The Ultimate Buyer's Guide for Purchasing High-Precision Air Compressors for Laser Cutting

Choosing the perfect industrial air compressor for your application depends on many factors, such as the required air pressure, the required air volume (based on air flow and air pressure requirements), air quality needed for the application, energy efficiency considerations, the environment in which the compressor will run, and how air will be used for industrial processes. If you are buying a new air compressor, it's important to look at all of these variables. Choosing the right compressor is the first step in designing a compressed air system that provides optimum efficiency and performance while lowering maintenance costs, reducing downtime and streamlining installation procedures.

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There are several types of air compressors used in industrial settings, including rotary screw air compressors, reciprocating (piston-style) compressors, and rotary vane compressors. Each sector has unique requirements and specifications, demanding a compressed air system tailored to their specific needs. Let's explore those options further in this guide to help you pick the perfect industrial air compressor.

Applications for Industrial Air Compressors 

Industrial air compressors find extensive use in various industrial and commercial applications, showcasing their versatility. Compressed air is a key power source extensively used across diverse industrial sectors due to its safety, flexibility and convenience. Compressed air ensures seamless transitions while delivering a consistently uniform force. Moreover, it boasts a superior power-to-weight ratio to alternative power sources, achieving higher pressures with minimal air volumes.

Air compressors assume roles in general manufacturing, the chemical and petrochemical industries, food and beverage manufacturing, pharmaceutical production, nuclear power generation, plastic production and more. The advancement of air compressor technology has revolutionized these industries, propelling them toward heightened speed, enhanced safety and improved efficiency.

Some of the most prevalent uses for air compressors are:

• Powering pneumatic tools: Pneumatic tools, such as drills, impact wrenches and pneumatic cylinders, require compressed air. An air compressor supplies the necessary pressurized air, enabling these tools to perform various tasks efficiently and with consistent power.
• Automation and control systems: Air compressors power automated systems and provide the necessary compressed air to operate pneumatic actuators, valves and cylinders, which are integral components of automatic machinery and production lines.
• Conveyor systems: Compressed air is commonly used to power conveyor systems in manufacturing facilities. It enables the movement of materials, components and finished products along the production line, facilitating smooth and efficient workflow.
• Pneumatic actuation: Pneumatic actuators, such as air cylinders, are essential for precise movement and control in manufacturing processes. An air compressor supplies the air required to actuate these devices, allowing for accurate and repeatable motion in assembly lines, sorting systems and other industrial applications.
• Cleaning and blow-off operations: Compressed air used for cleaning purposes, such as removing debris, dust or contaminants from parts, machinery or work surfaces. Air compressors power air blow guns or jets, providing a directed stream of compressed air for efficient cleaning and blow-off operations. In the food & beverage industry, air cleaning may be used for nuts, fruits and vegetables. 
• Pressurized systems and equipment: Certain manufacturing processes require pressurized air systems for specific applications. For example, pneumatic presses, clamps and control systems rely on compressed air from an air compressor to generate the necessary force or pressure for accurate and controlled operations.
• Packaging lines: Packaging lines use compressed air for carton forming, filling, and sealing, as well as for shrink-wrapping and blister packaging processes. Air jets are used to sort products, remove defective items, and direct products to different parts of the packaging line.
• Painting and coating: Compressed air is used in spray painting to atomize paint and coatings for a smooth and even application on products, components and machinery. This ensures high-quality finishes with minimal overspray and waste, making the process more efficient and cost-effective.
• Aeration systems: In wastewater treatment and aquaculture, compressed air is used for aeration to promote oxygenation and biological processes. This helps maintain healthy aquatic environments and improves the efficiency of waste decomposition.
• Tire inflation: In automotive and manufacturing industries, compressed air is used to inflate tires and other inflatable products. An air compressor is an essential element of any automotive body and service shop. 
• Welding and cutting: Compressed air is used in plasma cutting to create a high-temperature plasma arc for cutting through metals and other materials. Compressed air is used to cool welding torches, cables, and workpieces, preventing overheating and maintaining the integrity of the weld.

