How to Choose Assist Gas for a Fiber Laser Cutting Machine
As an engineer, I do not look at the gas system of a fiber laser cutting machine as a simple question of “oxygen, nitrogen, or compressed air.”
A correct gas selection should follow a complete technical chain:
Gas type → Pressure → Flow rate → Purity → Valve group control → Pipeline pressure rating → Alarm protection → Operating cost
If one part of this chain is wrong, the cutting result may become unstable, even if the laser source, cutting head, and CNC system are all good.
This guide explains how to choose assist gas for fiber laser cutting, how oxygen, nitrogen, and compressed air are used, how to understand gas pressure, how the valve group works, what high-pressure and low-pressure alarms mean, when to use an air compressor, when to use a nitrogen generator, and how to select gas pipelines safely.
Why Assist Gas Is Needed in Fiber Laser Cutting
During fiber laser cutting, the laser beam melts or vaporizes the material locally. The assist gas blows the molten metal out of the cutting kerf, cools the cutting area, and helps control the chemical reaction around the cutting edge.
In simple terms:
| Function | Role |
|---|---|
| Laser beam | Provides the heat source |
| Assist gas | Removes molten metal, protects the edge, and controls oxidation |
| Cutting head and nozzle | Focus the laser beam and guide the gas flow |
| CNC system | Controls cutting path, gas pressure, piercing, and cutting parameters |
Assist gas directly affects:
Cutting speed
Cutting edge color
Burrs and dross
Cutting stability
Piercing quality
Oxidation layer
Protective lens life
Welding, painting, or powder coating after cutting
Total operating cost
So when we choose a gas system, we are not only choosing a gas. We are choosing the cutting quality, operating cost, and long-term stability of the machine.
Oxygen, Nitrogen, and Compressed Air
The three most common assist gases for fiber laser cutting are:
| Gas | Main Use | Main Advantage | Main Limitation |
|---|---|---|---|
| Oxygen | Carbon steel, especially medium and thick plates | Helps cutting through oxidation reaction | Oxidized and darker cutting edge |
| Nitrogen | Stainless steel, aluminum, high-quality cutting | Bright, clean, oxidation-free edge | Higher gas cost and higher pressure demand |
| Compressed Air | General thin sheet cutting | Lowest operating cost | Edge quality is usually lower than nitrogen |
Oxygen
Oxygen is mainly used for cutting carbon steel.
When oxygen contacts hot carbon steel during cutting, it reacts with the metal and produces additional heat. This oxidation reaction helps the laser cut thicker carbon steel more easily.
Oxygen is suitable for:
Carbon steel
Medium and thick carbon steel plates
Parts where a black or oxidized edge is acceptable
Parts that will be ground, sandblasted, painted, or further processed
Advantages of oxygen:
Strong cutting ability for thick carbon steel
Relatively low gas cost
Lower laser power requirement in some thick carbon steel applications
Good for customers who focus on thick carbon steel cutting capacity
Disadvantages of oxygen:
The cutting edge becomes oxidized
The edge color is usually darker
Not suitable for stainless steel when a bright edge is required
Thin sheet cutting speed may be lower than high-pressure nitrogen cutting
Oxygen pipelines and valves must be clean, oil-free, and oxygen-compatible
From an engineering point of view, oxygen is a good choice when the customer mainly cuts carbon steel and accepts an oxidized cutting edge. But if the customer requires a bright, clean, oxidation-free edge, oxygen is not the right gas.
Nitrogen
Nitrogen is an inert gas. It does not support combustion like oxygen. Its main job is to prevent oxidation and blow molten metal out of the cutting kerf.
Nitrogen is suitable for:
Stainless steel
Aluminum
Brass and copper
Galvanized sheet
Carbon steel that requires an oxidation-free edge
Parts that need welding, powder coating, electroplating, or high-quality surface treatment after cutting
Advantages of nitrogen:
Bright cutting edge
No obvious oxidation layer
Better edge quality
Less burr in many applications
Good for stainless steel and aluminum
Suitable for high-end sheet metal parts
Disadvantages of nitrogen:
Higher gas consumption
Higher operating cost
Thick plate cutting needs higher pressure and higher flow rate
Higher requirements for gas pipelines, valves, regulators, and gas supply stability
From an engineering point of view, nitrogen is usually the first choice for stainless steel and aluminum when the customer needs a clean and bright cutting edge.
