Compressed Air Pipe

Intelligent Compressed Air: System Equipment

Published on by Russ BowmanLeave a comment

At the end of Naval Nuclear Power School, students who’ve just spent two years learning how to boil water must pass a comprehensive examination board before they’re released into the fleet as real live “Navy Nucs.” One popular question at these boards (in 1987 anyway) was to describe, in detail, the path a drop of seawater takes to become reactor coolant (a warship at sea must be self-reliant, and that includes making our own pure water.) A correct answer would prove the student’s knowledge of various piping systems, the steam distilling and water purification processes, reactor coolant chemistry maintenance, and, if you were lucky, a deep dive into the Six Factor Formula which mathematically defines the six events* that affect the probability of neutron multiplication, and hence, the sustainability of nuclear fission in the reactor core:

*Two of these six events relate to the thermalization of neutrons by the coolant. That’s why it’s considered to be a valid part of the ‘seawater-to-reactor-coolant’ question.
The block on the left represents a cubic foot of air at atmospheric pressure. The one on the right represents how much space the first one takes up when compressed to 100psig.

In that same vein, for today’s EXAIR blog, I thought I’d trace a Standard Cubic Foot (SCF) of air from the compressor room, through a typical industrial compressed air system, to its point of use. First, let’s define what that is: Imagine a cubic foot of air in front of you. If the atmospheric pressure is 14.5psia (average for sea level elevation), the ambient temperature is 68°F, and relative humidity is 0%, then that’s one Standard Cubic Foot of air. Now, let’s say this air is in an ideal compressor room – ‘ideal’ meaning those atmospheric conditions apply – and follow its path to an EXAIR Super Air Knife:

