Category: Air Amplifier

Super Air Amplifier vs Fan

Published on by Al WooffittLeave a comment

One of the more common applications we work with is cooling. In most instances, the goal is to cool the part as quickly as possible. In order to cool faster, you would think that blowing the coldest air possible would be the best option. Our Vortex Tubes can produce air as cold as -50°F! However, in many instances, more effective cooling will be achieved through larger volumes of air. As long as the ambient air temperature is lower than the target temperature, larger volumes of ambient air will outperform a small volume.

Our Super Air Amplifier is a great option for producing large volumes of laminar (non-turbulent) airflow for minimal compressed air consumption. Using a Coanda profile along with a patented shim, compressed air exits the Amplifier in a manner that generates a low pressure zone, which helps pull in the surrounding ambient air. This creates an amplification ratio of up to 25 times! Due to the laminar output flow having the same speed and direction, it is very effective at removing heat from a target. It also helps keep noise levels down.

The most common, non-compressed air alternative to our Amplifiers is an electric fan. Fans utilize motors and blades to direct air towards their target. When air comes in from behind the fan, the blades push the air forward to the target. This action generates turbulent air flow, as well as a lot of noise. Due to the use of motors, there are parts that can wear out over time, leading to additional maintenance costs over the lifetime of the fan.

Ultimately, when it comes to cooling, what we care about most is how quickly a given solution will get the job done. Is a Super Air Amplifier going to cool faster than a fan? In the video below we put both options to the test. As you will see, the Super Air Amplifier is significantly faster:

If you have a cooling application that you would like to discuss, give us a call!

Al Wooffitt
Application Engineer

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Boosting Ventilation With Air Amplifiers

Published on by Russ BowmanLeave a comment

Entering a confined space comes with a number of risks:

  • Physical hazards: mechanical equipment, falling objects, structural collapse, etc. Historically, these account for about 20% of fatalities associated with confined space entry.
  • Engulfment hazards: that’s a less horrific way to say “buried alive.” These are similar to some physical hazards, except the danger is from asphyxiation instead of being crushed. A prime example of this would be a farmworker falling into a grain silo in such a way that their head is submerged in the volume of grain. About 11% of confined space entry fatalities involve engulfment accidents. EXAIR Line Vacs are actually used in emergency responses to these.
  • Atmospheric hazards: Without adequate ventilation, carbon dioxide can build up, displacing the oxygen that workers need to breathe. Toxic and flammable gases are in this category as well, and whether workers are asphyxiated or poisoned, failure to provide a safe atmosphere accounts for almost 60% of confined space entry deaths.

Before workers enter a confined space, permits are oftentimes required. Atmospheric monitoring and ventilation are key aspects of such permits: Monitoring to ensure an adequate level of oxygen and the reduction of toxic & flammable gases to safe exposure limits, and ventilation to make sure that happens. It’s generally recommended to have ventilation/exhaust equipment capable of providing 20 air changes per hour.

EXAIR Air Amplifiers are an easy & reliable choice for providing the required ventilation. With no moving parts to break or electrical components to fail, all they need is a supply of compressed air. So, how do we choose the right one? Since we know we need 20 air changes an hour, the first step is to determine the volume of the space. Let’s say we need to enter a 10ft x 6ft x 6ft tank:

  • 10ft x 10ft x 12ft = 1,200 cubic feet
  • 1,200 cubic feet of air X 20 changes per hour = 24,000 cubic feet of air to change per hour
  • 24,000 cubic feet/hour ÷ 60 minutes/hour = 400 cubic feet per minute

In this case, we could specify a Model 6042 2″ Aluminum Adjustable Air Amplifier, which uses just 21.5 SCFM @80psig to generate a total developed flow of 430 SCFM (see table above). Minus the 21.5 SCFM of compressed air flow, that means it’s drawing 408.5 SCFM in from the tank.

If additional airflow is required, the ring gap of the Adjustable Air Amplifier can be easily increased by threading the plug out of the body until the needed flow is achieved. A Pressure Regulator can also be used to ‘fine tune’ the compressed air supply, and hence, the ventilation flow.

EXAIR Air Amplifiers are a simple, low-cost way to move air, smoke, fumes, and even light materials. If you’d like to find out more, or if you have a potential application to discuss, give me a call.

Russ Bowman, CCASS

Application Engineer
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Intelligent Compressed Air: Two Different Products Called “Air Amplifiers”

Published on by Russ BowmanLeave a comment
A 2psi change in compressor discharge pressure equates to a 1% change in compressor power consumption.

They say that necessity is the mother of invention, so it’s no coincidence that mechanical means of compressing air came about in the early days of the Industrial Revolution, eventually becoming known as the “4th Utility” along with electricity, water, and gas. For most of the 20th Century, compressed air system pressure was commonly generated in the neighborhood of 100psig, although many modern industrial air compressors can be operated at 160 to 200psig. Operating an air compressor at higher discharge pressure increases the cost of operation, though, so it’s in EVERYONE ‘S best interests to run compressed air systems at the lowest pressure possible, that still gets the job done for all the air-operated gear in the facility.

