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Inline air filters remove moisture, oil carryover, and dry particulates from compressed air. The right inline filtration can ensure a consistent supply of clean, dry air that fully meets your air quality requirements. Here&#;s everything you need to know about selecting, installing, and maintaining inline filters for your air compressor.
An inline filter for compressed air is a device that's integrated into a compressed air system to remove contaminants. Inline filters are installed directly into the system's air lines, as the name suggests, to efficiently filter out these impurities before the air reaches its point of use. These filters come in various types depending on what specific contaminants they're designed to remove, including dry particulate filters, coalescing oil filters, and adsorption (activated carbon) filters.
What do you need inline filtration? Compressed air contains contaminants when it leaves the compressor, including oils, particulates, and even microorganisms. The inline filter captures these contaminants before the compressed air meets your production environment. This ensures that the air that is used to power your machines and processes is as clean as required.
Contaminants in compressed air can build up within pneumatic equipment and in the compressed air system itself. Contamination in compressed air can cause significant problems for tools and equipment, product quality, worker health, and system efficiency. Appropriate inline filtration can help you avoid issues like these below.
Compressed air can contain various contaminants that can affect the performance and reliability of the system, as well as the quality of the air for specific applications. These contaminants can originate from the ambient air, the compression process, or the compressor's components. To ensure the efficient and safe operation of compressed air systems, it is essential to understand the different types of contaminants and implement appropriate filtration solutions.
Dry particulate contaminants consist of solid particles such as dust, dirt, and rust that can enter the compressed air system from the ambient air or form during the compression process. These particles can cause abrasion, clogging, or blockages in the system, leading to reduced efficiency and equipment damage. Proper intake filters and inline particulate filters can help remove these solid contaminants to ensure clean and efficient compressed air.
Dry contaminants in compressed air are measured in micron size. A micron is one-millionth of a meter or 0.001 mm. The human eye can see particles as small as 50-60 microns, or a bit less than the diameter of a human hair. Contaminants in compressed air systems can be much smaller than this. About 80% of industrial contaminants are in the fine (less than 2.5 microns) or ultra-fine (less than 0.1 microns) range.
Oil carryover is the presence of oil aerosols or vapors in compressed air, which is typically caused by the lubrication process in oil-lubricated compressors. These oil contaminants can lead to product contamination in sensitive applications and affect the performance of pneumatic tools. To address oil carryover, coalescing filters, and activated carbon filters can be used to remove oil aerosols and vapors from the compressed air.
Moisture is a common contaminant in compressed air systems, as the compression process causes the water vapor in the ambient air to condense into liquid water. If not properly removed, moisture can cause corrosion, bacterial growth, and freezing in low-temperature applications, leading to equipment damage and reduced efficiency. In addition to compressed air filtration, aftercoolers and air dryers can be used to remove excess liquid from the air supply. In-line filtration is typically the last line of defense against moisture once other air treatment methods have been applied.
Microorganisms such as bacteria, mold, and fungi can enter the compressed air system from the ambient air or grow in the presence of moisture. These biological contaminants can pose health risks to workers and lead to product contamination in industries like food processing and pharmaceuticals. To mitigate the risks associated with microorganisms, sterile filters and proper system maintenance, including regular cleaning and inspection, can help maintain the air quality and prevent microbial growth.
The combination of air compressor filters you need will depend on the type of air compressor you have, the purity of air you require, and what you are trying to filter out.
Dry particulate filters remove dry particulate from the airstream. Dirt particles are trapped by the filter media through direct interception, inertial impact, or diffusion. Large particles are directly blocked by the fibers in the filter media. Smaller particles are intercepted as they move erratically through the media via Brownian motion (diffusion). These particles are held in the media through electrostatic attraction.
A coalescing filter is another type of inline air compressor filter. An oil coalescing air filter is a type of air line filter that removes both oil mists or oil vapors and dry particulates. A coalescing filter works by trapping mists and aerosols in layers of fine mesh. Aerosolized oil particles and water droplets collect on the surface of filter media and coalesce into larger and larger droplets until they are heavy enough to fall. The liquid is collected at the bottom of the filter and drained away. Fine particulates fall out with the liquid, while coarser particles remain trapped in the filter media.
Coalescing filters provide superior filtration for both particulates and aerosols. They can remove aerosolized droplets and particles down to 0.01 microns and remaining oil to .008 PPM or lower. They may be used alone or in combination with other filters.
An adsorption air compressor filter is used to trap vapors, gaseous contaminants, chemical fumes, and odors. These filters are used for high-purity applications that require the removal of trace gases and vapors along with sub-micron particulates. Activated carbon is the most common material used for adsorption.
