The present invention relates to vapor compression systems and, more specifically, to determining the supercritical pressure within a heat exchanger in a transcritical vapor compression system.
In a typical vapor compression system, the refrigerant remains at subcritical pressures throughout the system. However, for some refrigerants, such as carbon dioxide, it is typical to operate the system as a transcritical vapor compression system wherein the refrigerant is at a supercritical pressure on the high pressure side of the system and at a subcritical pressure on the low pressure side of the system.
In such a transcritical system the refrigerant is compressed to a supercritical pressure in the compressor and then cooled in a heat exchanger, commonly called a gas cooler. After the refrigerant is cooled in the gas cooler, it is passed through an expansion device to lower its pressure from a supercritical pressure to a subcritical pressure. The low pressure refrigerant then enters an evaporator wherein the refrigerant absorbs thermal energy as it changes phase from a liquid to a vapor.
When a refrigerant is compressed to a supercritical pressure, i.e., a pressure above its critical pressure, the liquid and vapor phases of the refrigerant are indistinguishable and the refrigerant is commonly referred to as a gas. When the refrigerant is at a supercritical pressure, the phase of the refrigerant does not change by heating or cooling the refrigerant.
In a conventional vapor compression system wherein the refrigerant is not compressed to a supercritical pressure, when the pressure of the refrigerant in the condenser is monitored, i.e., the high pressure heat exchanger, it is typically directly measured by a pressure sensor that penetrates the structure forming the condenser. In a transcritical system, the pressure in the gas cooler will generally be substantially higher than that found in a conventional condenser and it is undesirable to penetrate the structure forming the gas cooler because such a penetration increases the possibility of a subsequent leak. Other methods of determining the pressure of a refrigerant which is at a subcritical pressure using the temperature or other physical parameter of the refrigerant are also known, however, such methods will generally not be applicable to a refrigerant at a supercritical pressure.
The Gibbs Phase Rule can be used to determine the degrees of freedom in a system and thereby indicate the number of parameters required to determine the thermodynamic state of the fluid system and states:
p+f=c+2
wherein, p=the number of phases; f=number of degrees of freedom in the system, i.e., the number of required parameters; and c=number of components in the thermodynamic system. Thus, a single phase system will have one more degree of freedom than a similar two phase system. For example, the temperature of a refrigerant can be used to determine the pressure of the refrigerant when the refrigerant is at a subcritical pressure and in a two phase state. For a refrigerant at a supercritical pressure and limited to a single phase, however, two physical parameters, such as temperature, pressure, specific volume or density, are required to determine any other thermodynamic property of the refrigerant.
The present invention provides a method and apparatus for determining the pressure of a supercritical fluid within a heat exchanger without directly measuring the pressure of the fluid.
The present invention comprises, in one form thereof, a method of determining the supercritical pressure of a refrigerant in a heat exchanger in a transcritical vapor compression system wherein the method includes obtaining a plurality of measurements representative of the temperature of the refrigerant at spaced locations on the heat exchanger, identifying a first location based upon the plurality of measurements wherein the first location is the approximate location of the minimum temperature gradient of the refrigerant within the heat exchanger, and determining the pressure of the refrigerant within the heat exchanger based upon the identification of the first location.
The pressure of the refrigerant may be obtained by determining the approximate temperature of the refrigerant at the first location and determining the pressure at which the refrigerant has a maximum specific heat at a temperature equivalent to the temperature of the refrigerant at the first location. This may be done in various manners including the use of a look-up table.
The pressure of the refrigerant may also be obtained by determining the approximate temperature of the refrigerant at a second location spaced from the first location, determining the approximate change in specific enthalpy of the refrigerant between the first location and the second location (or other value that is a function of the change in specific enthalpy between the first and second locations), and determining the pressure of the refrigerant at the first location based upon the approximate temperature of the refrigerant at the second location and the approximate change in specific enthalpy between the first and second locations. In such a method, the heat exchanger may be cooled using ambient air and, when the second location is the heat exchanger outlet, the temperature of the refrigerant at the second location may be estimated to be equivalent to the temperature of the ambient air.