For carbon steel, nitrogen can also be used if the customer requires an oxidation-free edge, but the operating cost will be higher.
Compressed Air
Compressed air is a mixed gas. It contains mainly nitrogen and oxygen. Because it contains oxygen, it can still create some oxidation during cutting. Because it also contains nitrogen, it can provide some protective effect.
Compressed air is suitable for:
Thin carbon steel
Thin stainless steel
Thin aluminum sheet
General sheet metal cutting
Advertising signs
Ordinary structural parts
Customers who want to reduce gas cost
Advantages of compressed air:
Lowest gas cost
Easy to generate on site
Suitable for thin sheet batch cutting
No need to rely on bottled nitrogen or liquid nitrogen supply
Good for cost-sensitive customers
Disadvantages of compressed air:
Cutting edge may become yellowish, darker, or slightly oxidized
Edge quality is usually not as good as nitrogen
Air must be clean, dry, and oil-free
Poor air quality may damage the protective lens in the cutting head
Requires a proper compressor, dryer, filter, oil-water separator, and air tank
From an engineering point of view, compressed air is not just “free gas.” It is a complete air supply system. If the air contains oil, water, or dust, the cutting head, protective lens, and cutting quality will be affected.
Basic Gas Selection Logic
The simplest rule is:
| Cutting Requirement | Recommended Gas |
|---|---|
| Thick carbon steel cutting | Oxygen |
| Stainless steel bright edge cutting | Nitrogen |
| Aluminum cutting with good edge quality | Nitrogen |
| Thin sheet cost-saving cutting | Compressed air |
| Oxidation-free cutting | Nitrogen |
| General low-cost production | Compressed air |
| Thick carbon steel with lower cost | Oxygen |
| High-end sheet metal parts | Nitrogen |
A more detailed selection table:
| Material | Recommended Gas | Reason |
|---|---|---|
| Carbon steel | Oxygen / Air / Nitrogen | Oxygen for thick plate, air for cost saving, nitrogen for oxidation-free cutting |
| Stainless steel | Nitrogen / Air | Nitrogen gives a bright edge; air is cheaper but edge quality is lower |
| Aluminum | Nitrogen / Air | Nitrogen gives better quality; air is acceptable for ordinary thin sheets |
| Galvanized sheet | Nitrogen / Air | Nitrogen is cleaner; air is cheaper |
| Brass / Copper | Nitrogen | Usually needs stable high pressure and better edge protection |
When I talk with a customer, I do not only ask what material they cut. I also ask what edge quality they need and what process comes after cutting.
For example, if the part will be welded, painted, powder coated, or electroplated, the cutting edge quality becomes more important. In that case, nitrogen may be a better choice.
How to Understand Gas Pressure
Gas pressure in laser cutting is not “the higher, the better.”
The correct gas pressure depends on:
Material type
Material thickness
Laser power
Nozzle diameter
Focus position
Cutting speed
Piercing method
Gas purity
Gas flow capacity
Cutting quality requirement
The general direction is:
| Gas | Pressure Logic | Typical Application |
|---|---|---|
| Oxygen | Usually lower pressure | Carbon steel, especially medium and thick plates |
| Nitrogen | Usually higher pressure | Stainless steel, aluminum, oxidation-free cutting |
| Compressed air | Medium to high pressure | Thin sheet, general cutting, cost-saving production |
Different laser powers, cutting heads, nozzles, and process databases may use different parameters. The final pressure should follow the cutting process database of the machine.
As an engineer, I do not recommend promising a fixed gas pressure before confirming the material, thickness, nozzle, laser power, and cutting quality requirement.
A more professional explanation is:
The exact gas pressure depends on material, thickness, nozzle size, laser power, and cutting quality requirements.
