This disclosure relates generally to refrigeration systems and methods of their use. More particularly, in certain embodiments, this disclosure relates to hot gas defrost using medium temperature compressor discharge.
Refrigeration systems are used to regulate environmental conditions within an enclosed space. Refrigeration systems are used for a variety of applications, such as in supermarkets and warehouses, to cool stored items. For example, refrigeration systems may provide cooling operations for refrigerators and freezers.
During operation of refrigeration systems, ice may build up on evaporators. These evaporators need to be defrosted to remove ice buildup and prevent loss of performance. Previous evaporator defrost processes are limited in terms of their efficiency and effectiveness. For example, using previous technology, defrost processes may take a relatively long time and consume a relatively large amount of energy. In some cases, previous technology may be incapable of providing adequate defrosting, for instance, in cases where a relatively large number of evaporators need to be defrosted in a multiple-evaporator refrigeration system.
This disclosure provides technical solutions to the problems of previous technology, including those described above. For example, a refrigeration system is described that facilitates improved evaporator defrost using a medium temperature discharge gas. The refrigeration system also uses a defrost-mode expansion valve that depressurizes high pressure, high temperature discharge gas provided from one or more medium-temperature compressors. The expanded refrigerant is provided to defrost one or more evaporators of the refrigeration system. The pressure of the heated refrigerant may be adjusted by the defrost-mode expansion valve to achieve improved defrost performance. In some case, evaporators of the refrigeration system may be configured to support operation at increased pressures (e.g., of about 45 bar or 60 bar) to facilitate this new defrost process.
Embodiments of this disclosure may provide improved defrost operations to evaporators of refrigeration systems, such as CO2 transcritical refrigeration systems. The refrigeration system of this disclosure facilitates the development of an increased pressure differential to drive the flow of refrigerant during defrost processes. The refrigeration system provides a higher mass flow rate of refrigerant than was available in previous systems in order to defrost multiple evaporators rapidly and efficiently. Higher refrigerant temperatures (e.g., of about 110° C.) can be achieved for improved evaporator defrost operations. During defrost operations, low-temperature compressors can operate under regular discharge pressures such that refrigeration processes continue efficiently for evaporators that are not being defrosted. Defrost operations can continue even in cases when low-temperature compressors are not present or during low load scenario. Certain embodiments may include none, some, or all of the above technical advantages. One or more other technical advantages may be readily apparent to one skilled in the art from the figures, descriptions, and claims included herein.
In an embodiment, a refrigeration system includes one or more medium temperature (MT) compressors, a gas cooler located downstream from the one or more MT compressors, a defrost-mode valve located downstream from the one or more MT compressors, a first evaporator unit located downstream from the gas cooler, and a controller communicatively coupled to the defrost-mode valve. The one or more MT compressors are configured to compress refrigerant. The gas cooler is configured to receive at least a portion (e.g., up to all when all evaporator units in refrigeration mode) of the compressed refrigerant and facilitate heat transfer from the received refrigerant to the ambient air, thereby cooling the refrigerant. The first evaporator unit includes an evaporator and is configured to receive a portion of the refrigerant cooled by the gas cooler when the first evaporator unit is operated in a refrigeration mode. The controller is configured to determine that operation of the first evaporator unit in a defrost mode is indicated. After determining that operation of the first evaporator unit in the defrost mode is indicated, the controller causes the first evaporator unit to operate in a defrost mode. Causing the first evaporator unit to operate in the defrost mode includes causing the defrost-mode valve to at least partially open. The defrost-mode valve is configured, when open, to divert a portion of the compressed refrigerant provided by the one or more MT compressors away from the gas cooler, expand the diverted portion of the refrigerant, and allow the expanded portion of the refrigerant to flow to the first evaporator unit, thereby defrosting an evaporator of the first evaporator unit.
For a more complete understanding of the present disclosure, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which:
Embodiments of the present disclosure and its advantages are best understood by referring to
As described above, prior to this disclosure, defrost operations of refrigeration systems suffered from certain inefficiencies and drawbacks. The refrigeration system of this disclosure provides improvements in defrost performance and energy efficiency. In some cases, the refrigeration system may ensure that all appropriate defrost operations can be performed when needed, while previous technology may have been limited in the number of evaporators that could be defrosted at a given time or over a given period of time.
