Domestic Hot Water Storage Tank Bank

Series vs. Parallel analysis

It dawned at me that I need to look at the series piping

differently.  After sketching some things out, it started to make sense,

and I am suddenly in favor of the series storage tanks I've seen in the

field.  See attached PDF and comment.



 Sheet 1



Figure 1 shows a typical vertical storage tank

with a heat pump water heater and a typical hot water recirculation loop. 

This system demonstrates good thermal stratification, maximizing the delta T

between T1 and T6, and as such maximizing the COP of the heat pump.





 Figure 2 shows an identical tank which has

been divided into three equal volumes for modeling (still a single compartment

tank).  Temperatures T2 & T3 are equal, as are temperatures T4 &

T5.  Stratification and HP performance are identical as Figure 1.





 Figure 3 shows the same three volumes as Figure

2, now modeled as separate compartments.  Similar stratification and

performances must occur regardless of height differences between the locations

of T2 & T3, and T4 & T5.



Sheet 2



Figures 1, 2, 3 show the

typical hot water recirculation path for all three scenarios in ORANGE, when the heat pump (and integral

circulation pump + valve) is OFF.



Sheet 3



Figures 1, 2, 3 show the

typical heat pump circulation path for all three scenarios in GREEN, when the heat pump (and integral

circulation pump + valve) is ON.  Note the direction of flow through the

pipe connecting the tank has reversed.



Figure 3 also shows the hot

water recirculation path in ORANGE,

when the heat pump is ON.



Sheet 4



Figure 4 shows a typical

horizontal hot water storage tank.  Stratification between T1 and T6 is

poorer than that seen in Figure 1, especially during periods of high

demand when cold make up water is mixing at greater rates. 



Figure 5 shows a typical

cluster of storage tanks piped in parallel.  This configuration closely

mirrors the thermal effects of Figure 4.



 In conclusion, it appears that Figure 3 provides

greater thermal stratification, greater Delta T between T1 & T6, and better

HP performance than Figure 5.  In the examples I sketched, it is

assumed that the volumes in the series and parallel systems are equal.  As

such, a parallel system won’t actually deliver a greater supply of hot water

during a sudden spike in demand – they are the same.  Furthermore, the

materials and labor cost to pipe Figure 5 appears to be greater than Figure

3.  All three tanks In Figure 5 must be properly balanced to

ensure even temperature distributions across all three tanks. 

 Plumbing multiple smaller vertical tanks in series can produce the

benefits of a large single storage tank where space limitations, and / or costs

(anything over 120 gallons must be an ASME pressure vessel I think) prohibit it.



Thoughts? Comments!  Thank you for the input!!!

response

Good points.  Stratification doesn't do much to overall energy storage, as you said 1 btu is still 1 btu.  What it does do though, is allow a greater average temperature to be supplied to the building, and allow a lower average temperature to feed the ASHP.  Vertical storage is typically preferred to horizontal storage for these reasons - similar in the solar water heating field.  In a horizontal tank, the stacking is less prevalent, mixing is greater, and the delta T between top and bottom is usually slightly less.   I'm just not convinced if tanks piped in series can truly model the same thermal effects of a single vertical tank.  It is also true that recirc will stir up the tank and lessen the stacking effect, but by how much, i'm not sure.   I'd like to do some testing.  I've been in 4 friend's apartment buildings recently out here in Hawaii and have found these series installations in every one.  I'm guessing a single contractor went around and did these retrofits 10 years back or so.  My inquiring mind just wants to know why.  Thanks for the comments.

It may just be a Hawaii thing

These particular colmac heat pumps appear to be best suited for environments such as that which we have here in Hawaii.  The COP of the heat pumps increases as enthalpy  of the air increases, and as the incoming water temperature drops.  Therefore, all effort is made to keep the bottom of the "cold tank" as cold as possible, to promote stratification and reduce mixing.  Colmac recommends using storage tanks with incoming water baffles or diffusers to reduce dilution, and feed the coldest water possible to their heat pumps. 



Larry I also was wondering about how the water flows through the system.  After some discussions I think I understand it now.  When on, the flow through the heat pumps (internal circ pumps) is fixed, lets say for the sake of discussion at 3gpm.  If valves are opened and hot water demand is at say 8gpm to the building, then 5gpm will draw off the hot tanks, and 3gpm will pass through the heaters to the building.  Cold water will replace the hot water in the cold tank at 5gpm.  Once demand falls back off, say to 2gpm, the flow through the heat pumps will continue at 3gpm and start to replenish the hot water tanks at 1gpm, feeding backwards through the hot water tank.  Its really a pretty slick system.  I did some field measurements of Colmacs installed out here and they are indeed getting COP's of 3.5 - 4.  If you take advantage of the free air cooling, you can get combined COP's that are very high. 



The only major disadvantage of the series system i still see is serviceability, as was mentioned.  You can't just valve off a tank to remove it.  Because the battle out here is always energy costs (remember we're paying $0.34/kwh, not counting demand charges, and Gas isn't much better), I think the benefits outweigh the serviceability issue.  I enjoy all of your inputs.  Mahalo!