Monthly Archives: March 2013

Is it The Pump or The Mainline Size That is Effecting the Performance of Your Tubing System?

Les Ober, Geauga County OSU Extension

           When you start to install a vacuum tubing system you need to understand a few basic principles that determine how air moves through a mainline. First you must consider the line loss. Line loss is caused by the friction of air moving through the line. A general rule of thumb is that the narrower the diameter of the mainline, the slower the air removal at long distances.   The line will restrict the pumps ability to quickly remove vacuum and recover from leakage. If you have a 1000 foot, 1 inch mainline attached to a 60cfm pump you will lose 50% of you CFM’s within the first 200 feet. If you attach the same pump to a 2” line you will lose 50% of your CFM at 1500 feet. Air moves easier through a larger diameter line.

You need to consider how a vacuum pump works. The measure of vacuum pumps efficiency is not how many inches of mercury it can obtain but how many cubic feet of air it can remove from the line in one minute. Remember even the smallest vacuum pump can remove the air from an air tight system and obtain high vacuum if you give it enough time to work. Also remember there is no such thing as an air tight maple tubing system, ability to recover from leakage quickly is critical.  Bigger pumps can remove air from the line faster but only if that air can move down the mainline quickly. If the diameter of the mainline is too small the air flow will be restricted by line loss.

Using the same 1000 ft. mainline, how many taps will it run? Let’s consider a 1 inch line, 1000 feet long hooked to a 60CFM pump. The 1 inch line will only allow 8 cubic feet of air to move through the line in one minute’s time at 1000 feet. If you follow the rule of 1 CFM for every 100 taps that would mean that you could not exceed 800 taps on that line, even though you have a vacuum pump capable of running 6000 taps. The only way to solve this problem is to go to a larger diameter line. If you move up to a 1 1/4 line of the same length hooked to the same pump you would have 12 CFM available at 1000 feet into the woods. You could theoretically run up to 1200 taps on this line. The major problem here is that many producers feel that they can solve their vacuum problems by buying a bigger vacuum pump. The truth is that at 1000 feet, with a 1 inch line, hooked to a 15 CFM, pump is capable of transferring 7 CFM.  If you replace the smaller pump with a much larger pump (60 CFM) it will only be able to transfer 8 CFM. A larger pump under these circumstances will not transfer any more CFM’s. 

               Another factor to consider is that most modern vacuum pumps are capable of maintaining a high level of hg mercury or inches of vacuum. Once a leak develops the vacuum level declines. At that point it is up to vacuum pump to overcome that leak by removing the incoming air. The pump must be able to do the job quickly to maintain an optimum level of performance (high vacuum) . As demonstrated in the above example a big pump can only be as efficient as the line capacity behind it.

               Up to this point we have only considered air flow through an empty line with no sap in it. What happens when we add sap? The optimum goal is to maintain 60% air and 40% liquid inside the vacuum line. What happens during peak flow when the ratio is often reversed? Under low flow conditions there is very little liquid inside you mainline and air can move freely. Under peak flow conditions sap builds up and air blockage often occurs. This blockage could be in the form of waves or even worse slugs of sap that seal off a portion of the line. This is real problem especially on slopes of 2 % or less. The solution to this problem, especially on flat ground or where large volumes of sap are entering the primary mainline from secondary main lines is a dual-line conductor or wet dry line. The bottom line conducts the sap and the top line removes the air from the system. The bottom line is sized based on its liquid capacity and the top line is sized based on air flow and CFM capacity. When figure the CFM capacity for a Wet-Dry system only consider the capacity of top line. The advantage of a wet-dry system is that you should never have liquid in you top line, that means that it will transfer air at full capacity and the bottom line will have more capacity to transfer sap. To get a more in-depth description of how to install a vacuum system, including line loss charts for both single and wet-dry mainline purchase a copy of the New York State Maple Tubing and Vacuum System Notebook from Cornell University, Stephen Childs Author.

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Vacuum an Explanation

Les Ober, Geauga County OSU Extension

 The concept of vacuum is the exact opposite of what most people think of when they see a pump and some lines. Most people think of air being pushed though a line, similar to a compressor with an air line. Air can be compressed to an infinite level as long as what is holding that air does not explode. With vacuum it is the exact opposite .Vacuum is pressure based on the force that the earth’s atmosphere exerts on all of us. This amounts to about 15 pounds per square inch of surface or 29 inches of mercury. This pressure is also referred to as barometric pressure. As the atmosphere fluctuates it will go up and down with atmospheric air movement (weather fronts). If you remove air from a container you will produce a vacuum inside that container. That lack of air creates a negative pressure that is measured in inches of mercury (hg.)  and will never exceed the outside barometric pressure.  As molecules of air are moving toward the pump and that air is ejected at a volume over a period of time. In this case Cubic Feet of air per Minute (CFM) . The capacity of the pump will determine how fast this will happens.  What we are trying to create inside our sap lines is the absence of air or a perfect vacuum.  Most producers grasp these basic concepts they also realize that there is no way to maintain a perfect vacuum inside their sap lines. Damage from wildlife and age introduces air into the system. Even the tree allows air to be introduced. For this reason we always allow for 1 CFM of air movement for every 100 taps. The problem with most systems is that we are getting way more air into the system than we want. This puts a greater burden on the pump to remove the air. The speed at which this is accomplished is largely determined not only by pump capacity, but how the tubing system is constructed. Line length and diameter in relation to the pump and the amount of liquid in the lines has as much to do with it as pump size. Couple this with the fact that most producers are attempting to run at high vacuum ( as close to the daily barometric pressure as possible). The problem with this is that it is counterproductive to pump efficiency. To go from 12 to 15” vacuum requires 20% more system capacity, 12 to 18”Requires 50% more system capacity and from 18 to 20” requires 80% more capacity. Research says you can get more sap per tap, up to 50 % increase. However, this greatly increases the demand on your pump and everything behind the pump has to be in optimum condition. You can see in one short paragraph there is more to running a vacuum system than hooking a line to a pump. 

               The best way to approach designing a vacuum system is to start with the tubing system and put a pump in place that will run that system. To do this, you need to determine how many taps will be on each mainline.  You need to know the slope of those mainlines. Sap flowing in a relatively flat wood will move more slowly than sap moving down a mountain side. Each line has a capacity for liquid it is conducting. For example a 1 inch line on gravity will conduct 50 gallons per hour on a 2% slope and 75 gallons per hour on 6% slope. Remember that you want no more than 40% of the space inside the tubing holding liquid. The rest of space is needed to move air. The vacuum line is dual purpose, but its main function is air movement. If the sap level rises to the point that it blocks that air movement then the vacuum level quickly drops off. This along with excessive leakage is the main reason for vacuum level drop from the pump out into the woods. Using too small a diameter line will result in lines running full of liquid and a drop in vacuum.  One of the best ways to overcome this problem is to use dual-line conductors, using the top line for air movement and the bottom line for liquid. The use of this type of system is vital in flat woods with very little slope. Getting your lines sized correctly is the first step in creating an efficient vacuum system. In the next post we will discuss the importance of vacuum line sizing and distribution.

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