Pressure Units: bar, MPa, and psi
The most common pressure units in laser cutting are:
bar
MPa
psi
The basic conversions are:
| Unit | Conversion |
|---|---|
| 1 bar | 0.1 MPa |
| 10 bar | 1.0 MPa |
| 16 bar | 1.6 MPa |
| 20 bar | 2.0 MPa |
| 30 bar | 3.0 MPa |
| 1 MPa | 10 bar |
| 1 bar | About 14.5 psi |
| 1 psi | About 0.069 bar |
So when a customer says:
16 bar air compressor
It means:
1.6 MPa air compressor
When a customer says:
30 bar nitrogen
It means:
3.0 MPa nitrogen
In the laser cutting industry, many customers use bar. Some technical documents use MPa. Some countries also use psi. So it is important to understand the relationship between these units when checking compressors, nitrogen systems, valves, pipelines, and pressure alarms.
When to Use an Air Compressor
An air compressor is suitable when the customer wants to reduce gas cost and does not require the highest edge quality.
An air compressor system is suitable for customers who:
Mainly cut thin sheets
Mainly cut general carbon steel, stainless steel, or aluminum
Do not require a perfect bright edge
Accept a slightly oxidized or darker cutting edge
Will paint, weld, grind, or further process the parts
Have high local nitrogen cost
Do not want to buy bottled gas or liquid nitrogen for a long time
Have a limited budget
A complete compressed air cutting system should include:
| Component | Function |
|---|---|
| Air compressor | Generates compressed air |
| Air tank | Stores air and stabilizes pressure |
| Refrigerated dryer or adsorption dryer | Removes moisture |
| Multi-stage filters | Removes oil, water, and particles |
| Oil-water separator | Protects gas quality |
| Pressure stabilizing system | Keeps output pressure stable |
| Gas pipeline | Delivers air to the machine |
The quality of compressed air is critical.
If the air contains oil, water, or dust, it may cause:
Protective lens contamination
Cutting instability
Poor edge quality
More frequent lens replacement
Damage to the cutting head
Higher maintenance cost
So compressed air cutting is economical only when the air system is properly configured and maintained.
A professional explanation for customers is:
If your main work is general sheet metal cutting and edge color is not critical, a high-quality air compressor system is a cost-effective choice.
When to Use a Nitrogen Generator
A nitrogen generator is suitable for customers who consume a large amount of nitrogen over a long period.
The basic working logic is:
Air compressor compresses air → nitrogen generator separates oxygen → nitrogen is produced → booster increases nitrogen pressure → nitrogen tank stores gas → laser cutting machine uses nitrogen
A nitrogen generator is suitable for customers who:
Run the machine for many hours every day
Cut a large amount of stainless steel or aluminum
Consume a large amount of nitrogen
Face high bottled nitrogen or liquid nitrogen cost
Have unstable external gas supply
Want to reduce long-term operating cost
Have multiple laser cutting machines in one factory
A nitrogen generator may not be necessary when:
Machine usage is low
The customer mainly cuts carbon steel
Stainless steel cutting is only occasional
Local nitrogen price is low
The customer has a very limited budget
Key parameters of a nitrogen generator:
| Parameter | Why It Matters |
|---|---|
| Nitrogen purity | Affects cutting edge quality |
| Nitrogen flow rate | Must meet cutting consumption |
| Output pressure | Must meet cutting pressure demand |
| High-pressure booster | Required for high-pressure nitrogen cutting |
| Gas storage tank capacity | Helps stabilize gas supply |
| Dew point | Affects dryness and cutting stability |
| Filtration level | Protects valves and cutting head |
| Maximum supported cutting thickness | Determines whether the system is suitable for the customer’s work |
For high-quality stainless steel cutting, higher nitrogen purity usually gives more stable edge quality. But higher purity also increases the cost of nitrogen generation.
So the nitrogen generator should not be selected only by price. It must match the laser power, material thickness, daily working time, and required edge quality.