Types of Air Compressors 

The most prevalent types of industrial compressors rely on positive displacement mechanisms to generate pressure. Two commonly used variations in industrial settings are the reciprocating air compressor (piston style) and the rotary screw air compressor. These compressors both produce compressed air using positive displacement, but each type uses a different compression process. Other types of compressors include rotary vane and centrifugal compressors. 

Reciprocating Compressor

Reciprocating air compressors, or piston compressors, use cylinders or pistons to compress air. They have a smaller capacity and are designed for intermittent usage. These compressors frequently are used in garages, workshops, and construction sites. There are two configurations for reciprocating compressors:

• Single-stage compressors: These compressors draw air from the atmosphere and compress it to the final pressure in a single stroke. Single-stage compressors are typically employed for pressures ranging from 70 to 135 pounds per square inch (PSI). They usually offer higher cubic feet per minute (CFM) rates than two-stage compressors.
• Two-stage compressors: Two-stage compressors involve a two-step process, compressing air to an intermediate pressure and then to a final pressure of up to 200 PSI. Two-stage compressors exhibit greater efficiency at higher pressures due to compressed air cooling between stages. While most two-stage reciprocating compressors are oil-lubricated, oil-less versions are also available.
  
  

Rotary Screw Compressor 

A rotary screw air compressor uses two screws rotating in opposite directions to compress air. They are characterized by their high capacity and low-pressure operation, designed for continuous use that can extend up to 24 hours daily. These compressors are typically large-scale industrial machines, ranging from 10 horsepower (HP) to 1,000 HP. Screw air compressors are known for their high reliability and efficiency in applications requiring high air flow and continuous operation. A screw compressor may be oil-lubricated or oil-free. 

Note that screw air compressors offer a maximum pressure of ~215 PSI and are not primarily intended for high-pressure applications like piston compressors. Extended periods of inactivity for a rotary screw compressor should be avoided, as they can lead to rust formation.

Rotary screw compressors are used in various industrial and commercial applications where a continuous and reliable compressed air source is required. Here are some typical uses of rotary screw air compressors:

• Manufacturing facilities: A screw compressor can power pneumatic machinery, such as automated assembly lines, conveyor systems and robotic equipment, providing a consistent compressed air supply for smooth and efficient operations.
• Construction and contractors: A screw compressor can power air tools and equipment, such as jackhammers, impact wrenches, pneumatic drills and sandblasters, enabling heavy-duty tasks and continuous operation without interruption.
• Automotive industry: In the automotive sector, rotary screw compressors are used to power air tools, such as pneumatic wrenches, air-powered paint sprayers and tire inflation systems, providing the necessary compressed air for automotive repair, painting and assembly operations.
• Manufacturing processes: Rotary screw compressors are used in manufacturing processes that require compressed air for operating machinery and equipment. They can power air-operated control systems, pneumatic actuators and cylinders, facilitating precise movement, control and automation in production lines.
• HVAC systems: Rotary screw technology provides compressed air for cooling, air circulation and pneumatic controls in large-scale HVAC applications, ensuring efficient and reliable operation of the systems.
• Food and beverage industry: In the food and beverage industry, rotary screw compressors are used for packaging, bottling and processing applications. They provide clean, oil-free compressed air, adhering to the strict hygiene standards required in food and beverage production.
• Energy and mining: Screw air compressors can power drilling equipment, pneumatic tools and control systems, enabling efficient exploration, extraction and processing of natural resources.

Rotary Vane Air Compressors

Rotary vane compressors are a type of positive displacement compressor that uses a series of vanes mounted on a rotor, which rotates inside a cavity. As the rotor turns, the vanes slide in and out, trapping and compressing air in the process. Like a rotary screw air compressor, they are typically used for applications requiring high airflow and continuous operation. 

Centrifugal Air Compressors

Centrifugal compressors are a type of dynamic compressor that uses the principles of centrifugal force to compress air or gas. They consist of a rotating impeller that accelerates the air or gas outward, increasing its velocity. They are capable of handling large volumes of air or gas and are designed for continuous, steady-state operation. 

