COP in vapor compression refrigeration analysis

AI Thread Summary
Heat pump compressors operate with a fixed compression ratio but do not maintain a fixed pressure, which varies with outdoor temperature changes. In cooling mode, as outdoor temperatures increase, the system pressure rises, affecting the coefficient of performance (COP), which decreases as the temperature rises. Calculating the COP requires understanding the relationship between pressure and temperature, particularly at the saturation points of the refrigerant. The COP can be determined using the enthalpy values at various points in the cycle, although assumptions may be necessary for certain temperatures. The discussion highlights the complexity of these calculations and the impact of outdoor conditions on heat pump efficiency.
bearcharge
Messages
26
Reaction score
0
Hi, has anybody worked with heat pumps? I'm recently confused about how the heat pump compressor operates. Does it have a fixed pressure or it actually adjust its pressure automatically to outdoor temperature variation? All my confusion originate from the following problem:

Now we have a heat pump that employs vapor compression refrigeration cycle for cooling. Suppose indoor temperature is 55 F(12.7 C) and outdoor temperature is 95 F(35 C), try to determine the parameters that compressor should be operating so that COP of 6 can be achieved. Then use the determined parameters to calculate COP when outdoor temperature is raised to 105 F and indoor temperature stays the same. For the sake of simplicity, assume saturated fluid in the condenser and saturated vapor in the entrance of compressor.

Any suggestion will be much appreciated. Thanks.
 
Physics news on Phys.org
A heat pump compressor is fixed compression ratio, but not fixed pressure. If the temperature outside drops (in heating mode), the pressure in the entire system will drop...and the COP will drop. Similarly, if the temperature outside rises when in cooling mode, the COP will drop.
 
thanks for the reply! so in the cooling mode, when the outdoor temperature is raised, the compression ratio stays the same, but the system pressure drops or rises? and can we calculate this pressure drop or rise based on the assumption of saturation liquid and saturation vapor? and from that we calculate the COP in this case? Thanks.
russ_watters said:
A heat pump compressor is fixed compression ratio, but not fixed pressure. If the temperature outside drops (in heating mode), the pressure in the entire system will drop...and the COP will drop. Similarly, if the temperature outside rises when in cooling mode, the COP will drop.
 
In air conditioning mode, if the temperature outside rises, the pressure rises.

Well...it depends on what other information you are given and how you are expected to use it. You can probably plot the cycle on a t-s diagram and work from there. Or maybe they just want you to use the carnot efficiency equation? Part of the difficulty in a calculation, though, is the CoP drop is related to the difficulty with dissipating heat at the heat exchanger when the temperature outside rises.
 
Thank you very much, Russ Watters! you've been very helpful.
Is it appropriate to assume this pressure is a function of temperature, considering it's saturated at the entrance of the condenser, and this pressure is equal to the pressure at the exit of the compressor? then by using the equation
COP = \frac{h_1-h_4}{h_2-h_1},
where 1:entrance of compressor
2:exit of compressor
3:entrance of condenser
4:exit of condenser
but it seems that even with the pressure calculated, we still need to know the temperature at point 2 to determin h2. Can I just assume a temperature at point 2?
by the way, I tried to use carnot cycle efficiency for calculation, but this method was denied...

russ_watters said:
In air conditioning mode, if the temperature outside rises, the pressure rises.

Well...it depends on what other information you are given and how you are expected to use it. You can probably plot the cycle on a t-s diagram and work from there. Or maybe they just want you to use the carnot efficiency equation? Part of the difficulty in a calculation, though, is the CoP drop is related to the difficulty with dissipating heat at the heat exchanger when the temperature outside rises.
 
What are the typical cop of vapor compression chiller and absorption chiller
 
Thread 'Gauss' law seems to imply instantaneous electric field propagation'

Thread 'Gauss' law seems to imply instantaneous electric field propagation'

Imagine a charged sphere at the origin connected through an open switch to a vertical grounded wire. We wish to find an expression for the horizontal component of the electric field at a distance ##\mathbf{r}## from the sphere as it discharges. By using the Lorenz gauge condition: $$\nabla \cdot \mathbf{A} + \frac{1}{c^2}\frac{\partial \phi}{\partial t}=0\tag{1}$$ we find the following retarded solutions to the Maxwell equations If we assume that...
View full post »

Thread 'Do electron density waves accompany EM waves in coaxial cables?'

Maxwell’s equations imply the following wave equation for the electric field $$\nabla^2\mathbf{E}-\frac{1}{c^2}\frac{\partial^2\mathbf{E}}{\partial t^2} = \frac{1}{\varepsilon_0}\nabla\rho+\mu_0\frac{\partial\mathbf J}{\partial t}.\tag{1}$$ I wonder if eqn.##(1)## can be split into the following transverse part $$\nabla^2\mathbf{E}_T-\frac{1}{c^2}\frac{\partial^2\mathbf{E}_T}{\partial t^2} = \mu_0\frac{\partial\mathbf{J}_T}{\partial t}\tag{2}$$ and longitudinal part...
View full post »
Thread 'Recovering Hamilton's Equations from Poisson brackets'

Thread 'Recovering Hamilton's Equations from Poisson brackets'

The issue : Let me start by copying and pasting the relevant passage from the text, thanks to modern day methods of computing. The trouble is, in equation (4.79), it completely ignores the partial derivative of ##q_i## with respect to time, i.e. it puts ##\partial q_i/\partial t=0##. But ##q_i## is a dynamical variable of ##t##, or ##q_i(t)##. In the derivation of Hamilton's equations from the Hamiltonian, viz. ##H = p_i \dot q_i-L##, nowhere did we assume that ##\partial q_i/\partial...
View full post »

Similar threads

How to estimate enthalpy change across a compressor in simple vapor compression cycle
Replies
1
Views
223
B Cooling effect of evaporation occurs even if the surroundings are colder?
Replies
10
Views
2K
Could somebody please explain the vapor compression cycle?
Replies
3
Views
5K
Designing an Actual Vapor-Compression Refrigeration Cycle
Replies
8
Views
5K
B HFC-134a Refrigerant & 2nd Law of Thermodynamics
Replies
20
Views
2K
Heat pump efficiency calculations - Compressor power issue
Replies
23
Views
3K
A Few questions about how a refrigerator works
Replies
13
Views
4K
Thermodynamics: Vapor Compression Refrigeration that is Adiabatic?
Replies
3
Views
3K
What is the Chemistry Behind Refrigerant Blends?
Replies
6
Views
4K
Vapor-compression refrigeration cycle
Replies
3
Views
2K

Hot Threads

Recent Insights

Back
Top