Gas System Structure and Valve Group
The gas system of a laser cutting machine can be understood as:
Gas source → Filtration → Pressure reduction → Control → Detection → Output to cutting head
Common components include:
| Component | Function |
|---|---|
| Ball valve | Manual gas on/off |
| Filter | Removes particles, oil, or water |
| Pressure regulator | Reduces and stabilizes pressure |
| Solenoid valve | Opens, closes, or switches gas circuits |
| Proportional valve | Automatically controls pressure according to CNC command |
| Pressure sensor | Sends actual pressure feedback to the CNC system |
| Pressure switch | Detects whether pressure is above or below a set point |
| Check valve | Prevents gas backflow |
| Safety valve | Releases pressure when pressure is too high |
| Gas mixing valve group | Controls or switches different gases |
| High-pressure valve group | Handles high-pressure nitrogen or air |
| Low-pressure valve group | Handles lower-pressure gas circuits |
A good gas valve group is important because it affects cutting stability, pressure repeatability, gas switching speed, and machine safety.
Pressure Regulator
A pressure regulator reduces high gas source pressure to the stable pressure required by the machine.
For example:
A nitrogen cylinder or liquid nitrogen system may have high pressure
The cutting process only needs a certain pressure range
The regulator reduces the pressure and keeps it stable
The pressure regulator is a basic pressure control component.
If the regulator is unstable, the cutting pressure may fluctuate. Pressure fluctuation can cause rough cutting edges, unstable piercing, more burrs, and inconsistent cutting quality.
Proportional Valve
The proportional valve is one of the most important components in a modern laser cutting gas system.
It is not just an on/off valve. It can automatically adjust gas pressure or gas flow according to the electrical signal from the CNC system.
For example, the CNC system may set:
| Cutting Stage | Required Pressure |
|---|---|
| Piercing | 8 bar |
| Cutting | 15 bar |
| Special process | Different pressure according to material and thickness |
The proportional valve automatically adjusts the gas pressure to the required value.
Main functions of a proportional valve:
Automatic gas pressure control
Different pressures for different materials
Different pressures for piercing and cutting
More stable cutting quality
Better repeatability
Less manual adjustment
Easier parameter management
If there is no proportional valve, the operator may need to adjust pressure manually. This can create several problems:
Pressure changes depend on the operator
Pressure repeatability is poor
Cutting quality is less stable
Changing material takes more time
Automation level is lower
A professional explanation is:
The proportional valve allows automatic gas pressure control from the CNC system, making cutting parameters more stable and easier to repeat.
Solenoid Valve
A solenoid valve is mainly used to open, close, or switch gas circuits.
It works like an electrically controlled switch.
Typical actions include:
| Machine Action | Solenoid Valve Action |
|---|---|
| Cutting starts | Gas valve opens |
| Cutting ends | Gas valve closes |
| Oxygen switches to nitrogen | Corresponding gas circuit changes |
| Piercing starts | Piercing gas circuit opens |
| Cutting begins | Cutting gas circuit opens |
The solenoid valve is important for gas switching and gas timing. If it fails, the machine may have no gas output, delayed gas output, or wrong gas selection.
Pressure Sensor
A pressure sensor sends the actual gas pressure back to the CNC system.
The system can judge:
Whether actual pressure reaches the set pressure
Whether pressure is too low
Whether pressure is too high
Whether gas supply is insufficient
Whether the proportional valve is working correctly
Whether the gas circuit is abnormal
Pressure sensors help the CNC system monitor the real cutting condition. Without reliable pressure feedback, it is difficult to know whether the actual gas pressure matches the programmed pressure.
Pressure Switch
A pressure switch is simpler than a pressure sensor.
It usually detects:
Gas or no gas
Pressure enough or not enough
Pressure above or below a set safety point
Many low-pressure alarms and high-pressure alarms are related to pressure switches or pressure sensors.
The pressure switch does not usually give detailed pressure feedback like a sensor. It mainly gives a yes/no signal.
Check Valve
A check valve prevents gas backflow.
This is especially important in a machine with multiple gas sources, such as:
Oxygen
Nitrogen
Compressed air
Without proper check valves and gas circuit separation, one gas may flow backward into another gas line. This can cause unstable cutting and safety risks.
For oxygen systems, gas backflow and contamination must be avoided carefully.
Safety Valve
A safety valve protects the system from excessive pressure.
When the pressure rises above a safe limit, the safety valve releases pressure to protect:
Pipelines
Valves
Regulators
Fittings
Gas tanks
Cutting head seals
A safety valve is not a normal operating valve. It is a protection component. If it opens frequently, the system pressure setting or valve group should be checked.