Oil-Lubricated vs. Oil-Free Air Compressors

The choice between lubricated vs. oil-free air compressors depends on specific industry requirements. Both reciprocating compressors and screw air compressors come in oil-lubricated and oil-less varieties. Oil-lubricated compressors are much more common in industrial environments, as they offer longer service life with less maintenance and downtime. However, oil-lubricated models may be required for applications requiring very clean air free from oil carryover. 

• Standard oil-lubricated compressors: Most air compressors require oil for lubrication to reduce friction and wear between moving components. The oil also helps dissipate heat generated during compression, leading to smoother operation and extended pump life. As the oil circulates in the pump or air end, it can introduce small amounts of oil vapor or particles into the compressed air stream. While these contaminants may not be an issue for many applications, they can impact sensitive equipment or processes that require clean, oil-free air.
• Oil-free compressors: Oil-free compressors utilize alternative mechanisms (such as non-stick coatings, like Teflon) to achieve lubrication without needing oil. Oil-free compressors provide a cleaner compressed air output, eliminating the risk of oil contamination. An oil-free operation makes them suitable for applications that demand oil-free air, such as in the food and beverage industry, electronics manufacturing, medical environments, and specific painting or finishing processes.

Variable Speed Drive (VSD) Air Compressors

A variable speed drive (VSD) compressor is an air compressor that uses a variable frequency drive (VFD) to control the speed of the compressor motor. This allows the compressor to adjust its speed and output to match the demand for compressed air, resulting in improved efficiency and energy savings. By operating at lower speeds when full capacity is not needed, the VSD air compressor consumes less energy compared to a fixed-speed compressor, which always runs at full speed. 

For businesses looking to reduce energy costs and lower utility bills, VSD compressors offer significant savings by operating only as needed. VSD technology is widely available and commonly used in screw compressors. It is less commonly used for reciprocating compressors.

Common Air Compressor Features 

When selecting a suitable air compressor for your company, you require more comprehensive information. In addition to the available types, you need to be aware of the air compressor features and options associated with each.

Pressure, Capacity and Flow Rate

Air pressure is measured in pounds per square inch (PSI) and represents the air pressure the compressor delivers at a certain airflow (CFM). Most industrial air compressors offer pressures ranging from 100 to 175 PSI. 

Maximum CFM Usage

Cubic feet per minute (CFM) measures the volume flow rate, indicating how much air a compressor can pump in one minute. The required air flow depends on the typical air consumption of the tools used at the same time. Larger applications require higher CFM ratings. Some compressors may be rated based on Standard Cubic Feet per Minute (SCFM), which standardizes the measured flow of air to a set of reference conditions: 14.5 PSIA, 68 degrees Fahrenheit and 0% relative humidity. Calculating the total CFM of all the tools used simultaneously and adding a 30% safety buffer helps determine the required CFM.

Horsepower

Horsepower is the unit of measurement for the power a compressor motor produces. Higher HP engines generate greater CFM at a given PSI and can handle heavier workloads. The typical range of HP for rotary screw compressors falls between 5 HP and 100 HP, though some models are available with ratings of 500 HP and up. Reciprocating compressors can range from 1 HP to 100 HP, though screw compressors are usually preferred at the higher HP range. 

Motor

The motor for the air compressor may be fixed-speed or variable-speed drive (VSD). 

• A fixed-speed motor runs at a constant speed and delivers a consistent level of output. These are best for applications where the demand for power or output is steady and predictable, such as simple tools, fans, and conveyor belts. However, they consume more power than a VSD if they are not used to their full capacity. 
• A VSD motor Adjusts speed based on the demand, providing variable output levels. It can help reduce energy costs and improve efficiency, especially where demand fluctuates. 

Drive System

The drive system for the compressor may be belt drive or direct drive. 

