Modeling Capacity and Coefficient of Performance of a Refrigeration Compressor

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urdue University urdue e-ubs International ompressor ngineering onference School of Mechanical ngineering 004 Modeling apacity and oefficient of erformance of a Refrigeration ompressor Hubert Bukac Little Dynamics Follow this and additional works at: http://docs.lib.purdue.edu/icec Bukac, Hubert, "Modeling apacity and oefficient of erformance of a Refrigeration ompressor" (004). International ompressor ngineering onference. aper 171. http://docs.lib.purdue.edu/icec/171 This document has been made available through urdue e-ubs, a service of the urdue University Libraries. lease contact epubs@purdue.edu for additional information. omplete proceedings may be acquired in print and on D-ROM directly from the Ray W. Herrick Laboratories at https://engineering.purdue.edu/ Herrick/vents/orderlit.html

04, age 1 Modeling apacity and oefficient of erformance of a Refrigeration ompressor Hubert Bukac Little Dynamics 1 ounty Road 138 Vinemont, AL 35179-6301, USA Tel.: (56) 775-871 -mail: hbukac@earthlink.net Abstract A rather complex mathematical model of a running refrigeration or air-conditioning compressor has been developed. The model is capable of predicting capacity and coefficient of performance of a compressor with acceptable accuracy. The input data consists of over sixty variables such as dimensions and tolerances of major parts of the compressor, thermodynamic and fluid mechanic properties of a refrigerant, oil viscosity, as well as the torque, power, and energy efficiency characteristics of an electric motor. The model has four major parts. The first part is a model of flow of gas through the suction valve. The second part is a model of flow of gas through the discharge valve [1]. The third part is the model of the leakage of gas through the clearance between the cylinder and the piston []. The fourth part is a model of electric motor torque and efficiency [3]. The loss of energy due to the viscous friction in bearings, and due to the viscous friction of the piston, is also considered. The model does not include gas pulsation in suction and discharge plenums and mufflers, and it does not include models of heat exchange in the condenser and in the evaporator. Instead, constant evaporating and condensing pressures are considered. 1. Introduction The ability to develop, in the shortest possible time, a refrigeration or an air-conditioning compressor that has required capacity and the coefficient of performance (O) is decisive factor in the contemporary fast paced market. Usually, a trial and error approach is the art-of-the-day. This method is not only time consuming, but it is costly too. The mathematical models presented here and in [1], [], and [3] can considerably shorten the development time.. apacity of a ompressor The capacity is a product of circulating mass per second, and the change in enthalpy of the refrigerant Q= h (1) Where Q is capacity [W], h is change in enthalpy in the evaporator [J/kg], and is the mass-flow-rate of gas [kg/s]. The mass-flow-rate, is actually equal to the net mass-flow-rate through the discharge valve, which is equal to m=m & & = DV SV L () The mass-flow-rates in () include the back-flow and the leakage through both valves. These mass-flow-rates are modeled by using equations (4) through (1) in [1]. Because the density of gas is different in different parts of compressor, and because the density of gas varies during the compression, it has to be emphasized, the correct gas density has to be used for each flow. For the flow out of the cylinder, the instantaneous density of gas in the cylinder is used. For the back flow through the valves, the density of gas in the discharge plenum and the density of gas in the suction plenum are used. If the density of gas inside the shell differs from the density of gas in the suction plenum, the density of gas in the shell shall be used to calculate positive piston leakage (the gas that enters the cylinder during the suction period through the clearance between the piston and the cylinder). While the flow through the valves, both the positive one and the leakage, is modeled as an isentropic flow, the leakage through the clearance between the piston and the cylinder is modeled as an isothermal flow. The mass-flow-rate calculated in () should correlate with the calorimetric measurement. DV International ompressor ngineering onference at urdue, July 1-15, 004

