Protecting Precision: Air Wipe Ensures Accurate Measurements

Published on by Tyler DanielLeave a comment

Imagine investing in a high-end laser measurement system, capable of gauging product dimensions down to fractions of a micron, only to have the readings thrown off by something as small as a speck of dust or a thin film of residue. For one of our customers, who specialize in repairing and calibrating laser gauges, this wasn’t just a “what if.” It was a real challenge that needed a reliable solution.

The answer came in the form of EXAIR’s Air Wipe.

In their setup, cylindrical products pass through a laser gauge that verifies their diameter. Any contamination on the surface risks altering the accuracy of that measurement. By installing an Air Wipe just upstream of the gauge, they created a 360° wall of compressed air that strips away residual coolant, debris, or dust. The result is a clean, consistent surface before every scan — ensuring the gauge is reading the product, not the contaminants.

Split ring design eliminates the need for product “threading” through the Air Wipe.

The beauty of the Air Wipe lies in its design. A hinged, split-body housing makes it easy to install around existing lines, while the engineered air gap creates a uniform, high-velocity sheet of air that fully encircles the product. Unlike multiple nozzles aimed at different angles, the Air Wipe eliminates guesswork and guarantees complete coverage without gaps.

This customer chose it for metrology, but the same principle applies across industries:

  • Extrusion lines use Air Wipes to remove cooling water from plastic or rubber profiles.
  • Wire and cable manufacturers rely on them to dry and clean before printing or spooling.
  • Pipe and tubing producers install them before coating or inspection processes.
  • Medical and electronics manufacturers trust them when cleanliness and precision are non-negotiable.

For this customer, the Air Wipe turned a potential weak point in their process into a strength. Instead of worrying about contaminants interfering with measurement, they can now focus on providing precise, reliable results for their clients.

It’s a simple solution that makes a big difference: when the measurement has to be right, start by making sure the surface is clean. EXAIR offers a wide variety of products that utilize a laminar flow of compressed air for cleaning, cooling, and drying operations. Give us a call today to discuss your application!

Tyler Daniel, CCASS

Application Engineer

E-mail: TylerDaniel@EXAIR.com

X: @EXAIR_TD

Protection Against Dead End Pressure with EXAIR Flat Super Air Nozzles

Published on by jasonkirbyLeave a comment

Safety in the workplace is of paramount importance, and most organizations recognize this by implementing annual safety training programs. A fundamental message from these sessions is that safety is a collective responsibility, not just the duty of a select few. At EXAIR, we prioritize safety in all aspects of our operations. Our commitment is evident in the design of many of our products, such as the Flat Super Air Nozzle, which emphasizes our dedication to safe practices. This focus is particularly vital, as improper handling of compressed air can lead to significant health risks.

Meets or Exceeds OSHA Requirements

In the United States, the Occupational Safety and Health Administration (OSHA) is responsible for enforcing regulations that promote safe and healthy working conditions. This agency has the power to levy significant fines for any infractions. Among the frequent violations related to compressed air are those concerning air guns and blow-off devices, specifically addressed in 29CFR 1910.242(b), which pertains to dead-end pressure and chip shielding, as well as 29CFR 1910.95(a), which sets forth the maximum permissible noise exposure levels.

The regulation 29CFR 1910.242(b) addresses the use of hand-held tools, specifically highlighting that blow-off devices must not operate at pressures exceeding 30 psig if there is a risk of compressed air becoming dead-ended. In situations where air has no escape route, it poses a serious risk of penetrating the skin and causing an air embolism. EXAIR’s air nozzles are engineered with fins that facilitate safe air release, thereby preventing skin blockage. Consequently, users can operate the EXAIR Super Air Nozzles confidently at pressures above 30 psig.

2″ Flat Super Air Nozzle

EXAIR’s Flat Super Air Nozzles distinguish themselves from other Super Air Nozzles by utilizing a design akin to an Air Knife, featuring a shim that determines the air gap instead of traditional fins for safe air release. The nozzle’s engineered lip at the outlet effectively prevents dead-ending, ensuring continuous airflow. In the event that the nozzle’s end becomes obstructed, air can still escape from the sides, maintaining safety and compliance with OSHA standards.

 If you have any questions regarding the OSHA directives mentioned above, or anything regarding EXAIR and our products, please do not hesitate to reach out. We would love to hear from you!

Jason Kirby
Application Engineer
Email: jasonkirby@exair.com
Twitter: @EXAIR_jk

Feeling Exhausted?

Published on by Brian FarnoLeave a comment
Our current calendar.

The school year has started here in Cincinnati. For some families, it’s the very first year in the school system; for others, it’s the last. Every year in between brings its own mix of emotions. Personally, I look forward to the sports and events, watching the camaraderie grow between my daughters, their friends, and their teams.

This year, we have a 10th, 7th, and 5th grader. One is about to get her learner’s permit, one is trying out for school volleyball, and one is in her final year of elementary. It feels like a big year all around. The pace of activities has been so fast that it’s hard to fully process what’s happening—and that same thing can easily happen in our work lives.