Low-Pressure Alarm
A low-pressure alarm usually means the actual gas pressure is lower than the required pressure.
Possible causes include:
| Possible Cause | Explanation |
|---|---|
| Gas source pressure is insufficient | Cylinder, tank, compressor, or nitrogen generator cannot provide enough pressure |
| Air tank pressure is too low | Storage pressure is not enough |
| Pressure regulator setting is too low | Output pressure is limited |
| Pipeline leakage | Gas is lost before reaching the cutting head |
| Filter blockage | Gas flow is restricted |
| Solenoid valve not opening | Gas circuit is blocked |
| Proportional valve failure | Pressure cannot be adjusted correctly |
| Pressure sensor abnormal | The system reads wrong pressure |
| Gas cylinder nearly empty | Gas source is almost finished |
| Air compressor capacity insufficient | Compressor cannot supply enough pressure or flow |
| Nitrogen generator flow rate insufficient | Nitrogen production cannot meet cutting demand |
Low pressure can cause:
Cutting cannot penetrate the material
More dross
Larger burrs
Piercing failure
Cutting interruption
Rough cutting edge
Faster protective lens contamination
Unstable cutting quality
When a low-pressure alarm appears, the correct approach is not to only clear the alarm. The gas source, regulator, valve group, pipeline, filter, and sensor should be checked step by step.
High-Pressure Alarm
A high-pressure alarm means the actual pressure is higher than the machine’s allowed range or higher than the system setting.
Possible causes include:
| Possible Cause | Explanation |
|---|---|
| Inlet pressure is too high | Gas source pressure exceeds machine limit |
| Pressure regulator failure | Regulator cannot reduce pressure correctly |
| Regulator setting is too high | Output pressure is set incorrectly |
| Proportional valve abnormal | Pressure control is unstable |
| Pressure sensor abnormal | System reads pressure incorrectly |
| Gas circuit blockage | Pressure builds up in the line |
| System parameter error | Set pressure exceeds allowed range |
High pressure can cause:
Valve group damage
Pipeline damage
Cutting head seal damage
Gas pipe rupture risk
Unstable cutting
Excessive nozzle impact
Safety hazards
A high-pressure alarm should not be ignored or disabled.
The correct checks include:
Gas source pressure
Pressure regulator setting
CNC pressure parameters
Pressure sensor reading
Rated pressure of the valve group
Rated pressure of the pipeline
Whether the gas circuit is blocked
Gas Pipeline Pressure Rating
There is no single answer to how much pressure all laser cutting machine gas pipes should withstand.
The basic principle is:
The rated pressure of the pipeline must be higher than the maximum working pressure of the system, with enough safety margin.
For example:
| System Type | Pipeline Selection Logic |
|---|---|
| 16 bar compressed air system | The pipe should not be selected exactly at the 16 bar limit |
| 25–30 bar high-pressure nitrogen system | Pipes, fittings, valves, and regulators must meet a higher pressure class |
| Oxygen system | Pipes and valves must be oxygen-compatible, oil-free, and degreased |
| Low-pressure auxiliary gas line | Must still match actual working pressure and gas type |
Parameters to check when selecting gas pipelines:
| Parameter | Meaning |
|---|---|
| Maximum working pressure | Normal safe working pressure |
| Burst pressure | Pressure at which the pipe may fail |
| Gas compatibility | Whether the material is suitable for oxygen, nitrogen, or air |
| Pipe material | PU, nylon, copper, stainless steel, or other materials |
| Fitting type | Must match the pressure and gas type |
| Seal material | Must be compatible with the gas |
| Temperature range | Must match the working environment |
| Oxygen-clean requirement | Required for oxygen lines |
Common gas pipeline material logic:
| Application | Common Choice |
|---|---|
| General low-pressure air | PU pipe, nylon pipe, or metal pipe depending on pressure |
| 16 bar air compressor system | High-pressure air pipe or metal pipe is more reliable |
| High-pressure nitrogen | Stainless steel pipe and high-pressure fittings are commonly used |
| Oxygen | Oxygen-compatible degreased copper pipe, stainless steel pipe, or oxygen-rated valves and fittings |
A professional explanation is:
Gas pipelines, valves, and fittings must be selected according to the maximum working pressure and the gas type. Oxygen lines must be oil-free and oxygen-compatible.
