electricpete
Electrical
- May 4, 2001
- 16,774
I typically see discussions like this:
I think it’s a very reasonable approach for most purposes (more later). But it’s not completely accurate to say that we only need the centrifugal pump affinity laws to get there.
The affinity laws predict change in centrifugal pump/fan CURVES as speed changes. A pump curve would be any curve involving any relationship among the variables flow, dp and horsepower. In order to map a curve from one speed to another speed, we apply Q~N, DP~N^2, HP~N^3 to BOTH coordinates of a point on a curve at old speed to find a point on the curve at the new speed… repeat for many points to generate the new curve.
The affinity laws do not in general predict the change in operating point as speed changes. The new operating point is of course the intersection of the new pump/fan curve and the system curve (which is unchanged for simple systems which don’t have something like auto-flow control valve or other feedback mechanism).
There is a special case where the affinity laws WILL predict change in operating point in the simple manner (Q~N, DP~N^2, HP~N^3). That happens IF AND ONLY IF the pump/fan is connected to a system which obeys DP~Q^2. That is a system characteric curve which is dominated by turbulent flow resistance. That is the case in closed loop piping systems with reasonably high flow velocities.
But if you happen to have an open fluid system, there may be pressure changes in the system that are independent of flow. Example a pump sends water from atmospheric pressure reservoir through a pipe into a pressurized tank at the same elevation– the pump must overcome both pipe pressure drop and the DP between tank and reservoir – the latter component does not vary with flow. The DP vs Q curve does not pass through (Q,DP)=(0,0) as a DP~Q^2 curve would. For DP=0 (no pump DP), you would have negative (reverse) flow (neglecting any check valves). If you tried to force Q=0 by installing a blank flange at the pump you would have a positive DP across the blank flange.
Likewise laminar flow would follow DP~Q instead of DP~Q^2, although I think most pumped fluid systems operate more in turbulent flow.
(I realize there are some circumstances which it makes more sense to deal in pump head rather than pump dp, but it doesn’t matter if we are not contemplating change in density.)
I’m not trying to pick on anyone. I saw something like this from a very respected member in another thread that spurred this comment. I decided not to clutter up that thread with my picky comment. It is something I was confused about myself awhile back before the guys on the pump forum straightened me out, so I thought others might be confused the same way I used to be (well… I’m still plenty confused, just not about this particular thing). I apologize if I’m telling you guys something you already know.
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(2B)+(2B)' ?
This principle (power ~ N^3) is then used to estimate how much the motor load might change if the speed is changed (neglecting changes in motor and pump/fan efficiency).
I think it’s a very reasonable approach for most purposes (more later). But it’s not completely accurate to say that we only need the centrifugal pump affinity laws to get there.
The affinity laws predict change in centrifugal pump/fan CURVES as speed changes. A pump curve would be any curve involving any relationship among the variables flow, dp and horsepower. In order to map a curve from one speed to another speed, we apply Q~N, DP~N^2, HP~N^3 to BOTH coordinates of a point on a curve at old speed to find a point on the curve at the new speed… repeat for many points to generate the new curve.
The affinity laws do not in general predict the change in operating point as speed changes. The new operating point is of course the intersection of the new pump/fan curve and the system curve (which is unchanged for simple systems which don’t have something like auto-flow control valve or other feedback mechanism).
There is a special case where the affinity laws WILL predict change in operating point in the simple manner (Q~N, DP~N^2, HP~N^3). That happens IF AND ONLY IF the pump/fan is connected to a system which obeys DP~Q^2. That is a system characteric curve which is dominated by turbulent flow resistance. That is the case in closed loop piping systems with reasonably high flow velocities.
But if you happen to have an open fluid system, there may be pressure changes in the system that are independent of flow. Example a pump sends water from atmospheric pressure reservoir through a pipe into a pressurized tank at the same elevation– the pump must overcome both pipe pressure drop and the DP between tank and reservoir – the latter component does not vary with flow. The DP vs Q curve does not pass through (Q,DP)=(0,0) as a DP~Q^2 curve would. For DP=0 (no pump DP), you would have negative (reverse) flow (neglecting any check valves). If you tried to force Q=0 by installing a blank flange at the pump you would have a positive DP across the blank flange.
Likewise laminar flow would follow DP~Q instead of DP~Q^2, although I think most pumped fluid systems operate more in turbulent flow.
(I realize there are some circumstances which it makes more sense to deal in pump head rather than pump dp, but it doesn’t matter if we are not contemplating change in density.)
I’m not trying to pick on anyone. I saw something like this from a very respected member in another thread that spurred this comment. I decided not to clutter up that thread with my picky comment. It is something I was confused about myself awhile back before the guys on the pump forum straightened me out, so I thought others might be confused the same way I used to be (well… I’m still plenty confused, just not about this particular thing). I apologize if I’m telling you guys something you already know.
=====================================
(2B)+(2B)' ?