At home, my wife and I often feel like we’re treading water, bouncing from one thing to the next. We use downtime not just to catch our breath, but also to talk through what’s working, what’s not, and how to prepare better for the weeks ahead. When we skip those conversations, tension builds, and we end up storming as a team. The same holds true in a production environment: without regular evaluation and planning, the whole system suffers.

In manufacturing, output rarely stops. Even when a sector halts for a planned shutdown, the project list is carefully managed to minimize disruption. The focus is always on keeping production moving—whether that means picking up speed, adding shifts, or running longer hours. But smooth production depends on proactive planning.

Take compressed air systems as an example. A simple habit like measuring pressure drop across filters can prevent costly downtime. By installing pipe tees and pressure gauges upstream and downstream of filters, you can monitor performance. Once the differential hits 5 psig, it’s time to plan for an element replacement. Adding this to a maintenance schedule and aligning it with your purchasing cycle turns an unexpected expense into a controlled, predictable one.

Pressure gauges and filters with indicators are both great options for monitoring filter performance.

Just like meal prep and calendar reviews keep our family life running more smoothly, preventive maintenance and equipment monitoring keep production lines efficient. For parents entering the whirlwind of school activities—hang in there. Build a community with the other parents around you. It truly takes a village, just like it takes every department working together to deliver a finished product.

Brian Farno, MBA – CCASS Application Engineer

BrianFarno@EXAIR.com
@EXAIR_BF

Basics of the Compressed Air System

Published on by John BallLeave a comment

Compressed air is used to operate pneumatic systems within a facility, and it can be separated into three categories; the supply side, the demand side, and the distribution system.  In this blog, I will cover each area. 

The supply side is the air compressor, after-cooler, dryer, and receiver tank that produce and treat the compressed air.  They are generally located in a compressor room somewhere in the corner of the plant.  There are two main types of air compressors: positive displacement and dynamic.  The core component of most air compressors is an electric motor that spins a shaft.  Positive displacement uses the energy from the motor and the shaft to change volume in an area, like a piston in a reciprocating air compressor or like rotors in a rotary air compressor.  The dynamic types use the energy from the motor and the shaft to create a velocity with an impeller like centrifugal air compressors.  This velocity converts to a rise in pressure.

How do they work?  Most air compressors are driven by an electric or gas motor.  The motor spins a shaft to push a piston, turn a rotor, or spin a vane.  At the beginning of the air compressor, we have the intake where a low pressure is generated from the displacement to bring in the surrounding ambient air.  Once trapped, Boyle’s law states that when the volume decreases, the pressure increases.  For the dynamic type, the velocity and design will increase the air pressure.  The higher pressure will then move to a tank to be stored for pneumatic energy.  The amount of power required is dependent on the pressure and the amount of air that needs to be compressed. 

The demand side is the collection of devices that will use that compressed air to do “work”.  These pneumatic components are generally scattered throughout the facility.  This would include valves, cylinders, blow-offs, pneumatic clamps, etc.   To condition the demand side, regulators and filters are used.  The Pressure Regulators help to limit the amount of pressure.  For blow-off devices, the lower the air pressure to “do the job”, the less compressed air is used.  To help with the fluctuations in demand, a secondary Receiver Tank can be used.  The demand side can also be a system to do specific jobs. In using pneumatic systems, the “power” must come from the supply side. 

To connect the supply side to the demand side, a compressed air distribution system is required.  Distribution systems are pipes which carry the compressed air from the compressor to the pneumatic devices.  For a sound compressed air system, the three sections have to work together to make an effective and efficient system. An analogy that I like to use is to compare the compressed air system to an electrical system.  The air compressor would be considered the voltage source, and the pneumatic devices would be considered as light bulbs.  To connect the light bulbs to the voltage source, electrical wires are needed which will represent the distribution system.  If the gauge of the wire is too small to supply the light bulbs, the wire will heat up and a voltage drop will occur.  This heat is given off as wasted energy, and the light bulbs will be dim.  The same thing happens within a compressed air system.  If the piping size is too small, a pressure drop will occur.  This is also wasted energy.  In both types of systems, wasted energy is wasted money.  One of the largest systematic problems with compressed air systems is pressure drop.  With a properly designed distribution system, energy can be saved, and, in reference to my analogy above, it will keep the lights on.  To have a properly designed distribution system, the pressure drop should be less than 10% from the reservoir tank to the point-of-use.

Processes lead to continuous improvement.

EXAIR created the “Six Steps to Optimizing Your Compressed Air System”.  By following these tips, you can have the supply side, demand side, and distribution system working at peak efficiency.  If you would like to reduce waste even more, EXAIR offers a variety of efficient, safe, and effective compressed air products to fit within the demand side.  This will include the EXAIR Super Air Knives, Super Air Nozzles, and Safety Air Guns.  This would be the electrical equivalent of changing those incandescent light bulbs into LED light bulbs.  If you wish to go further in enhancing your system, an Application Engineer at EXAIR will be happy to help you. 

John Ball
Application Engineer
Email: johnball@exair.com
Twitter: @EXAIR_jb

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