Oxygen System Safety
Oxygen itself is not fuel, but it strongly supports combustion.
So oxygen systems must be handled carefully.
Important oxygen safety points:
Strictly no oil contamination
Do not use ordinary grease or lubricant
Valves and fittings must be suitable for oxygen service
Do not open valves too quickly
Do not casually mix oxygen pipelines with air or nitrogen pipelines
Check cleanliness after maintenance
Use oxygen-compatible seals, valves, and fittings
Keep the gas circuit clean and dry
A professional explanation is:
For oxygen cutting, all oxygen pipelines and valves must be clean, oil-free, and suitable for oxygen service.
How to Recommend a Gas System to Customers
When recommending a gas system, I do not only look at the machine model. I look at the customer’s material, thickness, production volume, edge requirement, and local gas cost.
Use this table as a practical decision guide:
| Customer Situation | Recommended Solution |
|---|---|
| Mainly cutting thick carbon steel | Oxygen |
| Mainly cutting stainless steel and requiring bright edges | Nitrogen |
| Mainly cutting thin sheets and focusing on low cost | Air compressor |
| Cutting stainless steel in large quantities every day | Nitrogen generator |
| Small-power machine with occasional cutting | Bottled gas / liquid nitrogen / air compressor |
| Multiple high-power machines running continuously | Liquid nitrogen station or nitrogen generation system |
| Unstable local gas supply | Nitrogen generator has more advantages |
| Cutting edge oxidation is not critical | Compressed air or oxygen |
| Parts need welding, powder coating, or electroplating later | Nitrogen is preferred |
| Customer has limited budget and cuts ordinary parts | Compressed air system |
| Customer wants high-quality stainless steel cutting | High-purity nitrogen |
| Customer cuts carbon steel thick plates | Oxygen cutting system |
Simple Explanation for Customers
For customers, the explanation should be simple and practical.
You can say:
For carbon steel, oxygen is usually used because it helps the cutting process through an oxidation reaction and is cost-effective for thicker plates.
For stainless steel and aluminum, nitrogen is preferred because it prevents oxidation and gives a cleaner, brighter cutting edge.
For general thin sheet cutting, compressed air is a cost-effective choice, but the cut edge may not be as clean as nitrogen cutting.
This explanation is easy for customers to understand and also technically correct.
Core Questions Before Choosing Assist Gas
Before choosing the gas system, these questions should be confirmed:
| Question | Why It Matters |
|---|---|
| What material does the customer cut? | Different materials need different gases |
| What is the thickness range? | Thickness affects pressure, flow, and gas choice |
| Does the customer care about edge color? | Bright edge usually requires nitrogen |
| Will the parts be welded or painted later? | Edge oxidation may affect later processing |
| How many hours does the machine run per day? | Determines whether a nitrogen generator is worth it |
| What is the local nitrogen and oxygen price? | Affects long-term operating cost |
| Is the local gas supply stable? | Unstable supply may require on-site gas generation |
| Does the customer care more about cost or quality? | Determines whether to choose air, oxygen, or nitrogen |
| What laser power is used? | Higher power often needs higher gas flow |
| What maximum cutting thickness is required? | Affects gas pressure and supply capacity |
Final Selection Logic
The final logic is simple:
| Priority | Best Choice |
|---|---|
| Best edge quality | Nitrogen |
| Thick carbon steel cutting ability | Oxygen |
| Lowest operating cost | Compressed air |
| Long-term large nitrogen consumption | Nitrogen generator |
| Small or occasional gas use | Bottled gas / liquid nitrogen / air compressor |
| Stainless steel bright edge | Nitrogen |
| Ordinary thin sheet processing | Compressed air |
| Heavy carbon steel production | Oxygen |
Once you understand this logic, you can then study detailed cutting process data, such as gas pressure values for different laser powers, materials, thicknesses, nozzles, and focus positions.
Those detailed values belong to the cutting process database. They should not be memorized blindly.
A good engineer should first understand the gas system logic, then use the machine’s process database to fine-tune the actual cutting parameters.