Water Transfer Testing-Jet Siphon Flow Rates

Fairmount Fire Company

Water Transfer Exercise

9/24/2013

About a week and a half ago a good friend invited me along to observe a series of tests of the potential to transfer water using jet siphon devices.  The following results are our non-scientific data that were collected.  It was a great opportunity to get some baseline data on a topic that has little published information.

The Fairmount Fire Company protects a portion of Washington Township, in Morris County NJ.  Their response district includes some areas with hydrants, but is largely unhydranted.  The company operates two engines a tender and a support rig.  You can learn more about them at www.34fire.org

The goals of this drill were to;

1. Test the potential flow rate of jet siphon devices using one and two devices
2. Test the potential to transfer water up a grade through a jet siphon device

The setup for the first part of the test included;

• (1) 3500 Gallon folding tank (Tank #1)
• (1) 2000 Gallon folding tank (Tank #2)
• (1) Kochek “JS60” power jet siphon device connected to (2) 15’ x 6” suction hose
• (1) Kochek “JS60 power jet siphon device connected to (2) 10’ x 6” suction hose
• Clamp-on hose bracket with (2) 2 ½” hose connection elbows on the 3500G tank

Preparation for tests #1-4

• Two tanks were set up approx 3-4 feet apart, on flat asphalt, with a slight incline
• The 3500 gallon tank sat on the “downhill” side
• The 2000 gallon tank sat slightly “uphill” from the larger tank
• E34-62 pumped its 1000 gallons of booster tank water into the 3500 gallon tank through the clamp on hose bracket.
• Once the booster tank had been emptied, a mark was made on the sidewall of the tank indicating the 1000 gallon water level
• Using a tape measure, corresponding marks were added for 500, 1500 and 2000 gallons along the tank sidewall.  It should be noted that the 3500 Gallon tank was only able to hold about 2000 gallons due to the pitch of the parking lot
• (2) 15’ sections of hard sleeve were connected together and the Kochek jet siphon was attached.  The intake for the siphon was placed at the lowest “downhill” point in the 3500 gallon tank
• 50’ of double jacket-rubber lined hose was connected from the pump panel discharge of Tender 34 to the jet siphon
• A stopwatch was set to 00:00
• After each test, water was pumped back into tank #1 by E34-62, utilizing the clamp-on 2 ½” hose connection bracket.
• Time was recorded at each 500 gallon interval 

Preparation for test #5

• 3500 Gallon tank on the "downhill side"
• 2000 Gallon tank on the "uphill side"
• 50' of 6" hard sleeve with an approximate 7' elevation

Test #1

Objective: Determine flow rate of water from nozzle of jet siphon at different pump pressures through 50’ of 1 ½” hose.

The “JS60” Siphon used

The jet siphon was evaluated and noted to have a single ¾” nozzle orifice with a 1 ½” NH hose connection.  It has 6” male NH thread to connect to the hard sleeve hose.  A check of a smooth bore discharge chart shows the ¾” nozzle listed and therefore we can deduct the measurements taken with the handheld pitot gauge are generally accurate.

Water transfer back to original tank

The jet siphon was held by a firefighter and aimed into the portable tank.  The handheld pitot gauge was used to measure the pressure of the stream exiting the nozzle.

Results of Test #1

The flow test resulted in the following performances. 

• PDP - 75 PSI = 50 PSI nozzle pressure or approximately 120 GPM
• PDP - 100 PSI = 70 PSI nozzle pressure or approximately 140 GPM
• PDP of 125 PSI =  80 PSI nozzle pressure or approximately 150 GPM
• PDP of 150 PSI = unknown nozzle pressure – not tested

It should be noted that the sharp 90 degree bend of the nozzle pipe in the device results in a very broken stream, with fluctuations on the pitot gauge.  The values measures represent a good “average assessment” while holding the pitot gauge in the stream for approx 10-15 seconds.

