Tag: leak detection equipment

Understanding Pressure Requirements For Your Compressed Air System

Published on by Russ BowmanLeave a comment

One of the advantages to compressed air operated equipment is the ability to precisely “dial in” the performance by regulating the supply pressure. Consider an EXAIR Super Air Knife, for example. The flow & force can be adjusted from a “breeze to a blast” and any point in between, via a point-of-use Pressure Regulator. I know of users who operate them with a supply pressure as low as 5psig (that’s the “breeze”) and as high as 120psig (that’s the “blast”), depending on the requirements of the application.

EXAIR Stainless Steel Super Air Knives are popular in food processing applications (left to right): removing excess moisture prior to flash freezing of fish fillets, preventing clumping while packaging shredded cheese, and (my personal favorite) ensuring a consistent and even glazing of fresh, delicious doughnuts.

For a wide variety of typical industrial blowoff applications, a supply pressure of 80psig is a good place to start. So, it stands to reason that the compressed air header pressure will have to be at least 80psig. If the piping/distribution system is sized properly to carry the total amount of air flow you need to the points of use, though, it doesn’t need to be an awful lot higher than 80psig…and that’s a good thing. Here’s why:

Any fluid encounters friction as it flows through a pipe (or hose or tube) which causes a drop in pressure along every bit of the length of flow. The larger the pipe (or hose or tube) the lower the friction and hence, the lower the pressure drop. Now, that’s only important if you care about how much you’re spending on running your air compressor(s). Consider this:

We’ve got a customer that puts our Model 110042 42″ Aluminum Super Air Knives on machinery they make & sell to their customers. This Air Knife will use 121.8 SCFM when supplied at 80psig with the stock 0.002″ thick shim installed, and does the job quite well, most of the time. Some specific applications, however, need higher flow & force from the Air Knife, so our customer offers, as an option, the Super Air Knife with a 0.004″ thick shim installed. Since this doubles the air gap, it also doubles the air consumption. They’d plumbed the supply line to the Air Knife per the recommended in-feed pipe sizes from the Installation & Maintenance Guide:

Super Air Knife Kits include a Shim Set, Filter Separator, and Pressure Regulator.

Since the drop was less than 10ft long, they used a 3/4″ pipe, which was fine…until they installed the 0.004″ thick shim, which meant the air consumption doubled, to 243.6 SCFM. To get that much flow, at 80psig to the Air Knife, they had to increase their header pressure to 110psig, from the 90psig level at which they had been running. This was well within the operating parameters of their air compressor, but it made the compressor work harder, so it used more energy…and cost more to run. In fact, every 2psi increase in compressor discharge pressure results in a 1% increase in operating horsepower (source: Compressed Air & Gas Institute Compressed Air Handbook, chapter 4, page 8).

So, by increasing the discharge pressure by 20psi, the compressor’s power draw (and hence, operating cost) went up 10%. Now, I never found out what size their customer’s compressor was, but I DID look up prices for SCH40 black iron pipe, and for an 8ft length, the 1″ pipe was only $10-15 more than the 3/4″ pipe they were using. Since 243.6 SCFM is roughly 60HP worth of a typical industrial air compressor load (industry thumb rule says they use about 1HP to make 4 SCFM), we can assume that it’s at least a 75HP compressor. Using the following formula to calculate the operating cost while it’s drawing 80% of full load (while making a few reasonable assumptions):

Cost ($) = bhp x 0.746 x # of operating hours x $/kWh x % time x % full load bhp
motor efficiency

bhp = motor full load horsepower (frequently higher than nameplate HP but we’ll use nameplate 75HP to be conservative)
0.746 = conversion from hp to kW
# of operating hours (assume a month’s worth, 8 hours/day, 5 days/week, 4 weeks/month=800 hours)
$/kWh (assume $0.08/kWh)
% time = percentage of run time at this operating level (assume 85% of the time)
% full load bhp = brake horsepower as percentage of full load bhp at this operating level (assume 60HP load, 85%)
Motor efficiency = motor efficiency at this operating level (assume 95% fully loaded)

75HP x 0.746 x 800 x $0.08 x 0.85 x 0.85 = $2,723.29
.95

An additional 10% power draw changes the % full load bhp to 95%, and the cost for monthly operation is:

75HP x 0.746 x 800 x $0.08 x 0.95 x 0.85 = $3043.68
.95

That’s an extra $320.00 spent on running the compressor (per month) at 110psig discharge pressure, instead of an extra $15.00 spent on a larger pipe (one time cost) to run it at 90psig.

