The present invention relates to a refrigeration or air conditioning system, and more particularly, to a refrigerant system configured to operate at multiple capacity modes.
Refrigeration and heating or air conditioning systems (commonly called refrigerant systems) are generally configured with means for system unloading, thereby allowing the systems to improve temperature control accuracy, reliability, and energy efficiency.
Currently the most common means for system unloading is accomplished by unit cycling (i.e., turning the compressor on and off). However, unit cycling does not allow for tight temperature control, and therefore, commonly creates discomfort and/or undesired temperature variations if used to cool an occupied space. Additionally, unit cycling introduces system inefficiencies associated with unit cycling losses and the system must operate with a high refrigerant mass flow rate when the compressor is turned on.
A suction modulation valve is another means commonly utilized for system unloading. With a suction modulation valve unloading is accomplished by limiting the amount of refrigerant flow by partially closing the suction modulation valve. However, a suction modulation valve is relatively expensive and is inefficient for system capacity control due to flow throttling losses when the valve is in a partially closed position.
U.S. Pat. No. 7,353,660 to Lifson et al. discloses a multi-temperature cooling system with unloading. However, this system does not vapor inject refrigerant into an inter-stage of a multi-stage compressor assembly to achieve unloading. Additionally, the flow of refrigerant through the suction line from evaporator 68 to the port 54 of the compressor 52 cannot be throttled by a valve and directed through a bypass line to be injected into the inter-stage of the compressor to achieve unloading.
U.S. Pat. No. 6,860,114 to Jacobsen discloses a system capable of operating at different operational cooling stages. However, the valve 144 Jacobsen discloses in the bypass line is a check valve which only allows refrigerant to flow in one direction. Thus, the opening of valve 144 is controlled solely by pressure differential across it. Because valve 144 requires a specific pressure differential to open, both valve 144 and valve 134 cannot be opened simultaneously to achieve unloading by allowing refrigerant flow to both the first and second stages of compressor 60.
A refrigerant system capable of operating at multiple capacity modes includes an evaporator, a multi-stage compressor assembly, a first fluid flow path, a second fluid flow path, a first valve, and a second valve. The multi-stage compressor assembly has a first stage and a second stage. The first fluid flow path extends from the evaporator to the first stage of the multi-stage compressor assembly. The second fluid flow path connects to the first fluid flow path and to the multi-stage compressor assembly between the first stage and the second stage. The first valve is disposed along the first fluid flow path at or between the connection between the first fluid flow path and the second fluid flow path and the first stage. The first valve is responsive to control signals to selectively regulate flow of refrigerant to the first stage. The second valve is disposed along the second fluid flow path and is responsive to control signals to selectively regulate flow of refrigerant along the bypass line.
The heat exchanger 26 can include a condenser that condenses at least a portion of the refrigerant. Alternatively, heat exchanger 26 can be a gas cooler, where no condensation of refrigerant vapor takes place and the gas refrigerant is simply cooled to a lower temperature. The use of a gas cooler would be typical for systems that use CO2 as the system refrigerant.
The first valve 42 is positioned in the suction line 14 which provides a fluid flow path between the evaporator 16 and the multi-stage compressor assembly 18. The multi-stage compressor assembly 18 has the first stage 19 connected to the second stage 21 by the integral inter-stage line 20. Alternatively, the first stage 19 and second stage 21 can be separate compressor units each of which has a single compressive stage. The first stage 19 and second stage 21 interconnected in series by inter-stage line 20. Inter-stage line 20 can include piping or in certain design configurations the inter-stage line 20 can refer to a common plenum or integral compressor cavity connected between the first stage 19 and the second stage 21. The bypass line 22 connects to the suction line 14 upstream of the first valve 42 and bypasses the first stage 19 to connect to the inter-stage line 20 of the multi-stage compressor assembly 18. The second valve 44 is positioned in the bypass line 22 which provides a second fluid flow path extending between the evaporator 16 and the second stage 21 of the compressor assembly 18. The main flow line 24 (of which the suction line 14 is a part) extends serially through the heat exchanger 26, economizer heat exchanger 28, expansion device 30, evaporator 16, and multi-stage compressor assembly 18. The economizer line 32 connects to the main flow line 24 between the heat exchanger 26 and the economizer heat exchanger 28. The economizer line 32 extends through the economizer heat exchanger 28 to connect to the inter-stage line 20 of the multi-stage compressor assembly 18. Alternatively, the economizer line 32 can connect directly to the bypass line 22 prior to the connection of the bypass line 22 with the inter-stage line 20. In the embodiment shown, the economizer line valve 34 is disposed in the economizer line 32 downstream of the economizer heat exchanger 28.