• In a belt-driven compressor, a belt and pully system is used to transfer power from the motor to the air pump or air end. Most piston air compressors are belt-driven. 
• Direct-drive compressors, on the other hand, have a crankshaft that connects the motor directly to the air end. Most air compressors over 50 HP are direct-drive. 

Power Source

Most industrial air compressors are powered by electricity, but some are available in gasoline-powered models. 

• Electric motors are preferable if electrical power is consistently available. Electric systems are cost-effective and require less maintenance. Large stationary compressors used in manufacturing environments are almost always electric-powered. 
• On the other hand, if electrical power is not always accessible, a gasoline engine-driven compressor offers flexibility in the work area. Gasoline-powered compressors are almost always reciprocating compressors, as they are more rugged and portable. These compressors are valuable on construction sites and other scenarios where mobility is a priority. 

Air Tank

An industrial compressed air system will almost always require storage in the form of an air tank. The air receiver tank stores the compressed air after it exits the compressor. The air tank provides a ready supply of air that can be used on demand. The tank also allows some of the excess moisture to fall out of the compressed air as it cools. The tank may be integrated with the compressor or a stand-alone unit.  

• Tank-mounted compressors have the air compressor and air storage tank integrated into a single unit. This design is common in both reciprocating and rotary screw compressors. The integrated unit takes up less space, making it ideal for workshops or areas with limited space. Integrated tank-compressor combos are usually available for smaller compressors, 30 HP and below. 
• Larger compressors typically require a separate air tank for air storage. In large systems, there may be multiple air tanks, including wet and dry tanks. 

Cooling System

A compressor should feature an internal cooling system to maintain optimal temperature for the pumping mechanism and motor, thus extending their life span. 

Cooling systems to choose from include: 

• Air-cool system: An air-cooling system utilizes a fan to cool the pump and vents excess heat into the ambient air.
• Closed-loop dry cooling system: This system operates similarly to a car radiator or air conditioner coils. A coolant, usually glycol, circulates through closed coils, carrying heat away from the compressor pump and motor. Excess heat dissipates from the coils, re-cooling the liquid for the next cycle. 
• Open-loop evaporative cooling system: This system is different as it relies on fresh water and moving air to cool the compressor. A fan blows air across the water, cooling the compressor motor naturally.

Thermal Overload Switch

Due to the heat generated during air compression, an industrial air compressor should include a thermal overload switch. This safety feature shuts off the motor if the compressor overheats, reducing the risk of motor burnout.

Drain Valves

The compressor and air tank will require drain valves to drain excess water and prevent the buildup of moisture in the system. Automatic drain valves open automatically, ensuring dry air and reducing maintenance.

Noise Reduction Features

Enclosures and silencers can be used to minimize noise levels, which may be important for indoor or noise-sensitive environments.

What to Look for When Buying an Air Compressor

After determining the type of air compressor and horsepower best for your application, you can decide how to buy an air compressor. By understanding what to look for, you can select an air compressor that will provide reliable performance and meet your requirements.

Purpose and Intended Use

Determine the air compressor's primary purpose and intended use. Consider the applications you will be using it for, whether it's powering pneumatic tools, operating machinery or running a production line. Create a list of your requirements for your air compressor to help you identify the appropriate specifications and decide how to choose the right air compressor.

Operating Pressure

Assess your applications' maximum required operating pressure. Consider the air pressure needed by your tools or equipment and choose an air compressor that consistently delivers the required pressure. While tools typically operate at a maximum of 90 PSI, choosing a compressor with a higher PSI rating is wise. As air pressure decreases during usage, having a capacity of at least 35% above the required 90 PSI (around 120 PSI) ensures consistent pressure for optimal performance.

Air Flow

Evaluate the volume of airflow you will need. Determine the total CFM required by considering the air consumption of all the tools or equipment used simultaneously. Add a safety buffer of around 30% to ensure sufficient airflow. Remember that excessive CFM requirements can lead to an unnecessarily large and costly air compressor. 