The refrigeration system of this disclosure may be a CO2 transcritical refrigeration system. Transcritical refrigeration systems differ from conventional refrigeration systems in that transcritical systems circulate refrigerant that becomes a supercritical fluid above the critical point. As an example, the critical point for carbon dioxide (CO2) is 31° C. and 73.8 MPa, and above this point, CO2 becomes a homogenous mixture of vapor and liquid that is called a supercritical fluid. This unique characteristic of transcritical refrigerants is associated with certain operational differences between transcritical and conventional refrigeration systems. For example, transcritical refrigerants are typically associated with discharge temperatures that are higher than their critical temperatures and discharge pressures that are higher than their critical pressures. When a transcritical refrigerant is at or above its critical temperature and/or pressure, the refrigerant may become a “supercritical fluid”—a homogenous mixture of gas and liquid. Supercritical fluid does not undergo phase change processes in a gas cooler as occurs in a condenser of a conventional refrigeration system circulating traditional refrigerant. Rather, supercritical fluid is cooled to a lower temperature in the gas cooler. Stated differently, the gas cooler in a transcritical refrigeration system receives and cools supercritical fluid and the transcritical refrigerant undergoes a partial state change from gas to liquid as it is discharged from an expansion valve.
Refrigerant conduit subsystem 102 facilitates the movement of refrigerant (e.g., CO2) through a refrigeration cycle such that the refrigerant flows in the refrigeration mode as illustrated by the arrows in
Gas cooler 104 is generally operable to receive refrigerant (e.g., from MT compressor(s) 134 or oil separator 122) and apply a cooling stage to the received refrigerant. In some embodiments, gas cooler 104 is a heat exchanger comprising cooler tubes configured to circulate the received refrigerant and coils through which ambient air is forced. Inside gas cooler 104, the coils may absorb heat from the refrigerant and dissipates it to the ambient air, thereby cooling the refrigerant.
Cooled refrigerant from gas cooler 104 is provided to expansion valve 106. Expansion valve 106 is configured to receive gas refrigerant from gas cooler 104 and reduce the pressure of the received refrigerant. In some embodiments, this reduction in pressure causes some of the refrigerant to vaporize. As a result, mixed-state refrigerant (e.g., refrigerant vapor and liquid refrigerant) may be discharged from expansion valve 106. In some embodiments, this mixed-state refrigerant is discharged to flash tank 108. When outdoor temperatures are low (e.g., such as in the winter), valve 106 can be controlled to maintain a sufficient pressure in the gas cooler 104 to ensure that temperatures of the refrigerant provided for defrost are high enough to defrost evaporators(s) 116, 130 being defrosted, when at least one of the evaporator units 110a,b, 124a,b is operated in the defrost mode illustrated in
Flash tank 108 is configured to receive mixed-state refrigerant and separate the received refrigerant into flash gas and liquid refrigerant. Typically, the flash gas collects near the top of flash tank 108 and the liquid refrigerant is collected in the bottom of flash tank 108. In some embodiments, the liquid refrigerant flows from flash tank 108 and provides cooling to the MT evaporator units 110a,b and LT evaporator units 124a,b.
When operated in refrigeration mode (see
When the MT evaporator unit 110a is operating in the refrigeration mode illustrated in
When the MT evaporator unit 110a is operating in the defrost mode illustrated in
Valves 112 and 118 may be in communication with controller 170, and the controller 170 may provide instructions for adjusting the valves 112, 118 to open or closed positions to achieve the configuration of
In some embodiments, the defrost-mode expansion valve 142 may be opened to achieve a predefined output pressure. For example, the refrigerant may be provided from the defrost-mode expansion valve 142 at a pressure that is at least somewhat higher than (e.g., 10% or more greater than) the pressure of refrigerant in the flash tank 108. In some embodiments, the defrost-mode expansion valve 142 outputs refrigerant at a pressure of about (e.g., within about 5% of) 841 psig. In such embodiments, the evaporator 116 is rated for pressures of at least 870 psig. In some embodiments, the defrost-mode expansion valve 142 outputs refrigerant at a pressure of about (e.g., within about 5% of) 624 psig. In such embodiments, the evaporator 116 is rated for pressures of at least 650 psig.
