Taco book is in my truck but guess a 007 would work you have very little head and 007 is available in a zoning model.
Here is a pump selector guide from Taco. It may be helpful.
https://www.taco-hvac.com/uploads/FileLibrary/SelectingCirculators.pdf
Based on what you provided, for your flow rate, the pipe is too small, that is why the head is coming out very large. For water systems we try to keep water velocity under 7 ft per second, per the Taco chart the hydronic heat range is 2 to 4 feet per second. For 1/2" pipe the flow rate for that range of fluid velocity is 1.25 gpm to 2.5 gpm. To use a flow rate of 8.3 you need at least a 1 inch pipe, for a velocity of 3.4 feet per second. For your loop length you will need to be on the low end of the flow rate to get one of these Taco pumps to work properly due to the head loss in the pipe. You are probably looking at an 009, 0011 or 0013. In order to help you with those calcs we would need to also know what fluid you are using, the average fluid temperature, and what your expected temperature drop is.
Single zone?
With your 1/2" Pex, 50/50 mix, and loop at 272 feet (use about 281 feet, to account for 4 90 degree bends and a branch tee), calc is as follows:
H=0.0374*1.582*281*4.970 = 82.6 feet of head (using flow rate in 1/2" pex of 2.5 gpm, velocity slightly higher than 4 feet per second, none of the Taco pumps can do this.
H=0.0374*1.582*281*3.364 = 55.9 feet (flow rate of 2 gpm)
H=0.0374*1.582*281*2.033 = 33.8 feet (flow rate of 1.5 gpm, slightly higher than 2 feet per second velocity)
The Taco 009 circulator can do this, but when you back up and look at your system, the change in temperature is:
f=Q/(450*T)
1.5=72000/(450*T)
T=106.7 degrees
So realistically what would happen is
1.5=Q/(450*20)
Q=13,500 BTU delivered
1.5=Q/(450*30)
Q=20,250 BTU delivered
In other words due to your tube size, you can't circulate enough water to deliver all the heat you need. The flow rate should be around 8 gpm with a pex tube size of 1 1/4" for a 20 degree drop. Based on those numbers:
f=Q/(450*T)
8=72000/(450*T)
T=20 degrees
1.25 inch Pex
H=0.000794*1.582*293*38.055 = 14 feet head
The 0012 model matches that pretty good
1 inch Pex
H=0.00223*1.582*288*38.055 = 38 feet head - No Taco pump works, head too high
if you did a 30 degree drop
f=Q/(450*T)
f=72000/(450*30)
f=5.33 gpm, use 5.5 gpm
1 inch Pex
H=0.00223*1.582*288*19.753 = 20 feet head, the 009 and the 0014 match up pretty well.
With your 1/2" Pex, 50/50 mix, and loop at 272 feet (use about 281 feet, to account for 4 90 degree bends and a branch tee), calc is as follows:
H=0.0374*1.582*281*4.970 = 82.6 feet of head (using flow rate in 1/2" pex of 2.5 gpm, velocity slightly higher than 4 feet per second, none of the Taco pumps can do this.
H=0.0374*1.582*281*3.364 = 55.9 feet (flow rate of 2 gpm)
H=0.0374*1.582*281*2.033 = 33.8 feet (flow rate of 1.5 gpm, slightly higher than 2 feet per second velocity)
The Taco 009 circulator can do this, but when you back up and look at your system, the change in temperature is:
f=Q/(450*T)
1.5=72000/(450*T)
T=106.7 degrees
So realistically what would happen is
1.5=Q/(450*20)
Q=13,500 BTU delivered
1.5=Q/(450*30)
Q=20,250 BTU delivered
In other words due to your tube size, you can't circulate enough water to deliver all the heat you need. The flow rate should be around 8 gpm with a pex tube size of 1 1/4" for a 20 degree drop. Based on those numbers:
f=Q/(450*T)
8=72000/(450*T)
T=20 degrees
1.25 inch Pex
H=0.000794*1.582*293*38.055 = 14 feet head
The 0012 model matches that pretty good
1 inch Pex
H=0.00223*1.582*288*38.055 = 38 feet head - No Taco pump works, head too high
if you did a 30 degree drop
f=Q/(450*T)
f=72000/(450*30)
f=5.33 gpm, use 5.5 gpm
1 inch Pex
H=0.00223*1.582*288*19.753 = 20 feet head, the 009 and the 0014 match up pretty well.
The tubing is in the slab now so the numbers to maximize efficiency based on the heat source may not work. Also if he can get the slab up to the steady state temp the delta will narrow. The point here is to provide a sufficient circulator to supply the loops at around 4'p/second. In my shop I'm pushing 8 300' loops on a 1" manifold with a 15 - 58 Grundfos on speed 3 and if the floor is cold I get about a 20 degree delta. A 15 - 58 on speed 2 is about equivalent to a Taco 007. A Taco 11 is a multi speed pump. Either of those should work.
At that point if you can't meet your set point on the radiant loops alone you will need an additional zone such as a unit heater to fully utilize the output of your water heater.
As an aside, I really think members here should discourage people from using water heaters for space heating unless those water heaters are specifically rated for space heating. Use the proper appliance for the job. A modcon boiler is surely more expensive upfront but will pay dividends by having heating curves specifically for high mass (garage floor) radiant applications, and outdoor reset controls. Modcons thrive on high delta systems and the selectable heating curves mean in many applications no mixing valves, boiler protection loops or hydraulic separation is needed.
You guys seem to be missing the fact that the OP states he has 6 parallel 1/2in 270foot pex runs?
So if he needs 8gpm at 20deg to carry the load, that is only 1.33gpm per loop. Which is well within the capability of common pumps.
I like where this is going. Does anyone else have this opinion? So each parallel loop divides the total pressure and head pressure by 6 . Hmm maybe I did not make as big of mistake as I thought. Hopefully there are others that think this is correct.
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I suppose it would be better to have the pump run less times with more volume than a slow and steady flow. What do you mean by a unit heater. Unfamiliar with that term.
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