In adsorption technologies, molecules of a gas, liquid, or dissolved solid adhere to the surface of a material inside the filter cartridge. Adsorptive materials like activated carbon have millions of tiny micropores, which increase the available surface area for adhesion. Molecules bond to these surfaces and are trapped within the micropores.
An activated carbon inline filter can remove unwanted vapors, gases, and noxious odors from compressed air. It should be used in combination with a compressed air dryer (either a refrigerated dryer or adsorption dryer) and a coalescing filter to remove oil mists and dry particulate from the air before it hits the adsorption filter.
A 2-in-1 inline filter for compressed air is a multi-stage filter that combines two different filtration elements into a single unit. These filters are designed to remove more than one type of contaminant from the air, saving space and potentially reducing costs compared to installing separate filters for each type of contaminant. For example, a 2-in-1 filter may combine a prefilter with an activated carbon adsorption filter to remove both dry particulate and gaseous or vapor emissions.
There are several factors to consider when choosing filtration for your compressed air system. High-quality filters will reduce maintenance requirements, minimize pressure drop, improve energy efficiency, and ensure a consistent supply of clean, dry air.
Installing a high-quality air filter may cost a bit more up front, but it will pay off in the end. High-quality inline compressed air filters will last longer and require less maintenance. They also are less likely to have failures that allow contaminants to escape past the filter, ensuring that air quality will meet the requirements of your application. Always purchase compressed air filters from a trusted and reliable manufacturer to safeguard your equipment and processes.
There are two elements to filtration efficiency for an oil-lubricated air compressor: particulate filtration efficiency (measured in microns) and oil carryover (measured in parts per million, or PPM).
When selecting filters for your compressor system, there's often a trade-off between pressure drop and filtration efficiency. Pressure drop is defined as the difference in air pressure (PSI) measured before and after the filter; a higher pressure drop indicates that the system is working harder to push air through the filter. High filtration efficiency typically requires a denser filter media or smaller pore size, which can increase pressure drop across the filter and thus the energy requirements for the system. Striking the right balance between pressure drop and filtration efficiency is essential to maintain clean compressed air while minimizing energy consumption and operational costs. Select a filter that provides the necessary filtration efficiency while minimizing pressure drop to ensure optimal system performance and energy efficiency.
The filter media is the material used in the filter element to capture and remove contaminants. Common filter media materials include paper, polyester, cellulose, glass fibers, stainless steel, or synthetic materials. Each material has unique properties that affect filtration efficiency, pressure drop, and service life. Choose a filter media that provides the desired filtration performance while considering factors like operating environment, temperature, and humidity.
The flow rate refers to the volume of air that can pass through the filter per unit of time, typically measured in cubic feet per minute (CFM) or liters per second (L/s). Choose a filter with a flow rate capacity that matches or exceeds your air compressor's output to ensure proper filtration without causing restrictions or reducing efficiency.
Service life is the expected operating time before the filter needs to be replaced or serviced. Longer service life can reduce maintenance costs and downtime. When selecting a filter, consider factors like the operating environment and contaminant levels, and choose a filter with a service life that meets your maintenance schedule and budget.
The quality of compressed air is important. Clean, dry compressed air is a benefit for any operation, but the tolerance for contaminants in compressed air varies widely by application. Under ISO , compressed air purity is classified according to three parameters: dry particulate (measured by number and size), moisture (by Vapor Pressure Dew Point or liquid mass), and oil carryover (measured in mass).
Inline compressed air filters can be placed anywhere in the compressed air piping systems. Some of the most common placements are the following:
Depending on your application and air purity requirements, you may install multiple inline filters sequentially or at different places in your system. Inline filtration can be easily configured to your specific needs.
Filtering compressed air before it enters the main distribution piping is usually the most efficient solution. Point-of-use inline filtration can be costly to install and maintain. Efficient inline filtration of air before it enters the compressed air distribution system can usually eliminate the need for point-of-use filtration.
As a general industry rule, it is recommended that you change your inline air compressor filter at least once a year or after 8,000 hours of operation. Like all filters, inline air compressor filters require regular maintenance to ensure that they maintain their filtration efficiency. If you do not change your filters frequently enough, you will notice an increased pressure drop as the filter becomes more loaded. This will reduce the efficiency of your compressed air system and drive up energy costs. An overloaded filter will also impact the quality of your compressed air.
Aire Tip: Keep an eye on the differential pressure gauge to know when it is time to change your inline filter.