  • Filter, Part 1 (intake): When the air compressor draws our SCF in, it passes through filtration media to remove impurities like dust, oil, and moisture. It’s important to remember that this filter is there to PROTECT THE COMPRESSOR from those contaminants, not to provide any measure of cleanliness to the compressed air itself.
  • Compression: This is where our SCF gets compressed by reciprocal or rotating elements imparting energy to it, and it now occupies considerably less space than it did in the atmosphere. This also raises the temperature. When all the molecules that comprise our SCF get closer together, they run into each other more often, and that increased friction makes them hotter. Which can be bad, unless we do something about it.
  • After cooler: Hot compressed air can cause unsafe surface temperatures and can damage gaskets, seals, or other components in the downstream system. Cooling our SCF down is the first thing we want to do after compressing it.
  • Filter, Part 2 (discharge): While the Intake Filter takes care of impurities that could have damaged the compressor, the compressor itself can add some back into our SCF – like oil, wear particulate from meshing gears or seals on moving parts, etc. You’ll want to remove those as well, before letting them go any further in the system. Contaminants like that can really do a number on the operation and effectiveness of some types of dryers.
  • Dryer: While the intake filter removes some finite amount of moisture from our SCF before compression, the compression cycle increases the moisture concentration of it. Dryers come in different types and configurations, each with their own pros & cons, and certain types are more suitable for certain situations. Here’s a link to a blog on the subject by Jordan Shouse that’s both informative and entertaining!
  • Primary Storage: Once our SCF gets cooled, cleaned, and dried, it can take a little break if it’s not needed right away, in a receiver tank. Such a tank, like EXAIR’s Model 9500-60 60 Gallon Receiver Tank (right), near the compressor discharge, serves several purposes:
    • It maintains header pressure during any load transients that happen too quickly for the compressor to keep up in real time.
    • It provides further moisture removal, as any water that condenses in this receiver can be drained from a valve on the bottom.
    • It also allows the compressed air to cool further.
  • Distribution Header Piping: This is the “highway,” if you will, that our SCF travels to where it’ll be used. It’s not alone, either – there are sometimes hundreds, if not thousands, of other SCF’s passing through every minute. And if it’s not appropriately sized, there’ll be problems akin to traffic jams on crowded roads. The appropriate size and layout of the header piping will be determined by a number of factors – here’s a link to a blog with more details on that.
  • Airdrops: These are the branches from the distribution header that lead to the various points of use in the facility. Our SCF will take whichever one it gets directed to…in this case, the aforementioned EXAIR Super Air Knife. The proper size of the drop piping or hose will be determined by the compressed air consumption of the load(s) serviced by the drop, and its length from the header. In the case of our EXAIR Super Air Knife that our SCF is heading towards, the recommended in feed pipe sizes are listed in the Installation/Maintenance Guide:
The longer the drop length, the larger the diameter needs to be to compensate for line loss due to friction.
  • Filter, Part 3 (point of use): Good engineering practice calls for point-of-use filtration. Our SCF has already been through two filters, I know, but it’s also potentially picked up some more contamination along the way. Rust from the inside walls of iron pipes is the most common culprit. The EXAIR Super Air Knife that our SCF is heading towards needs its supply to be filtered for particulate to a level of 10 microns or less. EXAIR Automatic Drain Filter Separators have 5-micron particulate elements, and centrifugal elements that ‘spin’ out any remaining moisture. Depending on the needs of the application, we also have Oil Removal Filters with coalescing elements for oil/oil vapor. They also provide additional particulate filtration to 0.03 microns.
  • Regulator: It’s taken a good deal of effort and expense to get our SCF to this point, so it only makes sense to use it as efficiently as possible. A Pressure Regulator allows us to precisely ‘dial in’ the supply pressure so that we don’t use it (or any of the other SCF’s that it’s traveling with) any more than needed.
EXAIR Automatic Drain Filter Separators (left) can be directly coupled to Oil Removal Filters (center) and Pressure Regulators (right) for a compact installation, free from threaded connections.
EXAIR’s award-winning EFC Electronic Flow Control is a ‘plug and play’ system that can save you THOUSANDS of dollars in compressed air costs.
  • Shutoff valve: Years ago, I talked to an engineer at a company that was using one of our Super Air Knives to blow off parts that were passed in front of it by a robot. The robot’s arm turned & rotated the part in the air curtain to ensure it got completely blown off. This only took a couple of seconds, as the operators had ‘tweaked’ the arm movement to do it as quickly as possible. However, there were about 15 seconds between parts…and the Super Air Knife WAS BLOWING THAT WHOLE TIME. Since they’d already told me how great their automation techs were at programming the robot, I suggested that they go one more step and install a Solenoid Valve in the supply line to the Super Air Knife and use the robot’s logic to open it right before the robot got there, and close it right after the robot left. Step Four of our Six Steps To Optimizing Your Compressed Air System is to “turn off the compressed air when it’s not in use,” and by doing so, they reduced the compressed air consumption of this one Super Air Knife by about 80%. THAT’S optimized. If you don’t have existing logic to do this, our EFC Electronic Flow Control will do it for you.
  • The Super Air Knife: At long last, our SCF is ready to fulfill its purpose, and the Super Air Knife will help it do so in the most efficient way possible. It uses that SCF of air, along with all the others that pass through, to entrain a WHOLE BUNCH of SCF’s from the surrounding environment. The amplification ratio for EXAIR Super Air Knives is 40:1, making them the most efficient compressed air-blowing products on the market.
EXAIR Super Air Knives come in lengths from 3″ to 108″, and are available from stock in aluminum, 303SS, 316SS, or PVDF.

It’s been a LONG time since I’ve used the Six Factor Formula for the neutron life cycle in nuclear fission (and honestly, I haven’t missed it all that much), but every day, I use formulas and figures related to:

Just to name a few. If you’d like to “math something out,” (just not the Six Factor Formula, please), give me a call.

Russ Bowman, CCASS

Application Engineer
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Air Cooling Maintenance?

Published on by Brian FarnoLeave a comment

The time has finally come, and spring is here! The Cincinnati Reds are playing, Spring Soccer is happening early on Saturday mornings, and the FC Cincinnati Stadium is bustling here in Cincy. With that, temperatures are climbing, the grass and weeds are growing, and more and more families are out walking around and doing outdoor activities. With this, also comes warmer temps, and lots of spring allergies in the Farno household. As a dad, I have stepped into my role pretty well by trying to delay turning on the air conditioner until everyone else in the house is plotting my demise. This year, I achieved it by putting off the routine maintenance of the condensing coils.

