Green or Black c. Black or Blue d. Blue or Red

b. Green or Black

Which color is commonly assigned to the fuel gas (acetylene) hose in cylinder pressure regulators? a. Yellow b. Black c. Green d. Red

d. Red

Why are hoses for cylinder pressure regulators reinforced with two layers? a. To increase flexibility b. To decrease durability c. To avoid kinking and wear d. To simplify maintenance

c. To avoid kinking and wear

What is the purpose of the outside layer of rubber in most oxy-fuel gas hoses? a. To reduce flexibility b. To increase tangling c. To prevent tangling d. To decrease durability

c. To prevent tangling

What factor determines the sizing of oxy-fuel hoses in cylinder pressure regulators? a. The length of the hose b. The outside diameter of the hose c. The inside diameter of the inner tube d. The material of the hose

c. The inside diameter of the inner tube

Which of the following is the most common size for oxy-fuel hoses used in light-duty cutting and welding? a. 4.0 mm b. 5mm c. 6.4 mm d. 8mm

b. 5mm (3/16 in)

Why is a large-diameter hose recommended for cutting thick material? a. To decrease gas flow b. To increase gas pressure c. To deliver the required oxygen and fuel-gas d. To improve maneuverability

c. To deliver the required oxygen and fuel-gas

What is the recommended solution for overcoming greater pressure drops in long lengths of hose connected to cylinder pressure regulators? a. Increasing the gas flow rate b. Using a higher regulator pressure c. Decreasing the diameter of the hose d. Using a longer hose

b. Using a higher regulator pressure

Why is a larger diameter hose recommended for delivering gas from cylinder pressure regulators to the torch? a. To reduce the gas flow rate b. To increase pressure drops c. To decrease the volume of gas delivered d. To overcome greater pressure drops and deliver more volume

d. To overcome greater pressure drops and deliver more volume

What should be checked regarding hose size when using cylinder pressure regulators? a. Shops supervisors' recommended torch size b. The gas flow rate through the hose c. The manufacturer's oxy-fuel gas hose size d. The pressure rating of the hose material

c. The manufacturer's oxy-fuel gas hose size

Why are shorter hose lengths recommended for safety reasons when using cylinder pressure regulators? a. To reduce the risk of gas leaks b. To increase the pressure drop c. To decrease gas flow rate d. To improve the efficiency of the torch operation

a. To reduce the risk of gas leaks

Which grade of oxy-fuel gas hose is suitable for use with liquid fuel gases? a. Grade T b. Grade R c. Grade G d. Grade L

a. Grade T

Which grade of oxy-fuel gas hose is specifically designed for use with acetylene? a. Grade T b. Grade R c. Grade A d. Grade G

b. Grade R

+True or False. Grade R oxy-fuel gas hoses are suitable for acetylene. a. True b. False

a. True

Which grade of oxy-fuel gas hose is versatile and can be used with all fuel gases, including acetylene? a. Grade T b. Grade R c. Grade F d. Grade G

a. Grade T

What precautions should be taken to prevent fires or explosions related to oxy-fuel gas hoses? a. Ensuring hoses are coiled and supported b. Cleaning hoses with oil and grease c. Storing hoses in dry direct sunlight d. Securing puncture holes with grade A tape

a. Ensuring hoses are coiled and supported

What should be done with damaged oxy-fuel gas hoses? a. Keep using them if the damage is minor. b. Replace or repair them. c. Wrap them with tape for temporary fixes. d. Ignore the damage if it's on the exterior.

b. Replace or repair them.

Why should oxy-fuel gas hoses be purged before use and after every cylinder change? a. To increase the flexibility of the hoses. b. To decrease the risk of kinking. c. To prevent dirt or debris from clogging the torch passages. d. To remove excess smell from gas.

c. To prevent dirt or debris from clogging the torch passages.

What type of air should be used when blowing out hoses? a. Air with oil content. b. Oil-less compressed air. c. Air mixed with gasoline. d. Air from a regular compressor.

b. Oil-less compressed air.