The following table lists the flow data collected

PDP                 Flow                 Friction Loss (Hose) Approx.     Tip PSI             Device Loss (estimated)

75 PSI              120 GPM          34.6 PSI/100’ or 17.3 PSI/50’      50 PSI Tip         7.7 PSI

100 PSI             140 GPM          47 PSI/100’ or 23.5 PSI/50’         70 PSI Tip         6.5 PSI

125 PSI             150 GPM          54 PSI/100’ or 27 PSI/50’           80 PSI Tip         18 PSI

150 PSI             160 GPM          61.4 PSI/100’ or 30.7 PSI/50’      100 (estimate)   19.3 (estimate)

Test #2

Objective: Determine flow rate of single jet siphon to transfer 1000 gallons of water from one folding tank to another at 100 PSI pump discharge pressure.

The 3500 Gallon tank was marked at 500 gallon intervals with the top mark being 2000 gallons. 

The stopwatch was started when the discharge valve was opened.  The water level started at the 2000 gallon mark.  When the water level reached the 1500 gallon mark the time was recorded.  It was recoded again at the 1000 gallon mark.

The jet siphon was attached to (2) 15’ sections of 6” lightweight suction hose

 Tank Markings made using a tape measure and a measured quantity of water (1000 Gallons)

Results of Test #2

With a pump discharge pressure of 100 PSI the following results were achieved.

Water level at the 1500 Gallon mark (500 gallons transferred):      1:27

Water level at the 1000 Gallon mark (1000 gallons transferred):    3:22

Average flow rate for 1000 Gallons         4.95 Gallons/second or 297 GPM

Average flow rate for first 500 Gallons    5.74 Gallons/second or 344 GPM

Average flow rate for last 500 Gallons    4.34 Gallons/second or  260 GPM

The discharge gauge readings between the main pump and the line gauge were virtually identical at the 100 PSI test

Summary of Test #2

It appeared that the first 500 gallons of water transferred at a higher flow rate, while the last 500 gallons of the test transferred at a lower rate.  The difference in flow between the first and last 500 gallons was an 84 GPM decrease.  We felt that because the siphon action does not use the advantage of positive pressure that as the water level in the tank lowers that it requires more energy to raise the water up the suction hose, thus showing the decline in flow. 

The average flow of 297 GPM also did not account for “prime time” of the siphon, so the actual true flow rate might be slightly higher

Because the known flow of the jet siphon nozzle at the 100 PSI pump pressure is approximately 140 GPM, the average net flow rate of the transfer device is actually 157 GPM.  This could be considered the flow rate of a single 1 ¾” handline

Test #3

Objective: Determine the flow rate of two jet siphons to transfer 1000 gallons of water from one folding tank to another at 100 PSI Pump discharge pressure

The 3500 Gallon tank was marked at 500 gallon intervals with the top mark being 2000 gallons. 

The stopwatch was started when the discharge valve was opened.  The water level started at the 2000 gallon mark.  When the water level reached the 1500 gallon mark the time was recorded.  It was recoded again at the 1000 gallon mark.

The first jet siphon (#1) was attached to (2) 15’ sections of 6” lightweight suction hose.  The 50’ section of 1 ½” hose was connected to the pump panel discharge of Tender 34, shown below.

The second jet siphon (#2) was attached to (2) 10’ sections of 6” lightweight suction hose.  The 50’ section of 1 ½” hose was connected to the rear discharge of Tender 34.  The discharge is located to the lower right of the dump chute.

       

The photos show the piping and location (lower right) of the rear discharge on T34

Results of Test #3

With a pump discharge pressure of 100 PSI the following results were achieved.

Water level at the 1500 Gallon mark (500 gallons transferred):                  1:02 (62s)

Water level at the 1000 Gallon mark (1000 gallons transferred):                2:12 (132s)

Average flow rate for 1000 Gallons         7.57 Gallons/second or             454 GPM

Average flow rate for first 500 Gallons    8.06 Gallons/second or             483 GPM

Average flow rate for last 500 Gallons    7.14 Gallons/second or              428 GPM

Summary of Test #3

It appeared that the first 500 gallons of water transferred at a higher flow rate, while the last 500 gallons of the test transferred at a lower rate, as in test #2.  The difference in flow between the first and last 500 gallons was a 55 GPM decrease.  We felt that because the siphon action does not use the advantage of positive pressure that as the water level in the tank lowers that it requires more energy to raise the water up the suction hose, thus showing the decline in flow. 