The controller 40 controls the first valve 42, second valve 44, the economizer line valve 34, and the multi-stage compressor assembly 18. More specifically, the controller 40 controls the first valve 42, the second valve 44, and the economizer line valve 34, which are all configured to open and close in response to control signals therefrom to regulate the flow of refrigerant through the system 10.
In one embodiment, the valves 34, 42, and 44 are low cost solenoid valves that are selectively energized to open or close in response to the control signals of the controller 40. Whether valves 34, 42, and 44 are open or closed is dictated by the capacity mode desired for the system 10. In this manner, multiple system 10 capacity modes (each resulting in a different capacity) can be achieved efficiently at low cost.
In another embodiment (not shown), first valve 42 and second valve 44 are combined in a valve assembly that is a three way valve allowing the valve assembly to be positioned in the suction line 14 and communicate with the bypass line 22. The valve assembly can be opened and closed to regulate the flow of refrigerant along both the suction line and the bypass line. Similarly, economizer line valve 34 can be a three way valve assembly, where it combines the function of valve 34 and 44.
The suction line 14 transports refrigerant from the evaporator 16 to the first stage 19. In the first stage, the refrigerant transported through the suction line 14 is compressed to a higher pressure before being discharged into the inter-stage line 20. In the second stage 21, the refrigerant is further compressed to a pressure higher than that of the refrigerant exiting the first stage 19. In
The bypass line 22 connects to suction line 14 and is capable of transporting refrigerant bypassed from the suction line 14 and the first stage 19 to the inter-stage line 20 of the multi-stage compressor assembly 18. Thus, refrigerant transported in the bypass line 22 is undergoes only minimal compression by the first stage 19 just to overcome throttling losses within the multi-stage compressor assembly 18.
As previously indicated, the main flow line 24 interconnects several components of the system 10 in a refrigeration or air conditioning cycle. More particularly, the main flow line 24 transports compressed refrigerant from the multi-stage compressor assembly 18 through the heat exchanger 26 where the refrigerant (previously a vapor) condenses to a liquid. The main flow line 24 directs the fluid through the economizer heat exchanger 28 (which can be operational or idle depending on the capacity mode of the system 10) and through the expansion device 30, where the refrigerant is throttled to a lower pressure liquid-vapor mixture. From the expansion device 30, the main flow line 24 directs the refrigerant to the evaporator 16 where the liquid portion of the refrigerant evaporates to cool a required space. The refrigerant, in vapor state, is transported from the evaporator 16 to the multi-stage compressor assembly 18 via the suction line 14.
In a first capacity mode of operation for the system 10, the controller 40 signals the first valve 42 to open (or remain open) and the second valve 44 to close (or remain closed). This arrangement allows refrigerant to flow only through the suction line 14 to the first stage 19 of the multi-stage compressor assembly 18. The controller 40 also signals the economizer line valve 34 to open. The opening of the economizer line valve 34 allows a portion of the refrigerant from the main flow line 24 to flow through the economizer line 32. While traveling along the economizer line 32, the refrigerant passes through the heat recipient portion 36 of the economizer heat exchanger 28. After passing through the heat recipient portion 36 the refrigerant (in vapor state) has a pressure greater than that of the refrigerant exiting the evaporator 16. The refrigerant flows through the economizer line 32 and is vapor injected into the inter-stage line 20 of the multi-stage compressor assembly 18. In the first capacity mode, the portion of refrigerant continuing on the main flow line 24 and passing through the heat donor portion 38 receives additional cooling from the refrigerant flow passing through the heat recipient portion 36. The refrigerant is throttled in the expansion device 30 and then continues along the main flow line 24 to the evaporator 16. In the first capacity mode, the cooling capacity of the system 10 is at its highest level with a capacity of about 150% of that of the second capacity mode (discussed subsequently).