So, what if most of your compressed air loads operate at 80-100psig, but one (or a handful) needs 120psig? Or 160psig? Or even higher? Increasing your compressor discharge pressure from 100psig to 160psig means you’re using 30% more power to run the compressor. That’s a LOT for one (or a handful) of operations.

Good news: the laws of physics say that pressure is the amount force applied to a specific area…as in pounds(force) per square inch, or psi. So, if we apply a certain pressure to a large diameter piston, and attach that with a shaft to another smaller diameter piston, the amount of force doesn’t change, but the area does, so the pressure on the other side of the smaller piston HAS to:

Let’s say the primary pressure (P1) is 100psi, and the primary piston (D1) is 4″ in diameter, with a surface area of 12.56 in2. That means the force applied to the primary piston (D1) is : 100 lbf/in2 x 12.56 in2 = 1,256 lbf.
This is the same force applied to the air on the other side of the secondary piston (D2), which has a diameter of 2″ and a surface area of 3.14 in2. Since pressure is force divided by area, that 1,256 lbf applied to 3.14 in2 results in a secondary pressure (P2) of 400psi.

This is the basic theory behind how air (pressure) amplifiers – also known as booster regulators – work. Essentially, you’re trading compressed air flow (into the larger cylinder) for pressure. Now, if EVERYTHING you operate needs higher pressure, the best way to do that is to increase the compressor discharge pressure. But if you only have one, or a few, loads that need higher pressure, the increase in air consumption for those loads is likely less costly than compressing the air to a higher pressure than is needed for the majority of your loads.

The other type of air amplifier is the one that EXAIR manufactures – it’s an air FLOW amplifier, and here’s how it works:

In this case, we’re trading pressure for flow, and getting a much higher total developed air flow rate than just the amount of compressed air it uses. Not only does the entrained air make them incredibly efficient, it also develops a low-velocity boundary layer that attenuates the sound level of the total air flow. They can be used for cooling, drying, cleaning, ventilation, fume exhaust, and even material conveying, especially if the material to be conveyed is very light, or already airborne.

With (16) models to choose from, EXAIR Air Amplifiers are a quick and easy way to provide a tremendous amount of cooling air flow from a compact, lightweight product.

EXAIR Air Amplifiers come in a range of sizes, from 3/4″ to 8″. Super Air Amplifiers are lightweight, durable aluminum, and Adjustable Air Amplifiers are available in aluminum or 303SS. If you’d like to find out more about them, give me a call.

Russ Bowman, CCASS

Application Engineer
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Finding the Right Intelligent Compressed Air Product

Published on by Russ BowmanLeave a comment

I had the pleasure of talking with a customer who had purchased a Model 6063 1-1/2″ Stainless Steel Line Vac the other day. They were building chemical processing machinery, and needed to move vapor into a condenser for reclamation of the fluid. The Line Vac was doing exactly what they needed it to do, and with a supply pressure regulated down to 12psig, at that. Their question was, how do they quantify the flow rate?

Because the Line Vac generates a moderate level of vacuum head with a moderate vacuum flow, they’re ideal for drawing in bulk solid material and conveying it from one place to another. They’ll do the same with airborne dust, vapors, and gases, but…

Because they’re made for conveying bulk solids, our published performance data for the Line Vacs doesn’t address total developed airflow. However, because our Air Amplifiers are made for moving air (and anything that might be suspended in the air or already airborne), we DO publish airflow performance data for them. And it provides a GREAT segue for situations like this, when the only thing that can do a better job than one EXAIR product is another EXAIR product!

…Air Amplifiers, while similar in function to the Line Vacs, generate a high vacuum flow with a low vacuum head. This makes them the better choice for moving air & airborne dust, vapors, gases, etc.

In this case, the machine designer replaced the 1-1/2″ Stainless Steel Line Vac with a Model 6040 3/4″ Stainless Steel Adjustable Air Amplifier. It’s got a 1-1/2″ OD inlet plenum, so it was a ‘drop-in’ replacement for the 1-1/2″ Line Vac, which was plumbed in with a 1-1/2″ ID hose. When they regulated the supply pressure to 25psig, they were able to replicate the vapor carryover to the condenser at the specified rate, and even cut the already low compressed air consumption from 9.3 SCFM @12psig (for the Line Vac) to 3.7 SCFM @25psig (for the Air Amplifier).

As an EXAIR Application Engineer and a Certified Compressed Air Systems Specialist, I’m here to make sure you get the most out of your compressed air system. If that involves using a product other than the EXAIR Intelligent Compressed Air Product that you may have initially selected, I’m not going to be shy about telling you that. But, there’s a good chance that the more ideal solution is going to be another EXAIR Intelligent Compressed Air Product. If you want to talk about compressed air…so do I! Give me a call.

Russ Bowman, CCASS

Application Engineer
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