초록 ▼

A condenser unit including a compressor for compressing a refrigerant vapor to provide a superheated refrigerant vapor exerting a head pressure, and a condenser for receiving the superheated refrigerant vapor and condensing the superheated refrigerant vapor therein, the condenser being located in an

A condenser unit including a compressor for compressing a refrigerant vapor to provide a superheated refrigerant vapor exerting a head pressure, and a condenser for receiving the superheated refrigerant vapor and condensing the superheated refrigerant vapor therein, the condenser being located in an uncontrolled space with air therein at an ambient temperature. The condenser unit also includes a flow control means for controlling flow of the superheated refrigerant vapor from the compressor into the condenser, a rotatable condenser fan for moving air past the condenser to dissipate heat from the condenser, and a controller for controlling the flow control means and the speed of rotation of the condenser fan based on at least one preselected parameter, to maintain the head pressure within a predetermined range thereof.

대표청구항 ▼

1. A method of operating a condenser unit for providing a volume of refrigerant at a pressure within a predetermined range sufficient to provide a preselected minimum pressure differential, the method comprising: (a) compressing the refrigerant in vapor form in a compressor included in the condenser

1. A method of operating a condenser unit for providing a volume of refrigerant at a pressure within a predetermined range sufficient to provide a preselected minimum pressure differential, the method comprising: (a) compressing the refrigerant in vapor form in a compressor included in the condenser unit to provide a superheated refrigerant vapor exerting a head pressure;(b) condensing the superheated refrigerant vapor in a condenser module contained within a single core included in the condenser unit to provide a liquid refrigerant, the condenser module being located in an uncontrolled space in which air surrounding the condenser module is at an ambient temperature;(c) separating the condenser module into at least two segments, each segment including a separate refrigerant line;(d) directly connecting the refrigerant line of a first segment of the condenser module to the compressor and providing a valve in the refrigerant line of a second segment of the condenser module controlled by a condenser control circuit for controlling movement of the superheated refrigerant vapor from the compressor into the second segment of the condenser module for discretely apportioning a selected volume available in the condenser module to receive the refrigerant;(e) providing a fan control circuit for controlling a rate at which the refrigerant condenses in the condenser module by controlling a condenser fan motor included in the condenser unit to change a speed of rotation of a condenser fan positioned to move air over the condenser module;(f) with a controller, controlling the valve and the condenser fan motor via the condenser control circuit and the fan control circuit respectively, to maintain the pressure within the predetermined range thereof, wherein the controller is configured: when the pressure is below the predetermined range, to provide a gross adjustment to the pressure by selectively closing the valve associated with the second segment to reduce the selected volume available in the condenser module to receive the refrigerant and simultaneously to provide a refined adjustment to the pressure by selectively adjusting the speed of rotation of the fan, for increasing the pressure to within the predetermined range; andwhen the pressure is above the predetermined range, to provide a gross adjustment to the pressure by selectively opening the valve associated with the second segment to increase the selected volume available in the condenser module to receive the refrigerant, and simultaneously to provide a refined adjustment to the pressure by selectively adjusting the speed of rotation of the fan, for decreasing the pressure to within the predetermined range; and(g) wherein when the ambient temperature is below a threshold level, simultaneously (i) reducing the speed of rotation of the fan and (ii) reducing the selected volume available in the condenser module by closing off at least one of the segments of the condenser module. 2. A method of operating a refrigeration system for providing a refrigerant at a pressure within a predetermined range sufficient to provide a preselected minimum pressure differential, the method comprising: (a) compressing the refrigerant in vapor form in a compressor included in the condenser unit to provide a superheated refrigerant vapor exerting a head pressure;(b) condensing the superheated refrigerant vapor in a condenser module contained within a single core included in the condenser unit to provide a liquid refrigerant, the condenser module being located in an uncontrolled space in which air surrounding the condenser module is at an ambient temperature;(c) separating the condenser module into two segments, each segment including a separate refrigerant line;(d) causing the refrigerant to at least partially evaporate in an evaporator assembly through which the refrigerant is circulatable, to transfer heat to the refrigerant from air in a controlled space;(e) directly connecting the refrigerant line of a first segment of the condenser module to the compressor and providing a valve in the refrigerant line of a second segment of the condenser module controlled by a condenser control circuit for controlling movement of the superheated refrigerant vapor from the compressor into the second segment of the condenser module for discretely apportioning a selected volume available in the condenser module to receive the refrigerant;(f) providing a fan control circuit for controlling a rate at which the refrigerant condenses in the condenser module by controlling a condenser fan motor included in the condenser unit to change a speed of rotation of a condenser fan positioned to move air over the condenser module;(g) with a controller, controlling the valve and the condenser fan motor via the condenser control circuit and the fan control circuit respectively, to maintain the refrigerant at a pressure within a predetermined range sufficient to provide an appropriate pressure differential across