04, age The theoretical mass-flow-rate is equal to the quantity of gas that could circulate through the compressor if all leakages were neglected. It is equal to n = V D ρs (3) 60 Where is theoretical mass-flow-rate [kg/s], V D is displaced volume [m 3 ], ρ S is density of gas at the specified point in the compressor, in his case, it is the inlet into the suction port [kg/m 3 ], and n is sped of compressor [RM]. 3. The Mass-Transport fficiency of a ompressor The mass-transport efficiency of a compressor is better criterion for comparing quality of the design and the quality of manufacturing of the compressor than the volumetric efficiency is. Besides the re-expansion, the η M includes all other losses and effects such as gas warming, flow resistance in the valves, and all leakages. It is equal to the ratio of actual mass-flow-rate that is modeled or measured on a calorimeter, to the theoretical mass-flow-rate (0<= η M <=1). ηm = (4) The actual mass-flow-rate that is modeled should agree with the one measured on the calorimeter. In either case, the speed of compressor has to be the same for both mass-flow-rates in the equation (4). 4. nergy fficiency and O of a ompressor The model calculates several energy efficiencies of refrigeration or of an air-conditioning compressor. In addition to the thermodynamic efficiencies of a compressor, there is also a thermodynamic efficiency of a cycle. The model can calculate this one too. The isentropic energy efficiency of a thermodynamic cycle is the ratio of the change in isentropic enthalpy in the evaporator to the change in isentropic enthalpy in the compressor, Fig. 1. h η Y = (5) h Where h is the change in enthalpy in the compressor [J/kg]. For a given refrigerant, the η Y depends only on operating conditions. It has little meaning to the compressor design and quality of manufacturing. In a theoretical case, when the evaporation and condensation would take place at the same pressure, h would be zero, and η Y could reach infinity. The isentropic energy efficiency of the compressor is calculated as the ratio of the product of actual mass-flow-rate and the change in isentropic enthalpy in the compressor to the input power on the shaft of the compressor m h η IS = & (6) Where is the input power on the shaft of the compressor. In the theoretical case, when the evaporation and condensation takes place at the same pressure and the same temperature, the change in enthalpy in the compressor would be zero, and the shaft-power would cover only passive resistance against the rotation, and regardless of mass-flow-rate, the isentropic energy of a compressor would be zero. The actual coefficient of performance is calculated as the ratio of the capacity of the compressor and the change in enthalpy in the evaporator to the input power on the shaft of the compressor Q m h O = = & (7) International ompressor ngineering onference at urdue, July 1-15, 004

04, age 3 In the case of a hermetic compressor, the shaft-power in (6) and (7) is replaced by the power of an electric motor as it would be measured on its terminals. The ratio of the shaft-power to the electric power is energy efficiency η of the motor η = (8) Since the change in the enthalpy in the evaporator is given by operating conditions, the O is a measure of the effectiveness of the compressor to transport gas. The model also calculates the theoretical O as m h O = & (9) The theoretical O is the maximum O a compressor can attain. The model also calculates the ratio of the actual O to the theoretical O. This Ratio is also a useful parameter that may be used to judge overall quality of the design and quality of manufacturing of a compressor. From equations (4), (7), (8), and (9), we get h η= = =ηm η h (10) Thus, the overall energy efficiency of a compressor is equal to the product of the efficiency of the mass-transport of the compressor and energy efficiency of an electric motor. 5. The Shaft-ower The instantaneous power necessary to drive the compressor is equal to =T ω (11) i i Where T i is total instantaneous torque acting upon the shaft [N.m], i is total instantaneous shaft power, and ω is angular velocity of the crankshaft [s -1 ]. The total torque T i is instantaneous torque that is equal to the sum of torques due to the compression force, the force of viscous friction of the piston, and the friction torques acting upon the wristpin, the crank pin, and the torque of main bearings. T=T + T + T + T + T (1) i V W BG The compression torque T is modeled as π D LR sinϕ cosϕ T = R ( p ps ) cos ϕ+ (13) 4 R R 1 sinϕ L R The torque due to viscous friction of piston T V is modeled as International ompressor ngineering onference at urdue, July 1-15, 004