The approximate change in specific enthalpy between the first and second locations can be calculated using the following equation:
wherein:
is the heat transfer rate of the heat exchanger; and
The plurality of measurements representative of the temperature of the refrigerant at spaced locations on the heat exchanger can be obtained by various means including taking temperature measurements on the exterior surface of the heat exchanger or by obtaining strain measurements of the heat exchanger structure at the spaced locations.
The first location, corresponding to the point at which the refrigerant has a maximum specific heat and, thus, also has a minimal temperature gradient, may be identified by comparing the plurality of measurements and selecting a pair of adjacent measurements that define the minimal difference between adjacent measurements. Alternatively, the first location may be identified by the use of a curve based upon the plurality of measurements and the position of the measurements on the heat exchanger.
The current invention comprises, in another form thereof, a method of controlling the operation of a transcritical vapor compression system wherein the vapor compression system defines a closed loop circuit through which a refrigerant is circulated and includes therein, in serial order, a compressor, a first heat exchanger, an expansion device and a second heat exchanger wherein the refrigerant is at a supercritical pressure within the first heat exchanger. The method includes identifying a first location on the first heat exchanger wherein the first location is the approximate location of the minimum temperature gradient of the refrigerant within the heat exchanger and regulating the operation of the transcritical vapor compression system by controlling at least one characteristic of the first location.
The characteristic of the first location that is controlled may be the distance that separates the first location from the outlet of the first heat exchanger and/or the temperature of the refrigerant at the first location. Regulating the operation of the transcritical vapor compression system may include maintaining the distance between the first location and the outlet of the first heat exchanger at a relatively constant value. Regulating the operation of the system may alternatively include maintaining a desired temperature difference between refrigerant at the first location and refrigerant at the outlet of the first heat exchanger. In some embodiments, the temperature difference that is maintained in the regulation of the system may be a non-variable temperature difference, i.e., a constant value. When the first heat exchanger utilizes ambient air as a cooling medium, it may be advantageous to assume that the temperature of refrigerant at the outlet of the first heat exchanger is equivalent to the temperature of the ambient air.
The present invention comprises, in yet another form thereof, a transcritical vapor compression system that includes a closed loop circuit through which a refrigerant is circulated. The circuit includes, in serial order, a compressor, a first heat exchanger, an expansion device and a second heat exchanger and wherein the refrigerant is at a supercritical pressure within the first heat exchanger. A plurality of sensing devices are mounted on the first heat exchanger at spaced locations and each of the devices generate a signal representative of the temperature of the refrigerant within the first heat exchanger at a respective one of the spaced locations. The system also includes means for identifying a first location based upon the signals wherein the first location is the approximate location of the minimum temperature gradient of the refrigerant within the first heat exchanger and means for determining the pressure of the refrigerant within the first heat exchanger based upon the identification of the first location.
One advantage of the present invention is that some embodiments provide for the determination of the pressure of a supercritical refrigerant in a heat exchanger using measurements that can be taken on the exterior surface of the heat exchanger without requiring the penetration of the heat exchanger structure.
Another advantage of the present invention is that it can be used to monitor and regulate the supercritical pressure within a heat exchanger without directly measuring the refrigerant pressure within the heat exchanger.
The above-mentioned and other features and objects of this invention will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. Although the exemplification set out herein illustrates an embodiment of the invention, the embodiment disclosed below is not intended to be exhaustive or to be construed as limiting the scope of the invention to the precise form disclosed.
Referring to
In operation, refrigerant is compressed in compressor 12 to a supercritical pressure. The relatively warm, supercritical refrigerant is then cooled in gas cooler 14. The pressure of the refrigerant is then reduced to a subcritical pressure by expansion device 16. After passing through expansion device 16 the relatively low pressure refrigerant is in a liquid phase, or primarily in a liquid phase, when it enters evaporator 18. The liquid phase refrigerant is then converted to a gas phase in evaporator 18 thereby cooling the air passing over evaporator 18. The refrigerant vapor exiting evaporator 18 is then returned to compressor 12 and the cycle is repeated.