In case you weren’t aware, here in the Midwest, where pollen runs rampant and the winds have been strong this year, it is a great idea to clean out the condensing coils on your home’s A/C system before turning it on for the year. Unfortunately, your home A/C system is not maintenance-free like the Cabinet Cooler Systems EXAIR offers; at the same time, your home needs a lot more than a few thousand BTU/hr of cooling capacity. When we first bought the home, I didn’t know this was a thing, as the home I grew up in didn’t have central air. We rocked Window A/Cs, and my parents still do. So, cleaning the outdoor unit was not part of my knowledge base. This is something I learned once the air conditioner wasn’t working, and I started to troubleshoot.

The main purpose of the condensing coils is to strip all the heat out of the refrigerant and get it to “condense” back into its liquid state to be pushed back through the orifice and continue to cool the air that is being passed over the A Coils inside the house. These coils are covered in fins that are very tightly spaced. The outside unit has a large fan that pulls the surrounding air in through the coils and exhausts the hot air up out of the top. There is no filter on that incoming ambient air, though, so all the leaves, cobwebs, pet hair, pollen, dirt, mulch, you name it, get pulled up into these fins. Over time, this starts to get a buildup, and the cooling fins will start to lose their efficiency. The fan won’t be able to pull as much air through, and eventually, the gas doesn’t get condensed, which then reduces the cooling and can cause other bigger issues. This is just like a refrigerant-based A/C panel cooler in a facility. Most of the time, they have at least a small filter on the air intake to try and reduce the contamination of the condensing coils. So I clean the A/C condenser at my house using a coil cleaning solution diluted down, a pump sprayer, and a regular garden hose.

The main thing to remember when cleaning this is that the majority of the dirt is from the air being pulled into the center by the fan. So I rinse the coils from the inside out and make sure I have free passage all the way through. The water doesn’t need to be a high-pressure rinse like an OmniStream nozzle or one of BETE’s NF Nozzles, just a simple low-pressure stream of water to get between the fins and push all contaminants as well as rinse the solution away. Remove any leaves or other unwanted debris from inside the unit and then bolt the fan and cage back down. Then let the family enjoy some cold air inside the house.

This type of maintenance is something that easily gets overlooked when looking at refrigerant-based electrical panel coolers. That is where EXAIR Cabinet Cooler Systems shine. The only filter you have to worry about is a redundant point-of-use compressed air filter that is included with the Cabinet Cooler Systems. No chemicals needed for cleaning, no water, no mess to change out a compressed air filter, just long-lasting performance. If you want to talk about how to change your control panels over to Cabinet Cooler Systems, contact an Application Engineer today.

Brian Farno, MBA – CCASS Application Engineer

BrianFarno@EXAIR.com
@EXAIR_BF

Exploring the Versatility of EXAIR’s Vac-u-Gun

Published on by Jordan T ShouseLeave a comment

In industrial settings, maintaining a clean, efficient, and safe workspace is a constant challenge. Whether it’s removing debris, transferring materials, or blowing off surfaces, the tools used need to be reliable, cost-effective, and adaptable. Enter EXAIR’s Vac-u-Gun—a compressed air-powered, multi-functional device designed to tackle a variety of industrial housekeeping tasks. In this blog, we’ll dive into the technical details of the Vac-u-Gun, how it operates, and the applications where it shines.

Constructed from durable die-cast aluminum, the Vac-u-Gun has no moving parts, ensuring minimal maintenance and a long operational life. Switching between vacuum and blow-off modes is simple—just unscrew the threaded cap, reverse the orientation of the internal generator, and reassemble. This versatility, combined with its ergonomic trigger operation, makes it an indispensable tool for industrial environments.

How Does It Work?