04, age 4 R ωπd L R sin ϕcosϕ R ( sinϕ cosϕ) T = µ sinϕ+ cosϕ+ V D D R R L 1 sinϕ L 1 sinϕ L R L R (14) In the equations (13) and (14) there is: R crank radius [m], p pressure in the cylinder [a], p S pressure in the crankcase [a], D piston diameter [m], D cylinder diameter [m], L length of piston [m], L R length of connecting rod [m], φ angular position of the crank, µ dynamic viscosity of oil [N.s.m - ], and. in the equation (14) is relative part of the circumference of the piston (0 1) filled with the oil film. The torque of viscous friction of the wristpin T W is modeled as 3 π DW LW µ R cosϕ T W = ω (15) ( DWS DW ) LR R 1 sinϕ L R Where D W is diameter of the wristpin [m], and D WS is the diameter of the sleeve of the wristpin i.e. the diameter of small end of connecting rod [m]. The torque of viscous friction of the crankpin T is modeled as 3 π D L µ R cosϕ T = ω+ (16) ( DS D ) LR R 1 sinϕ L R The torque of viscous friction of the main bearing T BG is modeled as π D L µ 3 BG BG T BG = ω (17) ( DBS DBG ) Where D BG is the diameter of main bearing [m], D BS is the diameter of the sleeve of the main bearing [m], and L BG is the length of main bearing. If all main bearings do not have the same dimensions, the equation (18) has to be applied on each bearing and the results added. The average torque T is equal to N 1 T= T (18) N i = 0 i Where N is the number of positions of the crankshaft, within one revolution, for which the torque is calculated. 6. haracteristics of an lectric Motor In order to fit an electric motor to the compressor we need to know torque-slip, and torque-energy efficiency of the electric motor. The slip of an electric motor, re-arranged from [3] equation (10), is International ompressor ngineering onference at urdue, July 1-15, 004

04, age 5 T B A V T B A V 1 1 1 1 1 s 1 = ± (19) T B T B B Where s 1 is slip [ ], T is average torque [N.m], V is applied terminal voltage [V], A 1, B 1, and B are constants. The smaller of both roots of equation (19) is used. The energy efficiency of an electric motor η is found from equation (0). This equation is actually a curve-fit of the measured energy efficiency curve of the electric motor 1 T η = (0) D T + D1 T+ 1 Where 1, D, and D 1 are constants. Tab. 1 OMRSSOR DATA: Dimension LTRI MOTOR: Dimension ompressor Model Model Number of ylinders Motor Type ylinder Diameter (Bore) mm hase iston Diameter mm Frequency Hz iston Length (Active Friction Length) mm Voltage V rank Radius mm Start apacitor microfarad Length of onnecting Rod mm Run apacitor microfarad quivalent Head learance mm Torque onstant A1 N.m/V ompressor RM 1/min Torque onstant B1 Shaft Diameter of Upper Main Bearing mm Torque onstant B Sleeve Diameter of Upper Main Bearing mm fficiency onstant 1 1/N.m Length of Upper main Bearing mm fficiency onstant D1 Shaft Diameter of Lower Main Bearing mm fficiency onstant D Sleeve Diameter of Lower Main Bearing mm Length of Lower Main Bearing mm Diameter of rankpin mm Diameter of Big nd Of onnecting Rod mm Width of onnecting Rod Big nd Bearing mm Diameter of rankpin mm Diameter of Small nd of onnecting Rod mm Length of Small nd of onnecting Rod mm Viscosity of Oil in Bearings and iston microa.s Tab. RFRIGRANT Suction Gas: Dimension Discharge Gas: Dimension vaporating Temperature Deg. ondensing Temperature Deg. vaporating ressure a ondensing ressure a Gas Density at Suction ort Temperature kg/m^3 Discharge Temperature Deg. Gas Viscosity at Suction ort Temperature microa.s Gas Density at Discharge Temperature kg/m^3 Isentropic xponenet at Suction ort Temp. Gas Viscosity at Discharge Temperature microa.s nthalpy at Suction ort Temperature J/kg Isentropic xponenet at Discharge Temp. Gas Density (3.=90F) kg/m^3 nthalpy (3.=90F) J/kg International ompressor ngineering onference at urdue, July 1-15, 004