The average flow of 454 GPM also did not account for “prime time” of the siphon, so the actual true flow rate might be slightly higher

Because the known flow of the jet siphon nozzle at the 150 PSI pump pressure is approximately was not tested, the average net flow rate of the transfer devices is estimated at 174 GPM.  This could be considered the flow rate of a single 1 ¾” handline.

After reviewing the piping on Tender 34, we noted that the rear discharge contains several sharp bends, and that the pressure gauge line is affixed close to the pump.  It can be deducted that because of this, that jet siphon #2 was somewhat underpowered due to pressure loss in piping.  In addition, due to the difference in length of the two hard suction lines it can be deducted that there may have been a slightly lower level of efficiency in the longer of the two lines.  There were (4) 90 degree elbows and (2) 45 degree elbows identified within the pump house.  It is assumed once the piping reaches the last visible bend that it runs straight to the rear along the frame, but this was not certain.

The flow rate of approximately 280 GPM (140 GPM ea.) is required to support the two jet siphon devices, and thus makes this water unavailable for the fire site.  This must be considered in the pumps total capacity, especially since operating at draft as well as the required pump pressure (100 PSI) to achieve the flow.

Test #4

Objective: Determine the flow rate of one jet siphons to transfer 1000 gallons of water from one folding tank to another at 150 PSI pump discharge pressure

The 3500 Gallon tank was marked at 500 gallon intervals with the top mark being 2000 gallons. 

The stopwatch was started when the discharge valve was opened.  The water level started at the 2000 gallon mark.  When the water level reached the 1500 gallon mark the time was recorded.  It was recoded again at the 1000 gallon mark.

The jet siphon (#1) was attached to (2) 15’ sections of 6” lightweight suction hose.  The 50’ section of 1 ½” hose was connected to the pump panel discharge of Tender 34

Results of Test #4

With a pump discharge pressure of 150 PSI the following results were achieved.

Water level at the 1500 Gallon mark (500 gallons transferred):                  1:11 (71s)

Water level at the 1000 Gallon mark (1000 gallons transferred):                2:18 (138s)

Average flow rate for 1000 Gallons         7.24 Gallons/second or             434 GPM

Average flow rate for first 500 Gallons    7.04 Gallons/second or             422 GPM

Average flow rate for last 500 Gallons    7.46 Gallons/second or              447 GPM

Summary of Test #4

It appeared that the first 500 gallons of water transferred at a lower flow rate, while the last 500 gallons of the test transferred at a higher rate, as compared to the other tests.  This represents an inverse result to the previous pattern. The difference in flow between the first and last 500 gallons was a 25 GPM increase.  As stated, this is the opposite result of previous tests.  We can theorize that the higher velocity of water from the jet may have impacted this result, but have no other data to explain this difference.

The average flow of 434 GPM also did not account for “prime time” of the siphon, so the actual true flow rate might be slightly higher

The estimated flow of the jet siphon nozzle at the 150 PSI pump pressure is approximately 167 GPM, the average net flow rate of the transfer devices is actually 267 GPM.  This could be considered the flow rate of a single 2 1/2” handline or two 1 ¾” handlines.

Test #5

Objective: Determine the flow rate of one jet siphon to transfer 1000 gallons of water from one folding tank to another at 150 PSI Pump discharge pressure up an approximate 7’ elevation.

The 3500 Gallon tank was marked at 500 gallon intervals with the top mark being 2000 gallons. 

The two tanks were 3500 gallons each.  The lower tank was filled to capacity; the upper tank retained its water level markings.

50 total feet of hard sleeve were connected together (2) 10’ and (2) 15’ sections

E34-62 was connected to a 6’ low level strainer in tank #2 (uphill tank) and had approx 500 gallons of on board tank water.  The level of water in tank #2 was at the top of the opening to the strainer, and unsuitable to draft at the start of the test.