What should never be used for repairs on oxy-fuel gas hoses? a. Tape. b. Welding tacks. c. Glue. d. All of the above

d. All of the above

Which material is used to make fittings and connectors for oxy-fuel hoses, regulators, and torch bodies? a. Steel b. Aluminum c. Brass alloys d. Copper

c. Brass alloys

True or False. Brass alloys are preferred for making fittings and connectors because they do not corrode or create dangerous by-products when exposed to oxy-fuel gases and do not generate sparks if they contact other metals or materials. a. True b. False

a. True

What is the purpose of using yellow brass fittings for oxy-fuel gas hoses? a. To increase flexibility b. To reduce weight c. To avoid generating sparks d. To enhance gas flow

c. To avoid generating sparks

How can you identify the threading on acetylene hose fittings? a. By the colour of the hose b. By the presence of a groove cut into the fitting c. By the material used for the fitting d. By the size of the fitting

b. By the presence of a groove cut into the fitting

Why are acetylene fittings distinctly different from oxygen fittings? a. To prevent gas leaks b. To enhance compatibility c. To facilitate interchangeability d. To prevent accidental interchange

d. To prevent accidental interchange

Which materials are recommended for use in acetylene gas systems? a. Copper or red brass b. Aluminium or plastic c. Yellow brass, iron, or steel d. Titanium or ceramic

c. Yellow brass, iron, or steel

Why are copper or red brass fittings not recommended for acetylene hose fittings? a. They are too expensive. b. They are prone to corrosion. c. They can react with acetylene to form a dangerous residue. d. They do not provide a secure connection.

c. They can react with acetylene to form a dangerous residue (Acetylide).

What precaution should be taken before using fittings on oxy-fuel gas hoses? a. They should be cleaned with water. b. They should be lubricated with oil. c. They should be firmly secured. d. They should be heated to a certain temperature.

c. They should be firmly secured.

What is a backfire in oxy-acetylene equipment? a. A momentary recession of the flame into the torch tip or mixer. b. A steady flame burning from the torch tip. c. A complete extinguishment of the flame without any sound. d. A continuous flame that does not recede or make any noise.

a. A momentary recession of the flame into the torch tip or mixer, followed by a loud popping sound.

What sound may indicate that the flame has reignited after a backfire? a. A loud popping sound. b. A squealing sound. c. A hissing sound. d. A crackling sound.

b. A squealing sound.

What action should be taken if a backfire occurs in oxy-acetylene equipment? a. Immediately relight the torch. b. Close the oxygen and fuel gas valves immediately to check the equipment. c. Ignore it and continue working. d. Increase the gas flow to prevent further backfires.

b. Close the oxygen and fuel gas valves immediately to check the equipment.

When is a backfire most commonly likely to occur in oxy-acetylene equipment? a. When working with cold metal. b. When adjusting the gas flow. c. When the torch tip touches hot metal. d. When the equipment is not properly cleaned.

c. When the torch tip touches hot metal.

What should be done if backfires continue to occur despite cleaning and purging the equipment? a. Increase the gas flow. b. Replace the torch tip. c. Remove the torch from service for cleaning and possible repair. d. Ignore it and continue working.

c. Remove the torch from service for cleaning and possible repair.

What is a flashback in oxy-fuel torch lines? a. An unexpected increase in gas pressure b. A sudden ignition of the gas mixture within the torch or hoses c. A decrease in flame temperature d. A decrease in gas flow rate

b. A sudden ignition of the gas mixture within the torch or hoses

What can cause a flashback when using oxy-fuel torch lines? a. Insufficient gas pressure b. Excessive gas flow rate c. Presence of contaminants in the gas lines d. All of the above

d. All of the above

What are the potential aftereffects of a flashback? a. Damage to the torch tip b. Damage to the hoses c. Both a and b d. None of the above