In the second capacity mode of operation for the system 10, the controller 40 signals the first valve 42 to open (or remain open) and the second valve 44 to close (or remain closed). This arrangement allows refrigerant to flow only through the suction line 14 to the first stage 19 of the multi-stage compressor assembly 18. The controller 40 also signals the economizer line valve 34 to close. Thus, the refrigerant only flows along the main flow line 24 and is not economized (does not receive heat from the heat donor portion 36). In the second capacity mode, the system 10 can be thought of as operating in a basic or standard refrigeration cycle, and thus, is considered at full 100% capacity.
In a third capacity mode, the controller 40 signals the first valve 42 to open (or remain open) and the second valve 44 to open (or remain open). This arrangement allows a portion of the refrigerant from the evaporator 16 to flow through the suction line 14 to the first stage 19 and to the second stage 21 while also allowing a second portion of the refrigerant to flow through the bypass line 22 from the inter-stage line 20 of the multi-stage compressor assembly 18 to the suction line 14. The controller 40 also signals the economizer line valve 34 to close (or remain closed). Thus, the refrigerant only flows along the main flow line 24 and is not economized (does not receive heat from the heat donor portion 36). The third capacity mode allows the system 10 to achieve a capacity of about 45% of that of the second capacity mode.
In a fourth capacity mode of operation for the system 10, the controller 40 signals the first valve 42 to close (or remain closed) and the second valve 44 to open (or remain open). This arrangement allows refrigerant to only flow through the bypass line 22 to the inter-stage line 20 of the multi-stage compressor assembly 18. Therefore, the first stage 19 is bypassed entirely. The controller 40 also signals the economizer line valve 34 to close (or remain closed). Thus, the refrigerant only flows along the main flow line 24 and is not economized (does not receive heat from the heat donor portion 36). The fourth capacity mode allows the system 10 to achieve a capacity of about 35% of that of the second capacity mode.
In a fifth capacity mode, the controller 40 signals the first valve 42 to close (or remain closed) and the second valve 44 to open (or remain open). This arrangement allows refrigerant to only flow through the bypass line 22 to the inter-stage line 20 of the multi-stage compressor assembly 18. Therefore, the first stage 19 is bypassed entirely. The controller 40 also signals the economizer line valve 34 to open (or remain open). The opening of the economizer line valve 34 allows a portion of the refrigerant from the main flow line 24 to flow through the economizer line 32 (and through the heat recipient portion 36 of the economizer heat exchanger 28) and be vapor injected into the inter-stage line 20 of the multi-stage compressor assembly 18.
In a sixth capacity mode of operation for the system 10, the controller 40 signals the first valve 42 to open (or remain open) and the second valve 44 to open (or remain open). This arrangement allows a portion of the refrigerant from the evaporator 16 to flow through the suction line 14 to the first stage 19 and to the second stage 21. The controller 40 also signals the economizer line valve 34 to open (or remain open). The opening of the economizer line valve 34 allows some amount of the refrigerant from the main flow line 24 to flow through the economizer line 32 (and through the heat recipient portion 36 of the economizer heat exchanger 28) and either be vapor injected into the inter-stage line 20 or flow through the bypass line 22 to the suction line 14.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2010/036138 | 5/26/2010 | WO | 00 | 11/29/2011 |
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WO2010/144255 | 12/16/2010 | WO | A |
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