04, age 6 Tab. 3 SUTION VALV DATA: Dimension DISHARG VALV DATA: Dimension omprerssor Model ompressor Model Suction valve Mass 1 gr Discharge Valve Mass gr Suction valve Mass gr Discharge Valve Stiffness N/m Suction Valve Stiffness 1 N/m Mass of Stop gr Suction Valve Stiffness N/m Stiffness of Stop N/m Relative Damping 1 Realative Damping of Valve Relative Damping Relative damping of Stop Suction Valve OD mm Discharge Valve OD mm Diameter of suction port recess mm Discharge Valve ID (Recess) mm Depth of Suction ort Recess (if any) mm Depth of Recess mm Suction ort Diameter mm Discharge ort Diameter mm Length of Suction ort (without recess) mm Length of disch. port mm Valve Lift Limitter(Stop) mm Valve Lift Limitter(Stop) mm Valve reload N Valve reload N Minimum Oil Film Thickness mm Stop reload N Maximum Oil Film Thickness mm Length of Valve (Reed) mm Number of Suction orts per ylinder Number of Discharge orts per ylinder Oil Viscosity (on valve seat) microa.s Maximum Oil film Thickness mm Type of Valve seat Minimum Oil Film Thickness mm ort Inlet oefficient Oil Viscosity (on valve seat and stop) microa.s Valve Drag oefficient Valve-Stop ontact Area mm^ Type of Valve Seat ort Inlet oefficient Valve Drag oefficient Tab. 4 RSULTS Dimension RSULTS Dimension ompressor Suction Valve Ideal apacity W Suctin Valve Opens Before BD Deg apacity W Suction alve loses After BD Deg apacity ercent of Ideal apacity Angle of Valve Opening Deg Ideal Isentropic O Maximum Valve Lift mm O kg/hr Valve Seat Impact Velocity m/s O ercent of Ideal O kg/hr Discharge Valve Ideal irculating Mass Suctin Valve Opens Before TD Deg irculating Mass Discharge alve loses After TD Deg Mass-Transport fficiency Angle of Valve Opening Deg Mean Torque N.m Valve Seat Impact Velocity m/s Maximum Torque Nm Valve Stop Imact Velocity m/s Mean RM 1/min Mechanical ower W Required Motor ower W Motor nergy fficiency 7. The Model To run the model we need to know all the input data. All the input data is divided into four categories, compressor data, refrigerant data, suction valve data, discharge valve data, and electric motor data. Tab. 1 and Tab. is the example. Tab. 3 shows results of modeling. 8. onclusion Although it may seem that it should be somewhat laborious to collect all the necessary input data, the result is worth of it. Most of the data is valid for more then one model of the compressor. The model was applied the model capacity and O/R of a small refrigeration compressor with acceptable accuracy. International ompressor ngineering onference at urdue, July 1-15, 004

04, age 7 References [1] Bukac H.: Understanding Valve Dynamics, 00 International ompressor onference at urdue University, Lafayette, IN, USA [] Bukac H., Optimum iston-bore Fit for Maximum ompressor fficiency, 000 International ompressor ngineering onference at urdue University, Lafayette, IN, USA. [3] Bukac H.: Modeling ompressor Start Up, 00 International ompressor ngineering onference at urdue University, Lafayette, IN, USA. [4] ISO 917, International Standard Organisation [5] Hamrock Bernard, J.: Fundamentals of Fluid Film Lubrication, McGraw-Hill, 1994. [6] Shigley Joseph,., Uicker John, J., Jr.: Theory of Machines and Mechanisms, McGraw-Hill, 1980. [7] RFRO: National Institute of Standards and Technology, Standard Reference Data, BLDG. 80/Room 113, Gaithersburg, MD 0889. Log(pressure) h h nthalpy Fig. 1: ompression cycle International ompressor ngineering onference at urdue, July 1-15, 004

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