Once defrost mode operation is complete, the controller 170 may end defrost mode operation by closing defrost-mode expansion valve 142, closing first valve 112, and opening second valve 118 to return to the refrigeration mode configuration illustrated in
Refrigerant from the MT evaporator units 110a,b that are operating in refrigeration mode (i.e., MT evaporator units 110a and 110b in
LT evaporator units 124a,b are generally similar to the MT evaporator units 110a,b but configured to operate at lower temperatures (e.g., for deep freezing applications near about −30° C. or the like). When operated in refrigeration mode (see
When the LT evaporator unit 124a is operating in the refrigeration mode illustrated in
When the LT evaporator unit 124a is operating in the defrost mode illustrated in
Valves 126 and 132 may be in communication with controller 170, and the controller 170 may provide instructions for adjusting the valves 126, 132 to open or closed positions to achieve the configuration of
In some embodiments, the defrost-mode expansion valve 142 may be opened to achieve a predefined output pressure. For example, the refrigerant may be provided from the defrost-mode expansion valve 142 at a pressure that is at least somewhat higher than (e.g., 10% or more greater than) the pressure of refrigerant in the flash tank 108. In some embodiments, the defrost-mode expansion valve 142 outputs refrigerant at a pressure of about (e.g., within about 5% of) 841 psig. In such embodiments, the evaporator 130 is rated for pressures of at least 870 psig. In some embodiments, the defrost-mode expansion valve 142 outputs refrigerant at a pressure of about (e.g., within about 5% of) 624 psig. In such embodiments, the evaporator 130 is rated for pressures of at least 650 psig.
Once defrost mode operation is complete, the controller 170 may end defrost mode operation by closing defrost-mode expansion valve 142, closing first valve 126, and opening second valve 132 to return to the refrigeration mode configuration illustrated in
Refrigerant from the LT evaporator units 124a,b that are operating in refrigeration mode (i.e., LT evaporator units 124a and 124b in
Flash gas bypass valve 138 may be located in refrigerant conduit connecting the flash tank 108 to the MT compressors 120 and configured to open and close to permit or restrict the flow of flash gas discharged from flash tank 108. In some embodiments, controller 170 controls the opening and closing of flash gas bypass valve 138. As depicted in
The oil separator 122 may be located downstream the MT compressors 120. The oil separator 122 is operable to separate compressor oil from the refrigerant. The refrigerant is provided to the gas cooler 104, while the oil may be collected and returned to the MT compressors 120, as appropriate.
The defrost-mode expansion valve 142 is located downstream from the oil separator 122 and in fluid communication with the MT evaporator units 110a,b and LT evaporator units 124a,b via fluid conduits 146a-d. In the example of
In some embodiments, each of the refrigerant conduits 146a-d includes a corresponding controllable valve 148a-d to adjust the flow of refrigerant through the corresponding conduit 146a-d. This may facilitate control of the distribution of refrigerant to two or more evaporator units 110a,b, 124a,b that are operated in defrost mode at the same time. Valves 148a-d may be in communication with and controlled by controller 170. An optional pressure-relief valve 150 may be in line with refrigerant conduits 146a-d, as illustrated in
A temperature and/or pressure sensor 144 may be located downstream of the defrost-mode expansion valve 142. The temperature and/or pressure sensor 144 measures properties of the refrigerant that is to be provided to defrost evaporators 116, 130. The controller 170 is in communication with the temperature and/or pressure sensor 144 and may use the measured property(ies) to adjust the defrost-mode expansion valve 142. For example, if refrigerant pressure downstream from the defrost-mode expansion valve 142 is greater than a threshold value (e.g., indicated by the controller's instructions 178), the controller 170 may cause the defrost-mode expansion valve 142 to be adjusted, such that the refrigerant pressure is decreased.