The Vac-u-Gun’s functionality hinges on its reversible generator:

  • Vacuum Mode: When configured for vacuuming, compressed air (typically 80-100 PSIG) flows into an annular plenum chamber and exits through directed nozzles, creating a low-pressure zone that draws in surrounding air and debris. The material is then directed into a reusable bag or hose for collection.
  • Blow-Off Mode: In blow-off mode, the generator is flipped, and the compressed air is expelled through a large 1-1/4″ (32 mm) diameter outlet, providing a powerful stream for cleaning or drying surfaces.
  • Transfer Mode: By attaching a smooth-bore vacuum hose, the Vac-u-Gun can move lightweight materials over short distances, making it ideal for material handling tasks.

Applications Best Suited for the Vac-u-Gun

The Vac-u-Gun’s adaptability makes it a go-to solution for a wide range of industrial tasks. Here are some of its standout applications:

  1. Small-Scale Debris Cleanup – The Vac-u-Gun excels at vacuuming up sawdust, shavings, chips, or spills in workshops and manufacturing facilities. For example, a woodworking shop can use the Collection System to quickly clean up sawdust from workbenches, capturing it in the reusable bag without spreading it around the floor.
  2. Surface Cleaning and Blow-Off – In blow-off mode, the Vac-u-Gun is perfect for drying or clearing dust and dirty surfaces like electrical panels or machinery parts. Its large-diameter output ensures rapid coverage, making it a time-saver in fast-paced production lines.
  3. Material Transfer – When paired with a vacuum hose (as in the Transfer System), the Vac-u-Gun can move lightweight materials like polystyrene pellets or plastic granules over short distances. A bean bag chair manufacturer, for instance, could use it to transfer filling material from a bag to the product, eliminating the mess and tedium of manual scooping.
  4. Specialized Cleaning with the Deep Hole Vac-u-Gun Variant – For applications requiring the removal of chips from drilled holes or grooves—like in automotive part machining—the Deep Hole Vac-u-Gun variant offers a targeted solution. A small blow tube dislodges debris while the suction tube vacuums it away, all while containing flying particles for operator safety.

EXAIR’s Vac-u-Gun is more than just a tool—it’s a problem-solver. Whether you’re cleaning up a mess, transferring materials, or clearing surfaces, its technical design delivers efficiency and reliability in a compact package. For industries looking to boost productivity while keeping costs and maintenance low, the Vac-u-Gun is a worthy investment.

If you’re curious about how the Vac-u-Gun can fit into your operations, reach out to an EXAIR Application Engineer. With same-day shipping on stock items (orders by 2:00 PM ET), you could have it in hand by tomorrow—ready to tackle your toughest housekeeping challenges.

Jordan Shouse
Application Engineer

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EXAIR’s Knowledge Base

Published on by jasonkirbyLeave a comment

At EXAIR, we are dedicated to equipping our customers with the essential tools to address challenges and train their personnel through a diverse range of offerings, collectively referred to as the Knowledge Base. This resource is organized by various criteria to provide practical, experience-based solutions.

In our Knowledge Base, you will discover case studies that showcase how we have assisted customers in enhancing their processes, reducing compressed air consumption to save costs, and improving worker safety. Additionally, we provide a categorized list of frequently asked questions by product line, a collection of calculators designed to estimate potential savings, and various application examples to illustrate our impact.

We offer a collection of previously recorded webinars that you can access for free at your convenience. These sessions cover a range of topics, including the differences between inefficient and engineered nozzles, static generation, and methods for identifying and repairing leaks. Additionally, our video library features product demonstrations, informal content, and practical tips for maximizing the use of our products. We also provide Application Assistance and an Efficiency Lab, which facilitates tailored recommendations and performance comparisons.

Alongside the extensive resources found in the Knowledge Base, EXAIR boasts a team of skilled Application Engineers who possess expertise across a diverse range of industries and processes. It is likely that one of our engineers has encountered a similar application, and we are eager to assist you in finding the most effective solution.

If you have questions about our Knowledge Base, or anything regarding EXAIR and our products, please do not hesitate to reach out.

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