Noise Level

Evaluate the noise level of the air compressor, especially if you will be using it in a noise-sensitive environment. Look for compressors with lower decibel (dB) ratings or models with noise-reducing features such as insulated enclosures or vibration dampening.

Durability and Build Quality

Examine the build quality and durability of the air compressor. Consider factors such as materials, construction design and overall reliability. A sturdy and well-built compressor will provide long-lasting performance and require fewer repairs or maintenance.

Additional Features and Accessories

Take note of any additional features and accessories that may enhance the usability and convenience of the air compressor. Other features could include automatic shut-off, adjustable pressure settings, integrated air filtration systems or built-in air dryers. Consider whether these features align with your specific requirements and provide added value.

Brand Reputation and Customer Support

Research the reputation of the brand and the customer support they offer. Look for well-established, reputable manufacturers that produce reliable, high-quality air compressors. 

Budget Considerations

Set a budget for your air compressor purchase and ensure you find a model that fits your financial constraints. While it is essential to consider cost, prioritize finding a compressor that meets your specific requirements and offers good value for its features and performance.

How to Choose the Right Air Compressor 

By carefully considering factors and aligning them with your specific application, you can choose an air compressor that meets your needs, provides optimal performance and offers long-term reliability. Here is a list of factors to consider when selecting a suitable air compressor: 

• Required operating pressure: Determine the maximum pressure needed for your application. Consider the PSI requirements of the tools or equipment you will use with the compressor.
• Air flow: What is the total air volume (measured in cubic feet per minute, or CFM) of air needed for your application? The higher your air flow requirements, the larger the compressor will need to be to keep up. CFM ratings are directly tied to the horsepower (HP) of the motor. CFM and PSI are also interrelated; the higher your PSI requirements, the more air flow will be needed to maintain that PSI. 
• Duty cycle: Determine the expected duty cycle of your application. Some applications require continuous operation, while others have irregular usage patterns. Choose a compressor that can handle the duty cycle effectively.
• Maintenance requirements: Evaluate the maintenance needs of the compressor. Consider factors such as oil changes, filter replacements and overall upkeep. Determine if the maintenance schedule aligns with your resources and capabilities.
• Compressor type: Choose between different compressors, such as reciprocating (piston) or rotary screw, based on your specific requirements and budget. Choosing between a screw compressor and a reciprocating compressor depends on factors such as duty cycle and CFM requirements. Rotary screw air compressors are particularly suited to high-CFM, continuous operations found in many manufacturing environments. 
• Additional features: Consider other features that enhance usability and performance. These may include automatic start/stop, pressure regulators, built-in air dryers, thermal overload protection, digital controls or integrated air filtration systems.
• Safety considerations: Prioritize safety features such as pressure relief valves, proper grounding and adherence to safety standards.
• Future expansion: Consider potential future growth or changes in your air requirements. If development is anticipated, ensure the compressor can meet future demands.

Find the Right Air Compressor With Fluid-Aire Dynamics 

Fluid-Aire Dynamics offers an extensive range of air compressors tailored to meet diverse needs. We exclusively provide equipment and products manufactured by reputable companies that have earned our trust. We can help you find the perfect industrial air compressor for your application and design a compressed air system around your needs. 

Our commitment extends beyond product sales. With years of experience, we possess expertise in installing and repairing these products. Our services encompass a wide range, including repair, maintenance, installation and emergency support. By providing prompt assistance, we aim to minimize downtime for our customers, leading to increased profitability.

Explore our air compressors today, and feel free to contact us anytime for additional information or a free estimate. 

Overview of Air Compressor Laser Cutters

Many people are beginning to accept the use of laser cutting technology for both domestic and industrial applications.

Laser cutting has proven to be the most effective method of cutting materials, even in the most sensitive industries, such as chemical processing factories.

How these laser machines work tends to vary. One thing that we can be sure of is there has been a growing popularity of is air-assisted laser cutting machines.

In other words, we are simply talking about an air compressor for the laser cutting machine.

For years, laser cutting machines have been expensive to use and maintain. This forced manufacturers to come up with different innovations for these tools.