This is just one example of the effect of “artificial demand”, which is, essentially, wasted energy due to running your system at a higher pressure to compensate for undersized lines, leaks, intermittent high loads, etc. In addition to helping you specify the right supply line size for your compressed air operated products, we can assist with leak detection, intermediate storage, regulating supply pressures for differing loads, and replacing inefficient devices with engineered products. If you’d like to talk about any, or all, of that, give me a call.

Russ Bowman, CCASS

Application Engineer
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Adding Sound Levels Together to Determine Total dBA and Ensure a Safe Working Environment

Published on by Tyler DanielLeave a comment

Noise-induced hearing loss (NIHL) is one of the most common occupational diseases. This doesn’t occur overnight, but the effects are noticed gradually over many years of unprotected exposure to high sound levels. This is 100% preventable! Through proper engineering controls and personal protective equipment (PPE), NIHL can be prevented. It is irreversible, so once the damage is done there’s no going back. OSHA standard 19 CFR 1910.95(a) states that protection against the effects of noise exposure shall be provided when the sound levels and exposure time exceed those shown in the table below.

OSHA Chart

Intensity of the sound pressure level is expressed in decibels (dB). The scale is logarithmic; a 3 dB reduction cuts the sound level in half. A 10 dB reduction decreases it by a factor of 10, and a 20 dB reduction decreases the sound level by a factor of 100. To calculate the dB level, we use the following formula:

Sound SPL

Where:

L – Sound Pressure Level, dB

P – Sound Pressure, Pa

Pref – reference sound pressure, 0.00002 Pa

For example, normal conversation has a sound pressure of .01Pa. To calculate the dB level:

dB = 20 log10 (.01Pa/.00002Pa)

 = 54 dB

When designing a new blowoff process, it’s important to consider the sound levels produced before implementation. EXAIR publishes the sound level for all of our products for this very reason. If you’re implementing multiple nozzles, you’ll need to add the sound levels together. To do so, we use the following formula:

Sound Addition

Where:

L1, L2… represent the sound pressure level in dB for each source

A customer was using ¼” open-ended copper tubes for a blowoff application removing trim after a stamping operation. They had a total of (4) tubes operating at 80 PSIG. Not only were they VERY inefficient, but the sound level produced at this pressure was 94 dBA. To calculate the sound level of all (4) together we use the above formula:

L = 10 x log10(109.4+ 109.4 + 109.4 + 109.4)

L = 100 dB

At this sound level, permanent hearing loss begins to occur in just two hours of unprotected exposure. We recommend replacing the loud and inefficient copper pipe with our 1” Flat Super Air Nozzle, Model 1126. At 80 PSIG, the 1126 produces a sound level of just 75 dBA.

L = 10 x log10 (107.5 + 107.5 + 107.5 + 107.5)

L = 81 dB

At almost a 20 dB reduction, that’s nearly 100x quieter! Don’t rely on just PPE to keep your operators safe from NIHL. Replacing loud inefficient blowoff methods with EXAIR’s Intelligent Compressed Air Products will take it one step further in ensuring your creating a safe working environment for your employees.

Tyler Daniel, CCASS

Application Engineer
E-mail: TylerDaniel@EXAIR.com
X: @EXAIR_TD

Pressure Sensing Flow Meters

Published on by Jordan T ShouseLeave a comment

If you are looking to add some control to your compressed air system, one of the first things you need to do is understand the baseline for where your system is. This includes, of course, the volume of compressed air you are providing, but also the pressure at which your system is seeing as well. This is especially important when you have an application that is very pressure dependent like a CNC mill tool changer.