There are a few variables that will impact filter life and necessitate more frequent filter changes. These include:
Aire Tip: Change your float drain at the same time you change your inline filter(s).
The best inline air compressor filter for you depends on your application, usage patterns, and air purity requirements. We can help you select the best inline filter for your compressed air needs.
There are four different types of inline filtration offered by PneuTech: particulate, coalescing, activated carbon, and 2-in-1 filtration.
Not sure which filter is right for you? Give us a call at 866-432-. We can help you design an inline filtration solution to deliver compressed air of the purity you need.
© Fluid-Aire Dynamics, Inc. All Rights Reserved.
Currently, it is almost impossible to meet the requirements of the EMC standards. Schurter EMC components will help you with this.
This is an archive article published 08/01/. Some information may no longer be up to date and in line with the current state. Please contact us in case of interest.
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The majority power entry modules features V-Lock locking system. The power connector is equipped with a pin that interlocks with a notch in the power entry module and thus reliably prevents the cord from being pulled out unintentionally.
Link to Daji
You can find more information about all Schurter EMC components in PEM, filter and chokes overviews.
Currently, electronic equipment typically use switching-mode power supply and fast digital circuit. Such devices generate high-frequency voltages and currents during normal operation. Without the power line filter, it is almost impossible to meet the requirements of the EMC standards.
The two primary functions of the power line filter are:
Currently, information technology equipment (ITE) has to fulfil the requirements of EN emission standard and EN immunity standard.
EN defines limits for conducted disturbance at mains terminals in frequency range 150kHz to 30MHz and radiated disturbance in range 30MHz to 1GHz.
Schurter power line filters are optimized for frequency range 150kHz to 30MHz where they provide the best attenuation but simultaneously, they have also around 20dB attenuation at 400MHz, which helps decrease the radiation from antenna created by power cord.
Conducted emission regulations are intended to control the radiation from the public AC power distribution system, which results from high frequency currents conducted back onto the power line. Normally, these currents are too small to cause interference to other products connected to the same power line, however, they are large enough to cause power line to radiate and possibly become a source of interference, for example to AM radio. (For example, EN requires conducted disturbance from Class A devices &#; 60dBuV = 1mV in the frequency range 500kHz to 30MHz.)
Power-line filter also efficiently attenuates continuous RF disturbances during the test according to EN §4.2.2.3, where 3V RMS RF signal in range 150kHz to 10MHz, 3 to 1V in range 10MHz to 30MHz and 1V in range 30MHz to 80MHz is injected into power line.
In combination with surge protection, filter also helps to pass tests according to EN §4.2.4 &#; electrical fast transient and EN §4.2.5-surges.
The filter efficiency is equally, if not more dependent on how and where it is mounted, and how the leads are routed to the filter than on the electrical design of the filter. The figure below shows three common problems associated with the mounting of a power-line filter, which significantly decrease its effectiveness.
1.The filter is not mounted close to the point where the power line enters the enclosure. The exposed power line (antenna) can pick up noise from electric and magnetic fields inside the enclosure.The exposed power line (antenna) can pick up noise from electric and magnetic fields inside the enclosure.
2. The wire grounding the filter to the enclosure has large inductance, which decreases the effectiveness of the Y-capacitors in the filter.
The manufacturer assembles Y-capacitors so that the connection with the cover has minimal inductance.
3.Capacitive coupling occurs between the noisy power-supply-to-filter wiring and the ac power line.
Next figure shows properly mounted power-line filter.
The filter is mounted where the AC power line enters the enclosure to prevent electromagnetic field coupling to the filtered power line. The metal enclosure now also blocks any capacitive coupling from the filter input cable and the filtered power line.
The filter is mounted in a way that the filter&#;s metal case makes direct contact with the device enclosure, which eliminates any additional inductance in series with the internal Y-capacitors. Any wire between the filter&#;s case and the enclosure decreases the effectiveness of the filter as a result of its inductance.
The wires between the filter and the power supply should be routed close to the enclosure to minimize any pickup. Do not route the filter&#;s input leads close to output DC power leads, as this will maximize the parasitic capacitance coupling. Input leads should also be kept away from any signal cables (especially digital cables) and should not be routed over, or near, a digital logic PCB.
An additional improvement over the arrangement shown above is mounting the power supply close to the power line filter.
The above fact points out the advantages of power-line filter having an integral AC power cord connector.
This configuration forces the filter to be mounted where the power cord enters the enclosure and where the filter&#;s metal flange is screwed or riveted to the enclosure (on an unpainted, conductive surface) so the Y-capacitors will be properly grounded.
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