As they were focusing on reducing the cost of the laser machines, they also wanted to improve on the efficiency of laser cutters.

Among the many inventions that were introduced, one of them was the use of air or compressed air to control the performance of the cutter.

Do you want to reduce the cost of using your laser cutting tool? Maybe it is tome to introduce an air compressor.

In this article, we are going to uncover everything that you should know about air compressor for laser cutter.

Understanding the Principles of a Laser Cutter
To know the importance of an air compressor in a laser cutting machine, it will be prudent to start off by learning the basics of a laser cutter.

Just as the name suggests, laser cutting is all about cutting or slicing a material by using laser technology.

A powerful laser beam is focused on the target area where it causes the material to vaporize or burn.

You can obtain different designs and dimensions just by using the laser beams. This is because it allows users to focus on specific areas. The beam will not touch the unmarked parts of the material.

Laser cutting is a non-contact thermal fabrication technique that can be used on a wide range of materials.

You can use it on metals and even plastic materials.

How Does Laser Cutting Work?

The procedure works by having a focused laser beam go through the material that you are hoping to cut, conveying a precise and smooth completion.

At first, the beam penetrates the material with an opening at the edge, and afterward, the beam is proceeded with from that point.

The laser basically liquefies or melts the material away that it is run over, so it is more similar to dissolving than cutting. This implies it can undoubtedly cut light materials, for example, fabric up to harder metals and gemstones, for example, precious stones.

When using a laser cutter, you can choose either a pulsed beam or a consistent wave beam, with the previous being conveyed in short blasts while the last works persistently.

For more information, please visit High-Precision Air Compressors for Laser Cutting.

You can control the beam power, length heat output, and the material you are working with. You can also use a mirror or unique focal point to additionally centre the laser beam.

Laser cutting is a profoundly precise procedure because of this significant level of control that you are offered.

Because of this, cuts with a width as little as 0.1mm can be accomplished when utilizing the procedure.

And that is how a laser cutter works. So, where does the air compressor come in? W

During the laser cutting process, the main function of the compressed air is to expel the molten material.

Since laser beams generate heat, this means that the affected section of the material will melt. The residue will accumulate around the burnt section.

The pressured gas will form a strong jet that will expel the material from the surface.

What Types of Gases are Used in the Air-Assisted Laser cutting Machines?

Are there specific gases that are used in the air compressor for the laser cutters?

Due to the nature and the operation of the laser cutting machines, There are only a few types of gases that are used for the process.

These gases are oxygen, nitrogen, and CO2.

-Oxygen
There are two critical roles that oxygen gs plays in an air compressor for laser cutter.

The first role is it blows away the molten material from the cut surface. The second role is to enhance the melting of the metal by acting as an oxidation agent.

With these two critical roles, the cutting power of the laser cutter will be improved by a big margin.

However, the presence of oxygen on a laser cutter also means that the surface will be oxidized.

Oxygen can also improve the hardness and rigidity of the processed material.

-Nitrogen gas
Since nitrogen takes 78% of the total gas, we should definitely expect it to be heavily used in the laser cutting process.

One of the key roles of nitrogen gas is to form a protective layer around the molten metal.

In doing so, it prevents the oxidation of the cut material hence preserving the quality of the surface.

However, since nitrogen works against the effect of oxidation, it does not have any impact on the heat transfer process.

Also, it does not improve the heating capability of the laser cutter. This explains why people tend to assume that it increases the cost of the cutting process.

-Air
Under natural circumstances, oxygen takes 21% and nitrogen 78%. The remaining percentage is occupied by other gases.

These other specific gases make up for the remaining small percentage.

However, the sensitivity of the laser cutting means that only a few select gases can be utilized in the air compressor.

For instance, the gas should not inhibit the oxidation property of the laser cutting process.

The gases should not cause an increase in the power consumption of the compressed air.

Also, they should be dense enough so as to cause the expulsion of the molten material that has been extruded through the laser cutting process.