The Pressure Sensing Digital Flowmeters are available from 2″ Sched. 40 Iron Pipe up to 8″ Sched. 40 Iron Pipe.  As well as 2″ to 4″ copper pipes.  These will be read out and with additional data logger as well, so you can track the pressure over the course of every shift, and even days.

Generating a pressure and consumption profile of a system can help to pinpoint energy wasters such as timer-based drains that are dumping every hour versus level-based drains that only open when needed. A scenario similar to this was the cause of an entire production line being shut down nearly every day of the week for a local facility until they installed flowmeters and were able to narrow the demand location down to a filter baghouse with a faulty control for the cleaning cycle.

If you’re serious about getting the most out of your compressed air use, the very first step in EXAIR’s Six Steps To Optimizing Your Compressed Air System is literally a great place to start.

Six Steps to Optimizing Your Compressed Air System

Here are some blogs on the other steps!

Step #1- Step 1 – Measure your Air

Step #2- Step 2 – Finding and fixing leaks

Step #3- Step 3 – Use Efficient and Quiet Engineered Products

Step #4- Step 4 – Turn the air off while its not in use

Step #5- Step 5 – Install Secondary Receiver Tanks

Step #6 – Step 6 – Control the air pressure

If you would like to discuss the best digital flowmeter for your system and to better understand the benefits of pressure sensing, please contact us. To find out more, give me a call.

Jordan Shouse
Application Engineer

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Tool Changer Photo courtesy of Luke Gilliam via creative commons

Decibels and How to Calculate

Published on by Al WooffittLeave a comment

Most of us are familiar with the term decibels. We know that it is a measure of sound, and that a larger decibel value means a larger sound. But the details of how they are calculated, or how different values compare to one another are not as widely known.

The first thing to note about sound levels is that they are not measured on a linear scale. Rather, they are measured on a logarithmic scale. This means that decibel values are not as intuitive as maybe we would like. A sound of 20dB is actually 10 times more powerful than a sound of 10dB, and 30dB would be 100 times more powerful than 10dB. If the scale was linear, 20dB and 30dB would be 2 and 3 times more powerful than 10dB (like with mass, for example, 20kg is twice as much mass as 10kg).

You can see why this is the case with the formula for calculating sound levels, which is as follows:

Image courtesy of OSHA Technical Manual (OTM)
Section III: Chapter 5 Appendix B5

It is important to note that the sound pressure levels calculated with this formula are unweighted. When we want to know how loud something will sound to us, we need to take into account how the human ear perceives different frequencies. The basic effect of this is that low and very high frequencies are given less weight than on the standard decibel scale, but the exact weighting can be seen in the chart to the left. This weighted measurement is denoted as dBA or sometimes dB(A) as opposed to the standard dB for sound pressure levels. Some common sounds and their dBA level can be seen on the chart below:

Due to this logarithmic scale, adding two sounds together can also be quite counter-intuitive as well. Our Model 1100 Super Air Nozzle will produce a sound level of 74 dBA, but two side by side will produce a sound of 78dBA. The specifics of this calculation are explained in this blog here, but OHSA provides a quick and easy way to calculate, as shown in the table below:

Difference Between Two Levels to Be AddedAmount to Add to Higher Level to Find the Sum
0-1 dB3 dB
2-4 dB2 dB
5-9 dB1 dB
10 dB0 dB
From <https://www.osha.gov/otm/section-3-health-hazards/chapter-5>

Now that you know how to calculate sound levels, it is important to understand the dangers inherent in prolonged exposure to high levels of noise. OSHA Standard 29 CFR-1910.95 (a) shows the Maximum Allowable Noise Exposure:

If you would like to find out if you need to address the sound level in your facility, you first need to take a baseline reading of your various processes and devices that are causing the noise. EXAIR’s Sound Level Meter, Model 9104, can help you out. It is an easy-to-use instrument that provides a digital readout of the sound level (so you don’t have to mess with logarithms!) They come with a NIST traceable calibration certificate and will allow you to determine what processes and areas are causing the most trouble.

If you would like to discuss sound levels in your facility, or any of your other compressed air needs, give us a call!

Al Wooffitt
Application Engineer

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Photo of Ear auricle Listen by geralt Pixabay License