System 10 has numerous applications. For example, system 10 could be employed in a water heater with the first heat exchanger 14 being used to heat the water. Alternatively, system 10 could be employed as a refrigeration or air conditioning system wherein evaporator 18 is used to cool air that is then used to cool a refrigerated cabinet or interior building space.
In exemplary system 10 discussed herein, the refrigerant employed is carbon dioxide. The present invention, however, may alternatively employ other refrigerants suitable for use in a transcritical vapor compression system.
Also shown on
The operation of system 10 is also represented in
The thermodynamic cycle represented by AB′C′D′ reflects the operation of system 10 at a reduced capacity. In this second mode of operation, the conditions of the carbon dioxide at the inlet to compressor 12, represented by point A, are the same as in the first, normal, operating mode. In this second mode of operation, the carbon dioxide is compressed to a lesser pressure as shown by point B′ which represents the conditions of the carbon dioxide discharged from compressor 12. The carbon dioxide is then cooled in gas cooler 14 to the same outlet temperature as in the first mode of operation as represented by point C′ which lies on the same isotherm as point C. For example, if the carbon dioxide in gas cooler 14 were cooled to a common ambient air temperature in both modes of operation, points C and C′ would lie on the same isotherm as shown. As a result of the lower gas cooler pressure and common outlet temperature, point C′ is positioned to the right of point C on the chart of
In addition to the capacity of system 10, the coefficient of performance (COP) is also a function of the pressure of the supercritical carbon dioxide in gas cooler 14. Consequently, it is desirable to measure the pressure in gas cooler 14 to facilitate the monitoring and regulation of transcritical system 10.
As can be seen in
As depicted in
By taking a plurality of temperature measurements along the length of tube 13, e.g., at equally spaced sensing locations 34, the temperature variations between each adjacent pair of locations 34 can be determined. For example, as depicted in
h=cp*Tabsolute
wherein h is specific enthalpy, cp is specific heat, and Tabsolute is the absolute temperature in Rankine (tRankine=tFahrenheit+459.69).
The temperature at which the maximum specific heat value occurs can then be used to determine the pressure of the carbon dioxide within gas cooler 14 by using a look up table, a chart, or by solving the appropriate mathematical equations. For example, after plotting the data points represented in
Presented below is a lookup table that presents the temperature (° F.) of carbon dioxide at its inflection point (i.e., its maximum specific heat) and the corresponding pressure. Thus, for the example of
With reference to
Alternatively, the physical location of the maximum specific heat value within gas cooler 14 relative to the outlet of gas cooler 14 can be used in the determination of the pressure within gas cooler 14. As described above, the minimum temperature gradient within gas cooler 14 corresponds to the point at which the line BC intersects dashed line 28 wherein dashed line 28 is a locus of isotherm inflection points and maximum specific heat values. Once the physical location of this inflection point (INF) is known, the change in specific enthalpy, Δh, between the inflection point INF and the outlet of the gas cooler can be calculated using the following equation:
wherein Q is the amount of heat extracted from carbon dioxide gas between inflection point INF and the outlet of the gas cooler, m is the mass flow rate of the carbon dioxide through the gas cooler,
is the instantaneous heat transfer rate of the gas cooler, and dl is the differential length of the gas cooler. Assuming that
has constant value and that the carbon dioxide temperature at outlet 32 of gas cooler 14 equals the temperature of the ambient fluid surrounding gas cooler 14, the average heat transfer rate can be calculated using the following equation:
where α is the total heat transfer coefficient (including both convection and conduction), do is the outer diameter of gas cooler tube 13, and (Tavgamb−Tavgtube) is the average temperature difference between the cooling medium temperature, e.g., ambient air temperature, and the outer tube wall temperature. The outer diameter of gas cooler tube 13, the average temperature of the cooling medium and the average temperature of the gas cooler tube 13 between the inflection point INF and gas cooler outlet 32 can be measured. The heat transfer coefficient can be determined empirically as discussed in greater detail below. The value of
can be calculated using equation (2), however, this value is typically provided by the manufacturer of the heat exchanger and may also be determined empirically. Once the heat transfer rate is known, and assuming it to be a constant value, equation (1) can be rewritten to calculate the change in specific enthalpy using the following equation:
wherein ΔLINF is the length of gas cooler 14 between the inflection point INF and the outlet of the gas cooler. As can be seen in the schematic illustration of
With the change in specific enthalpy having been calculated, the gas cooler pressure may be determined using the pressure-enthalpy diagram for carbon dioxide as shown in
Alternative methods for determining the pressure from the change in specific enthalpy and outlet temperature may also be employed. For example, a lookup table containing specific enthalpy values for various isotherms and inflection points together with the corresponding pressures, or, the use of appropriate mathematical equations describing the location of the isotherms and inflection points and corresponding pressures could be used instead of the graphical method discussed above.