c. Both a and b

At what temperature does the burning speed of the gas mixture increase dramatically during a flashback? a. 150°C b. 190°C c. 220°C d. 250°C

c. 220°C

At approximately what temperature can spontaneous ignition and burning of the gas mixture within the tip occur? a. 220°C b. 250°C c. 280°C d. 315°C

d. 315°C

What temperature must the torch tip be kept below to prevent spontaneous ignition of the gas mixture within the tip? a. 150°C b. 190°C c. 220°C d. 250°C

b. 190°C

What is the primary function of flashback arrestors in oxy-fuel torch lines? a. To increase the flow rate of gas b. To regulate the temperature of the flame c. To extinguish flames d. To create a spark in the torch line

c. To extinguish flames

In addition to extinguishing flames, what other function do flashback arrestors serve? a. They increase the pressure of the gas b. They regulate the oxygen-to-fuel ratio c. They prevent the backflow of gas d. They cool down the torch line

c. They prevent the backflow of gas

What happens if certain temperatures and/or pressures are exceeded in a flashback arrestor? a. The gas flow is increased b. The flashback arrestor shuts off the gas flow c. The flashback arrestor ignites d. The flashback arrestor expands

b. The flashback arrestor shuts off the gas flow

How are flashback arrestors typically marked to indicate the direction of gas flow? a. With a circle b. With a square c. With an arrow d. With a triangle

c. With an arrow

Where can flashback arrestors be installed in oxy-fuel torch lines? a. Only at the torch b. Only at the regulators c. Both at the torch and regulators d. None of the above

c. Both at the torch and regulators

What is the primary function of a torch-mounted flashback arrestor? a. To protect the regulator b. To prevent flashback from entering the hose c. To stop the flow of gas d. To extinguish flames on the torch tip

b. To prevent flashback from entering the hose

What is the purpose of a regulator-mounted flashback arrestor? a. To protect the torch b. To prevent flashback from going further back to the acetylene bottle c. To stop the flow of oxygen d. To extinguish flames on the regulator

b. To prevent flashback from going further back to the acetylene bottle

Why won't a reverse-flow check valve stop a flashback? a. Because it is not designed for gas flow direction b. Because it is ineffective in high-pressure systems c. Because it does not extinguish flames d. Because it cannot prevent gas from flowing backwards

d. Because it cannot prevent gas from flowing backwards

What is the primary function of a reverse flow valve in oxy-fuel torch lines? a. To increase the flow rate of gases b. To regulate the temperature of the torch flame c. To prevent the backflow of gases into the hoses d. To adjust the pressure of the gases

c. To prevent the backflow of gases into the hoses

How does a reverse flow valve function in oxy-fuel torch lines? a. By allowing the gases to flow in one direction only b. By mixing oxygen and fuel gases to create a combustible mixture c. By controlling the speed of the gas flow d. By shutting off the gas supply in case of an emergency

a. By allowing the gases to flow in one direction only

What is he typical life expectancy of a reverse flow check valve? a. 4 months b. 8 months c. 16 months d. 18 months

18. months

Cylinder pressure regulators have how many gauges? a. 1 b. 2 c. 3 d. 4

c. 2

What position should the pressure regulator adjusting knob be set at prior to opening the cylinder valve? a. Backed out all the way. b. Threaded in all the way. c. Threaded in 1-1.5 turns. d. Threaded halfway.

a. Backed out all the way.

What should you shut down first in the event of a flashback? a. Acetylene cylinder valve. b. Acetylene valve (torch). c. Oxygen cylinder valve. d. Oxygen valve (torch).

d. Oxygen valve (torch).

What should you shut down first in the event of a backfire? a. Acetylene cylinder valve. b. Acetylene valve (torch). c. Oxygen cylinder valve. d. Oxygen valve (torch).

b. Acetylene valve (torch).

Oxy-Fuel Gas Cylinders and Equipment Section 5-6 Flashcards

To Remember (110 cards)