an expansion valve, wherein the controller is configured: when the pressure is below the predetermined range, to provide a gross adjustment to the pressure by selectively closing adjust the valve associated with the second segment to reduce the selected volume available in the condenser module to receive the refrigerant and simultaneously to provide a refined adjustment to the pressure by selectively adjusting the speed of rotation of the fan in order to increase the pressure, until the pressure is within the predetermined range; andwhen the pressure is above the predetermined range, to provide a gross adjustment to the pressure by selectively opening the valve associated with the second segment to increase the selected volume available in the condenser module to receive the refrigerant and simultaneously to provide a refined adjustment to the pressure by selectively adjusting the speed of rotation of the fan in order to decrease the pressure, until the pressure is within the predetermined range; and(h) wherein when the ambient temperature is below a threshold level, simultaneously (i) reducing the speed of rotation of the fan and (ii) reducing the selected volume available in the condenser module by closing off at least one of the segments of the condenser module. 3. The method as recited in claim 1, further comprising: determining that the pressure is below the predetermined range, providing a gross adjustment by closing the valve associated with the second segment to reduce the selected volume available in the condenser module to receive the refrigerant, and simultaneously providing a refined adjustment to the pressure by selectively increasing the speed of rotation of the fan, for adjusting the pressure to within the predetermined range; anddetermining that the pressure is above the predetermined range, providing a gross adjustment by opening the valve associated with the second segment to increase the selected volume available in the condenser module to receive the refrigerant, and simultaneously providing a refined adjustment to the pressure by selectively decreasing the speed of rotation of the fan, for adjusting the pressure to within the predetermined range. 4. The method as recited in claim 1, wherein the two segments each represent fifty percent of a total volume available in the condenser module to receive the refrigerant. 5. The method as recited in claim 1, wherein there is at least a third segment for the condenser module, providing a valve between the compressor and the line of the third segment controlled by the condenser control circuit for controlling movement of the superheated refrigerant vapor from the compressor into the third segment of the condenser module for discretely apportioning the selected volume available in the condenser module to receive the refrigerant, the third segment selectively providing a more refined gross adjustment to the pressure when combined with the first segment and the second segment. 6. The method as recited in claim 1, the condenser fan always rotating so long as the refrigerant is moving through the condenser module. 7. The method as recited in claim 6, the fan circulating air over the second segment even when the valve is closed. 8. The method as recited in claim 1, decreasing the selected volume available in the condenser module to receive the refrigerant when the valve is closed. 9. The method as recited in claim 1, the controller relying on at least two preselected parameters related to the pressure, at least one of the parameters based on a temperature within the condenser unit. 10. The method as recited in claim 1, the single core surrounding each of the segments, the lines of each of the segments intersecting a perimeter of the single core. 11. The method as recited in claim 2, further comprising: determining that the pressure is below the predetermined range, providing a gross adjustment by closing the valve associated with the second segment to reduce the selected volume available in the condenser module to receive the refrigerant, and simultaneously providing a refined adjustment to the pressure by selectively increasing the speed of rotation of the fan, for adjusting the pressure to within the predetermined range; anddetermining that the pressure is above the predetermined range, providing a gross adjustment by opening the valve associated with the second segment to increase the selected volume available in the condenser module to receive the refrigerant, and simultaneously providing a refined adjustment to the pressure by selectively decreasing the speed of rotation of the fan, for adjusting the pressure to within the predetermined range. 12. The method as recited in claim 11, decreasing the selected volume available in the condenser module to receive the refrigerant when the valve is closed. 13. The method as recited in claim 11, the controller relying on at least two preselected parameters related to the pressure, at least one of the parameters based on a temperature within the condenser unit. 14. The method as recited in claim 11, the single core surrounding each of the segments, the lines of each of the segments intersecting a perimeter of the single core. 15. The method as recited in claim 11, wherein the two segments each represent fifty percent of a total volume available in the condenser module to receive the refrigerant. 16. The method as recited in claim 11, wherein there is at least a third segment for the condenser module, providing a valve between the compressor and the line of the third segment controlled by the condenser control circuit for controlling movement of the superheated refrigerant vapor from the compressor into the third segment of the condenser module for discretely apportioning the selected volume available in the condenser module to receive the refrigerant, the third segment selectively providing a more refined gross adjustment to the pressure when combined with the first segment and the second segment. 17. A method as recited in claim 1, the ambient temperature selectively ranging being between 100 degrees Fahrenheit and −20 degrees Fahrenheit. 18. A method as recited in claim 1, making each segment the same volume. 19. A method as recited in claim 2, the ambient temperature selectively ranging being between 100 degrees Fahrenheit and −20 degrees Fahrenheit. 20. A method as recited in claim 2, making each segment the same volume.