A specific example in which the gas cooler pressure is determined in accordance with one embodiment of the present invention will now be discussed. In this example, the ambient temperature is 100° F. and the gas cooler has a heat exchange tube 13 with an outer diameter (do) of 0.250 inches and a heat transfer rate of heat exchanger
that is assumed to have a constant value of approximately 2113 Btu/ft. The mass flow rate is 300 lbm/hr and the measured length of LINF is 4.76 ft. Substituting these values into equation (3) one obtains:
ΔhINF=(1/300)*2113*4.76=27.4 BTU/lbm
This value corresponds to a specific enthalpy variation per unit of length of:
(27.4 BTU/lbm)/4.76 ft=5.76 BTU/ft.lbm
Referring to
Instead of employing the graphical method described above, the pressure may also be found using a look-up table. The use of a lookup table will facilitate the implementation of the present invention using a microprocessor or logic module. The following table presents a list of pressure values and corresponding specific enthalpy values at 100° F. (corresponding to the specific enthalpy at outlet 32 for an ambient temperature of 100° F.), the specific enthalpy value at the inflection point INF, and the difference between the two specific enthalpy values. Once the difference in the specific enthalpy has been determined to be approximately 27.4 BTU/lbm, this value can be looked up in the Δh column and the pressure is found to be 1700 psia. Similar tables can be prepared for different outlet temperatures.
In another embodiment of the present invention, a more precise calculation of the gas cooler pressure can be made by taking into consideration the variation of heat transfer coefficient (α) with temperature and pressure and computing the heat transfer of the gas cooler using equation (2) set forth above. The pressure may then be determined as described above. This alternative method of computing the heat transfer rate may be particularly useful for providing more accurate results when the operating conditions within the gas cooler are nearing the critical point.
Alternative embodiments of the present invention may account for additional criteria including non uniformity of air flow velocity and temperature and carbon dioxide gas pressure drop along the gas cooler tube. For example, such an embodiment may utilize an experimental method that includes varying the operation of system 10 to compile a table of pressures, ambient temperatures, changes in specific enthalpy, and gas cooler lengths that may be used to determine the gas cooler pressure. This type of method could also take into account various other operating parameters such as the intermediate cooling temperature (for a system employing a two stage compressor), suction line heat exchanger efficiency, flash gas removal usage, gas cooler thermal conductivity, and approach temperature. This type of method may be advantageously employed on an existing carbon dioxide system when upgrading the system to include capacity and/or efficiency controls.
Once the pressure of the supercritical refrigerant within gas cooler 14 is known, the capacity and coefficient of performance (COP) of the system can be monitored and the operation of the system may also be controlled to effect changes in the capacity or COP.
With regard to
Similarly, in
At each ambient temperature, the cooling capacity and the COP each have a maximum value which occur at different pressures. Because the maximum values for capacity and COP occur at different pressures, it is not possible to maximize both the capacity and COP at the same time. The maximum capacity and COP values for specific ambient temperatures (which correspond to the gas cooler outlet temperature) illustrated in
The operation of system 10 may be controlled in a variety of ways to alter the pressure in gas cooler 14 and thereby regulate the capacity and COP of system 10. For example, compressor 12 may be a variable compressor that can be controlled to adjust the discharge pressure or expansion device 16 may be a variable expansion valve whereby adjustment of valve 16 can be used to control the operation of the system. Other methods of controlling the operation of a transcritical vapor compression system may include the control of an air blower associated with heat exchanger 14 or 18, various valving arrangements, or by controlling the quantity of refrigerant charge actively circulating through the system. For example, one method of controlling a transcritical vapor compression system is described by Manole in U.S. patent application Ser. No. 10/653,581 filed on Sep. 2, 2003 and entitled “Multi-Stage Vapor Compression System with Intermediate Pressure Vessel” which is hereby incorporated herein by reference.