What are the Applications of Laser Cutting Air Compressor

An articulately cut metal sheet. A wooden load up that mirrors a decent idea or aviation save the part that makes an ideal plane.

Exactness, precision, and master building go into the creation of helpful parts, devices, and other creative products you see around yourself.

What's more, what goes behind the thinking about these items?

All things considered, with regards to making flawless creations, 'Laser Cutting' has consistently been an extreme strategy.

Laser engraving machines can cut the most multifaceted shapes quicker than some other instruments. Furthermore, a large portion of the great quality laser cutting machines has been perfectly curated for different applications.

In the event that you are into laser cutting business, you should think about various laser cutting applications and their degree. Tell us about every last one of these applications in detail.

Here is a brief overview of the most common applications of air compressor for laser cutting machine:

1. Metal Sheet Cutting
Metal sheet cutting the greatest and the most broadly perceived applications of laser cutting.

Through laser cutting, it is conceivable to cut metals like steel, aluminum, metal, tungsten, and nickel. Anyway, what occurs during metal sheet cutting?

A laser beam is centered around the outside of the metal.

The metal at that point absorbs the beam, melts, and takes the ideal shape.

On the off chance that you need clean cuts and smooth finishes, you can still go ahead and do so with the post-laser processes.

2. Signage cutting
As per different promoting reports, signage will make the most noteworthy print application in recent years. many people are expected to embrace signage.

Signage manufacturing companies need laser cutting to make 3D signage boards out of wood and plastic. Furthermore, laser machines have all the adaptability one needs to engrave various signage designs.

For making an ideal laser cut signage, experts must guarantee that the measurements are pre-characterized and right.

Air-assisted laser cutting with signage laser parts is known to give an ideal, proficient, and modified cut. The last size obviously, relies upon the client.

The compressed air can also ensure that the signage has a smooth finishing.

3. Glass cutting and engraving
That glass looks extremely beautiful! Have you ever found yourself making this statement?

If the answer is yes? Then you probably are delighted by the work of compressed air for laser cutting machines.

Most glasses that are used in different application areas are cut and engraved through laser cutting.

Glass mugs, wine glass, and other artifacts that are made of glass material must have undergone an intricate laser engraving process.

This applies to other glasses that are used in large scale applications such as construction.

4. Plastic cutting
Although cutting plastics may seem to be a simple process, there are times when you need to be more careful, especially when dealing with high-density plastic materials.

Compressed air for laser cutting is also deployed when you want to improve the accuracy of the plastic cutting. It is usually not easy to achieve precise cutting when using different techniques.

Laser cutting is also safe for cutting the plastic materials as it limits the burning effect. There will also be minimum pollution on the environment.

The cutting can also be used for engraving and adding labels onto the plastic materials.

Advantages of Air-Assisted Laser Cutting

There are many factors that have contributed to the massive popularity of air compressor laser cutting machines. The benefits of buying the best air compressor for laser cutting cannot be underestimated. Some of these benefits include;

-The ability to cut complex designs: The laser beams can access any location; hence can easily work on the complex designs.

-Cut different materials. As we have seen, a great air compressor for laser cutter can cut and engrave different types o materials.

-Saves time: Air compressor for laser cutting can save you a great deal of time. It cuts through the materials faster than the other laser cutters. Also, the blowing mechanism of these laser cutters speeds up the whole process.

-Reduces wastage: Air compressor for laser cutting helps to reduce wastage of the material. This is because laser beams are able to focus only on the target area of the material. The surrounding patches won't be affected by the cutting process.

-Deeper and precise cuts: The laser beam has the power to penetrate deep into the material and obtain quality cuts.

Conclusion
In an increasingly competitive environment, there is always a need to improve the productivity of all the manufacturing processes.

One way of doing so is by cutting down the cost of running any activity. This is something that the air compressor for the laser machine has strived to achieve.

By using a combination of different types of gases, the performance of the laser cutting machines has been greatly improved.

Air compressors have also widened the application areas of the laser cutting machines both for commercial and personal use.

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