Why An Air Prep Is So Important For Blasting Success
In this insight we’re going to explain what an Air Prep does, how it works, the common problems experienced when working without one – and why other market solutions, don’t deliver at the same level as this air prep.
What it does:
First – an air prep simply cools and dries the hot moist air coming from your compressor. On planet Earth there exists no atmospheric condition as 0% humidity. All air contains some degree of moisture. As corrosion control experts, your end goal – both during and after the project, is to prevent moisture from making contact with the steel surface. At least minimize this to the degree you are able. An air prep moisture removal system maximizes the odds of you accomplishing this goal.
How it works:
Let’s start with your air compressor. This equipment basically compresses 7 cu ft of air down to a single cu ft. That’s what creates the pressure. In so doing it also compresses whatever moisture is in that 7 cu feet and transfers it into the 1 cu ft used for blasting. Can you see the problem?
Each cu ft of air now contains 7x the moisture of the surrounding ambient air. And this will be concentrated and directed first into your blast pot full of abrasive and then onto the steel surface.
Our best air prep condenses and reduces this moisture in 3 separate phases – before the air ends up in your blast stream.
PHASE 1: First, the air from the compressor enters an inlet moisture separator. Basically, this acts like a drop out box and the heaviest moisture molecules fall out of the air stream. This is the first line of defense.
PHASE 2: Air coming from the compressor is extremely hot. Around 200 degrees F /90 degrees C. After passing through the inlet moisture separator, it then runs through a radiator to help cool it. Cooling the air causes water vapor to condense into water molecules. We want the vapor to condensate because that’s how we’re going to separate it from the air in the next phase.
PHASE 3: After being cooled in the radiator, the compressed air then enters the large tank of the air prep where it immediately expands and spins around the vessel – causing the heavier water molecules to separate from the air flow and drip to the bottom of the tank.
So those are overviews of what an air prep does and how it works…
Here are those 5 common headaches an air prep remedies. These are common problems found on basically every jobsite we visit, that isn’t using an air prep.
The first 3 problems all deal with moist abrasive.
Let’s imagine the hot, moist compressed air travels directly from the compressor into the blast pot where this moisture is absorbed into the abrasive… in essence dampening the abrasive.
Problem: Like wet sand, damp abrasive clumps.
Your blast pot is supposed to behave like an hour glass. The abrasive falls from the pot through the metering valve and into the blast stream, by gravity. Just like sand in an hour glass.
When the abrasive gets moist, it clumps, and it doesn’t fall naturally from the pot through the metering valve.
This is an extremely common problem. Almost every blaster has experienced this situation. Not enough abrasive enters the blast stream and blasting either suffers or halts.
Now that may seem like the problem – but that’s not even one of the 3 problems we’re exposing.
The 3 problems occur because of the solution the blasters take to increase the abrasive flow. They choke the pot!
To get the abrasive to fall into the air stream they simply lessen the pressure in the pusher-line which creates an imbalanced positive pressure in the pot. Aha- they think. The pot’s pressure is greater and will FORCE that abrasive into the blast stream.
And that does work.
However, it works at the expense of 3 very costly side-effects.
You use more abrasive – actually waste it – which costs money, causes more downtime refills to the pot, and because you use more abrasive, it costs more to cleanup and dispose. Even if you aren’t constantly choking the pot, your operators are compensating for moisture by opening the abrasive valve more than they’d need to if you had an air prep. We have seen up to 15% abrasive savings with an air dryer in dry desert climates!
The positive pressure of the pot, now forces that abrasive through your metering valve – which causes premature wear – costing you either downtime, increased maintenance & repair, or in time, both.
And finally – by choking the pot and reducing the pusher-line pressure, you are now blasting with reduced pressure. And for every 1psi of pressure loss, you can expect a 1.5% efficiency loss. A 10 psi reduction, simply to force the damp abrasive into the blast stream equals 15% inefficiency for the remaining time that lower pressure stays intact. If you don’t think this is happening on your jobsite, we invite you to inspect for yourself. Globally, we visit thousands of jobsites each year and this situation is rampant across every country we’re in.
And that’s just 3 problems!
Problem #4 is you’re smashing moist abrasive into the substrate – when your end goal was to reduce moisture coming into contact with the surface. Without an air prep, you just increased the probability of flash rust.
And a 5th problem which seems so remote, most don’t even consider it, is when you’re blasting in very cold temperatures. The moisture traveling through the compressed air finds it way not only to the steel surface, but also inside your lines, hoses, and valves. Even your pneumatic deadman controls. When you shut down for the day, that moisture stays inside, potentially freezing overnight and causing complications the next morning on start-up.
You reduce or eliminate all these problems by minimizing the moisture in the compressed air. And the best way to do that is by using an air prep.
Common Objections: “But I use a moisture separator.” “My compressor has an in-built after-cooler.” “I work in mild climates.” “I’ve used an air prep and it drops my pressure!”
Let’s tackle these objections one by one.
A moisture separator only removes the incoming heavy moisture, it does nothing for moisture at the vapor level. Also, the diameter of these cylinders don’t really facilitate much expansion to shake out the moisture. These are better than nothing. But kind of like putting a Band-Aid on a bullet hole.
In-Built Compressor After-coolers. First, we have found they can lower your pressure up to 15 psi – that’s a 22% drop in efficiency. Our air preps typically have a 3psi drop when the air expands in the vessel to shake out the water. Second, we decided to test the efficacy of an in-built after-cooler by attaching it to one of our airpreps. We wanted to see if the air prep could catch any remaining water that escaped the compressor. The video you’re about to see was shot on a sunny day in a mild humidity climate — so not only does it address the In-built After-cooler objection, it helps cover the mild climate defense as well.
That leaves the final objection – an air prep drops my pressure. This is true. However, an inbuilt after cooler can drop your pressure by 15 psi. A regenerative air dryer can drop it by 10-25 psi. Our leading air preps result in an expected 3psi drop. If your concern is pressure loss, we have a feeling you haven’t tried ours yet.
And finally, the best news is we love to rent air preps. We invite everyone to try before they buy. Just give us a call. You team has a tough job to begin with. An air prep can remove some of their common headaches.
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