With regards to the illustrative example discussed above, the gas cooler pressure was determined to be 1700 psia and the ambient/gas cooler outlet temperature was 100° F. As shown in
Referring again to
When the current gas cooler pressure differs from the desired pressure, it is possible to determine the desired distance LINF between the inflection point INF and the gas cooler outlet 32 that corresponds to the desired pressure of 1550 psia. First, the current specific enthalpy variation per unit length of gas cooler 14 is found by dividing the calculated change in specific enthalpy, ΔhINF, by the current actual length LINF of the gas cooler between inflection point INF and the gas cooler outlet. In the example set forth above, the specific enthalpy variation per unit length is found by dividing 27.4 Btu/lbm by 4.76 ft to thereby obtain 5.76 Btu/(lbm ft ° F.). The ΔhINF line segment 36′, shown in
Operation of system 10 may then be adjusted, e.g., by control of compressor 12 or expansion device 16, until the minimal temperature gradient measured on gas cooler 14 occurs 3.88 ft from gas cooler outlet 14. Alternatively, system 10 could be regulated to maximize either the capacity or COP of the system by employing a similar method and using either the Qmax curve 44 or the COPmax curve 46 instead of optimization curve 48 to determine the desired length of LINF.
Providing a system 10 wherein the pressure of gas cooler 14 may be varied to optimize either the capacity or efficiency of the system under changing load conditions, i.e., a system wherein the desired length of LINF is varied to address changing operating conditions, will typically be more expensive than a system which is operated to maintain LINF at a constant length. For many applications, however, e.g., water heaters and air conditioners in relatively stable environments, the operating conditions of the system may not be subject to large variations in operating loads and conditions. For such applications it may be suitable to provide a system 10 wherein the system is operated to maintain the length of LINF at a constant length. As can be seen in
In the schematic illustration of
Measurements may be taken along tube 13 of gas cooler 14 at locations 34 using a variety of different sensing devices. For example, the temperature of tube 13 may be measured directly using a temperature sensor or thermistor. Alternatively, strain gages may be used to measure the thermal expansion of tube 13. When using strain gage measurements, it is possible to convert the measurements to temperature readings, or, the strain gage measurements may be directly compared to identify the relative temperature differences between points 34 without converting such measurements into temperature readings. For example, in some embodiments of the present invention, strain gage measurements may be used to identify the location of the minimal temperature gradient within heat exchanger 14, which would correspond to a minimal change in strain per unit length, without determining a corresponding temperature reading.
The sensing devices generate signals representative of the sensed parameter. The signals may then be processed by a comparator or other suitable means. For example, an analog to digital converter may be employed to convert the sensing device signals to a digital format before the signals are processed by a suitable device such as a logic module or microprocessor. The signals are then processed as described above to determine the gas cooler pressure, optimal location or temperature of the inflection point on the gas cooler, or other desired parameter. This information may then be employed in the control and regulation of system 10, e.g., by a controller to adjust the operating parameters of compressor 12 or expansion device 16.
In the illustrated embodiment, gas cooler 14 is a conventional tube and fin heat exchanger that exchanges thermal energy with the ambient air. The present invention, however, may also be employed with other types of heat exchangers. For example, with appropriate modifications, the methods described above could be employed with a microchannel heat exchanger or a tube-within-a-tube heat exchanger that exchanges thermal energy between the refrigerant and a second heat exchange medium, such as water, conveyed within one of the tubes.
While this invention has been described as having an exemplary design, the present invention may be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains.
This application claims the benefit under Title 35, U.S.C. § 119(e) of U.S. Provisional Patent Application Ser. No. 60/505,817, entitled METHOD AND APPARATUS FOR DETERMINING SUPERCRITICAL PRESSURE IN A HEAT EXCHANGER, filed on Sep. 25, 2003.
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