As described above, controller 170 is in communication with at least the defrost-mode expansion valve 142, valves 112, 118 of the MT evaporator units 110a,b, and valves 126, 132 of the LT evaporator units 124a,b. The controller 170 adjusts operation of components of the refrigeration system 100 to operate the evaporator units 110a,b, 124a,b in refrigeration mode or defrost mode as appropriate. The controller includes a processor 172, memory 174, and input/output (I/O) interface 176. The processor 172 includes one or more processors operably coupled to the memory 174. The processor 172 is any electronic circuitry including, but not limited to, state machines, one or more central processing unit (CPU) chips, logic units, cores (e.g. a multi-core processor), field-programmable gate array (FPGAs), application specific integrated circuits (ASICs), or digital signal processors (DSPs) that communicatively couples to memory 174 and controls the operation of refrigeration system 100.
The processor 172 may be a programmable logic device, a microcontroller, a microprocessor, or any suitable combination of the preceding. The processor 172 is communicatively coupled to and in signal communication with the memory 174. The one or more processors are configured to process data and may be implemented in hardware or software. For example, the processor 172 may be 8-bit, 16-bit, 32-bit, 64-bit or of any other suitable architecture. The processor 172 may include an arithmetic logic unit (ALU) for performing arithmetic and logic operations, processor registers that supply operands to the ALU and store the results of ALU operations, and a control unit that fetches instructions from memory 174 and executes them by directing the coordinated operations of the ALU, registers, and other components. The processor 172 may include other hardware and software that operates to process information, control the refrigeration system 100, and perform any of the functions described herein (e.g., with respect to
The memory 174 includes one or more disks, tape drives, or solid-state drives, and may be used as an over-flow data storage device, to store programs when such programs are selected for execution, and to store instructions and data that are read during program execution. The memory 174 may be volatile or non-volatile and may include ROM, RAM, ternary content-addressable memory (TCAM), dynamic random-access memory (DRAM), and static random-access memory (SRAM). The memory 174 is operable (e.g., or configured) to store information used by the controller 170 and/or any other logic and/or instructions for performing the function described in this disclosure. For example, the memory 174 may store instructions 178 for performing the functions of the controller 170 described in this disclosure. The instructions 178 may include, for example, a schedule for performing defrost mode operations, threshold temperature and/or pressure levels for determining when defrost is complete (e.g., based on information from sensors 156, 158 or other sensors of the refrigeration system 100), and the like.
The I/O interface 176 is configured to communicate data and signals with other devices. For example, the I/O interface 176 may be configured to communicate electrical signals with components of the refrigeration system 100 including the compressors 120, 134, gas cooler 104, valves 106, 112, 114, 118, 126, 128, 132, 138, 140, 142, 148a-d, evaporators 116, 130, and sensors 156, 158. The I/O interface 176 may be configured to communicate with other devices and systems. The I/O interface 176 may provide and/or receive, for example, compressor speed signals, compressor on/off signals, temperature signals, pressure signals, temperature setpoints, environmental conditions, and an operating mode status for the refrigeration system 100 and send electrical signals to the components of the refrigeration system 100. The I/O interface 176 may include ports or terminals for establishing signal communications between the controller 170 and other devices. The I/O interface 176 may be configured to enable wired and/or wireless communications.
Although this disclosure describes and depicts refrigeration system 100 including certain components, this disclosure recognizes that refrigeration system 100 may include any suitable components. As an example, refrigeration system 100 may include one or more additionally sensors configured to detect temperature and/or pressure information. In some embodiments, each of the compressors 120, 134, gas cooler 104, flash tank 108, and evaporators 116, 130 include one or more sensors.
