bigAlittlee
Mechanical
- Feb 10, 2010
- 13
A very fundamental to HVAC, though not so simple problem I am trying to solve using a route I wouldn't normally take. Up until now my experience estimating building performance has largely been with using various energy modeling programs, with libraries for equipment etc. Well - I got a new job and part of the description is retro-commisioning, which I am very happy to dive into, but using bin data, trend data, and MS Excel has not been my forte. However, these calcs must be transparent and reviewable, so that's the way it has to be.
This project's cooling plant is around 40 years old. Installed tower capacity is 6 cells @ design capacity of 833 tons (which includes oversizing/redundancy as CHW plant rarely breaks 3000 tons, though all 6 cells run under normal operation). Towers are crossflow (Marley I believe) similar to BAC 3000 series or Marley NC with single speed 40hp fans. Design CWS setpoint is 80F with 90F CWR. Carrier has provided documentation on these old chillers, verifying I can take them down to 70F.
Dropping CWS to 70F and saving ~ 10% on chiller consumption is simple enough to calculate. I have plenty of trend data giving current performance, and original documentation to assist in estimating savings due to condenser water relief.
Now what isn't simple to calculate is the increase in fan energy consumption that must be deducted from chiller savings. (Because VFDs will not be considered at this time, we are talking about fan run hours, and the increase of those hours at a lower condenser water temperature.)
Even better - optimal condenser water temperature / balancing chiller savings with fan energy increase to determine best operating point(s) or optimal operating curve vs. wet bulb etc.
I have used one method to come up with results, but I am not satisfied and don't feel I have "fully" solved the problem.
Does anyone know of any good references that I may not have thought of yet for solving such a problem? Basically the goal is to come up with coefficients characteristic of the tower based on operating conditions that I know and can verify, that can be used to predict performance under other operating conditions. "Refrigeration and Air Conditioning" by W.F. Stoecker (1958) for example comes up with fgA/0.245 = constant for a given tower with constant flow rates - this is what I am using as reference for this 2nd attempt at a better solution, but would be happy to hear any further comments/recommendations!
This project's cooling plant is around 40 years old. Installed tower capacity is 6 cells @ design capacity of 833 tons (which includes oversizing/redundancy as CHW plant rarely breaks 3000 tons, though all 6 cells run under normal operation). Towers are crossflow (Marley I believe) similar to BAC 3000 series or Marley NC with single speed 40hp fans. Design CWS setpoint is 80F with 90F CWR. Carrier has provided documentation on these old chillers, verifying I can take them down to 70F.
Dropping CWS to 70F and saving ~ 10% on chiller consumption is simple enough to calculate. I have plenty of trend data giving current performance, and original documentation to assist in estimating savings due to condenser water relief.
Now what isn't simple to calculate is the increase in fan energy consumption that must be deducted from chiller savings. (Because VFDs will not be considered at this time, we are talking about fan run hours, and the increase of those hours at a lower condenser water temperature.)
Even better - optimal condenser water temperature / balancing chiller savings with fan energy increase to determine best operating point(s) or optimal operating curve vs. wet bulb etc.
I have used one method to come up with results, but I am not satisfied and don't feel I have "fully" solved the problem.
Does anyone know of any good references that I may not have thought of yet for solving such a problem? Basically the goal is to come up with coefficients characteristic of the tower based on operating conditions that I know and can verify, that can be used to predict performance under other operating conditions. "Refrigeration and Air Conditioning" by W.F. Stoecker (1958) for example comes up with fgA/0.245 = constant for a given tower with constant flow rates - this is what I am using as reference for this 2nd attempt at a better solution, but would be happy to hear any further comments/recommendations!