The stopwatch was started when the discharge valve on E34-62 was opened.

Test #5

Results of Test #5

Water was discharged from the 6” hard sleeve into tank #2 (uphill), but it was noted to have a low volume, and did not fill the entire hose coupling opening.

After exhausting approximately 500 gallons of remaining tank water, E34-62 was unable to establish an effective transfer and the operation stopped.

Summary of Test #5

The test failed.

While attempting to prime the siphon, E34-62 operator increased pump pressure to near 200 PSI, with no appreciable results.  It was also noted that tank #1 (downhill) began to overflow, leading us to believe that the tank water from E34-62 was simply being exhausted into this tank and backflowing out of the siphon. A small stream of water exited the uphill end of the suction hose, but never gained enough water to establish a draft with the low level strainer.

We believe that the action of the jet siphon is limited to very slight elevation differences.  It would seem logical that because the action of the siphon it requires more energy to “prime” itself and flow than if the water were being pumped through the hard sleeve.  With that conclusion, we felt that dump site setup is critical when elevation is a factor and that the following options exist in such a situation;

• Portable pumps
• Drafting out of tanks directly and pumping back into other tanks

Overall Conclusions

After running the previous tests, we came to a few conclusions, which are listed below.  Understanding that without additional test gauges and more precise testing parameters, that the results have a known “approximation” built in, however, we can still consider the data is fairly consistent to use for “real world” purposes.

• Regarding the pressure to pump the jet siphons at, we felt that the best results were at the 150 PSI PDP and that a flow of 125-150 PSI PDP will yield best results in most cases
• Regarding how many jet siphons to use for water transfer, we felt that no less than two should be used as a standard practice between each tank
• Regarding the hose supplying the jet siphons, we used 1 ½” hose, 1 ¾” hose may yield better performance due to lower friction loss
• The use of the primary fireground supply pumper for water transfer beyond 2-3 jet siphons will impact its ability to deliver higher volumes to the fire scene.  With a flow of 160+/- GPM per siphon, this can add up quickly.  The operator should consider the flow of a jet siphon as equivalent to a typical 1 ¾” handline when factoring in total water supply.  Also, this water being used in each siphon is “recirculated” and never delivered to the fire, hence why we mentioned the “net” flow of each siphon.
• Using a separate pumper for water transfer may be a preferable option at large scale fire events, to allow the primary supply pumper to flow its best possible capacity to the fire site.
• When elevation is an issue, water can be transferred downhill, but not uphill beyond slight elevations when using jet siphons.  Dump site setup should consider this factor
• The discharge end of the hard sleeve must remain above the static water line in the folding tank, failure to maintain this position will result in high likelihood of back flow, as when the flow stops from the jet, the transfer will tend to reverse itself and return the water back to the original tank.
• Portable tanks on uneven ground will not hold their capacity, and additional tanks may need to be deployed on inclines to compensate for the lowered overall capacity
• You can mark the liquid level of folding tanks, but doing so must be done on level ground and there must be an understanding that if the tank is uneven that the level will be inaccurate.  One way to make this issue more apparent is to mark opposite sides and compare the levels.  If nothing else, it serves to indicate an approximate liquid level, as most fires don’t happen on flat, level ground.
• Water supply officers have a dity to collect additional suction hose, strainers and jet siphon devices from tanker and engine companies assigned to the operation, in order to be able to build an effective dump site.  Be familiar with thread size of hose and appliances used by mutual aid companies.

At the time we ran this rtest, we had no good information reporting the potential performance of jet siphons.  We were made aware that www.gotbigwater.com did some comprehensive tests in 2012, which you can find on their site.  http://www.gotbigwater.com/content/data/file/Jet%20Siphon%20Flowtests.pdf

Fairmount Fire Co. should be commended for quickly unloading and setting up all the required equipment and taking the time out of their evening to run these tests.  -Mike G.