In an example operation of the refrigeration system 100, the refrigeration system 100 is initially operating with all evaporator units 110a,b, 124a,b in the refrigeration mode, as illustrated in
At some point during operation of the refrigeration system 100, the controller 170 determines that defrost mode operation is needed for the first MT evaporator unit 110a and the first LT evaporator unit 124a. For example, the first MT evaporator unit 110a and the first LT evaporator unit 124a may be scheduled for defrost at the same time that has just been reached. After determining that the defrost mode operation is indicated, the controller 170 causes the first MT evaporator 110a and the first LT evaporator 124a to be configured according to
With the defrost-mode expansion valve 142 at least partially open and the evaporator units 110a and 124a configured as shown in
At step 406, the controller 170 causes the first valve 112, 126 to open and the second valve 118, 132 to close in the evaporator unit 110a,b, 124a,b for which defrost mode operation was indicated at step 402. This achieves the defrost mode configuration illustrated in
At step 408, the controller 170 at least partially opens the defrost-mode expansion valve 142. After being opened, the defrost-mode expansion valve 142 allows heated refrigerant output by the MT compressor(s) 120 (or from oil separator 122) to be provided to the evaporator unit 110a,b, 124a,b for which defrost operation was indicated at step 402. In some cases (e.g., where defrost mode operation is indicated for multiple evaporator units 10a,b, 124a,b), the controller 170, at step 410, may adjust valves 148a-d to control flow of heated refrigerant to the evaporator units 110a,b, 124a,b for which defrost mode operation was indicated at step 402. This may facilitate improved control over the defrost process (e.g., if a greater flow rate of refrigerant is needed for one evaporator type than another).
At step 412, the controller 170 may determine whether the properties of the refrigerant received from defrost-mode expansion valve 142 are appropriate for defrosting the evaporator 116, 130 for which defrost mode was indicated at step 402. For example, controller 170 may use a temperature and/or pressure measured by sensor 144 to determine if the refrigerant provided from defrost-mode expansion valve 142 can be received by the evaporator(s) 116, 130 without damaging the evaporator(s) 116, 130. For instance, if a refrigerant pressure measured by sensor 144 exceeds a pressure rating of the evaporator(s) 116, 130 being defrosted, then the refrigerant properties are not appropriate for defrosting the evaporator(s) 116, 130.
If the refrigerant properties are not appropriate for defrost at step 412, the controller 170 may proceed to step 414 where the defrost-mode expansion valve 142 is adjusted to bring the refrigerant properties into line with what is needed for effective defrost. For example, the defrost-mode expansion valve 142 may be adjusted to achieve a pressure that is within the specifications of the evaporator(s) 116, 130 being defrosted. Once the appropriate conditions are satisfied at step 412, the controller 170 proceeds to step 416.
At step 416, the controller 170 determines whether defrost conditions are satisfied for ending defrost mode operation. The defrost conditions may be indicated by the instructions 178 stored in the memory 174 of the controller 170. For example, the defrost conditions may indicate that defrost mode operation must be performed for a predefined period of time. As another example, the defrost conditions may indicate that an output temperature at or near the positions of sensor 156, 158 must increase to at least a predefined temperature (e.g., of about 11° C.) before defrost mode operation is complete. If the defrost conditions are not met, the controller 170 proceeds to step 418 to wait a period of time before returning to step 412.
If the defrost conditions of step 416 are satisfied, the controller 170 proceeds to step 404 and returns to operating in the refrigeration mode. In order to operate in the refrigeration mode at step 404, the controller 170 may cause the first valve 112, 126 to close and the second valve 118, 132 to open. If no other evaporator unit 110a,b, 124a,b is operating in the defrost mode, the defrost-mode expansion valve 142 may be closed.
Modifications, additions, or omissions may be made to method 400 depicted in
While several embodiments have been provided in the present disclosure, it should be understood that the disclosed systems and methods might be embodied in many other specific forms without departing from the spirit or scope of the present disclosure. The present examples are to be considered as illustrative and not restrictive, and the intention is not to be limited to the details given herein. For example, the various elements or components may be combined or integrated in another system or certain features may be omitted, or not implemented.
In addition, techniques, systems, subsystems, and methods described and illustrated in the various embodiments as discrete or separate may be combined or integrated with other systems, modules, techniques, or methods without departing from the scope of the present disclosure. Other items shown or discussed as coupled or directly coupled or communicating with each other may be indirectly coupled or communicating through some interface, device, or intermediate component whether electrically, mechanically, or otherwise. Other examples of changes, substitutions, and alterations are ascertainable by one skilled in the art and could be made without departing from the spirit and scope disclosed herein.
To aid the Patent Office, and any readers of any patent issued on this application in interpreting the claims appended hereto, applicants note that they do not intend any of the appended claims to invoke 35 U.S.C. § 112(f) as it exists on the date of filing hereof unless the words “means for” or “step for” are explicitly used in the particular claim.