The field of the disclosure relates generally to fluid pump down using valves and, more particularly, to valve systems for removing refrigerant used in cooling systems from the interior of a structure.
Known heating, ventilation, and cooling (HVAC) systems and other cooling systems use refrigerants to remove heat from the conditioned space. In these systems, refrigerant flows from an outdoor condensing unit through a liquid line into an interior space, such as a residence. The liquid refrigerant boils while absorbing heat to be removed from the conditioned space, thereby cooling blowing air before the refrigerant is returned to a compressor in the outdoor condensing unit using a suction line. Many of these known HVAC systems use chlorofluorocarbons (CFCs), hydrochlorofluorocarbons (HCFCs), and/or hydrofluorocarbons (HFCs) and other similar, relatively inert compounds as refrigerants. Advantageously, such refrigerants are non-flammable, meaning that the refrigerants are relatively safe while they are pumped through residences and other facilities. As such, between cycles of the HVAC system, residual refrigerant may be left in interior portions of the HVAC system and pose little risk to the structure. Typically, these systems include manually operated service valves, which facilitate shipping and service of the system by isolating the condensing unit from the home side of the system when closed. Additionally, such systems using non-flammable refrigerants can be easily serviced using common Schrader valves or other similar valves to monitor pressure and add or remove the refrigerants from the system.
However, CFCs, HCFCs, HFCs and other similar compounds have a high Global Warming Potential (“GWP”) or Ozone Depletion Potential (“ODP”) and, as such, pose an environmental risk. Because of this high GWP potential, there has been a drive to use refrigerants having a lower GWP. Unfortunately, many such potential lower GWP refrigerants, such as difluoromethane, are flammable. In fact, many of the proposed low GWP refrigerants carry an American Society of Heating, Refrigerating and Air-Conditioning Engineers (“ASHRAE”) designation of A2L, which indicates they are mildly flammable. Other low GWP refrigerants with higher flammability, carrying designations of A2 and A3, are also potential replacements for high GWP refrigerants. The flammability of these refrigerants poses a potential risk to the interior space if a quantity of A2L-designated or other flammable refrigerant above a critical volume is left within the interior space between cooling cycles of the HVAC system. For example, under some proposed U.S. regulations, a volume of A2L-designated refrigerant above 4 pounds (approximately 450 grams) within the interior space is considered dangerous to an average residential structure and requires additional mitigation to isolate the refrigerant from the environment as compared to non-flammable refrigerants.
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
In one aspect, a valve system includes a motor, a first valve, a second valve, and a controller. The motor has a shaft. The first valve is connected to the shaft and is rotatable to an open position, through which fluid flows to a first channel, and a close position, in which fluid is prevented from flowing through the first channel. The second valve is connected to the shaft and is rotatable to an open position, through which fluid flows to a second channel, and to a close position, in which fluid is prevented from flowing through the second channel. The controller is connected to the motor and is configured to, using the motor and the shaft, sequentially actuate the first valve and the second valve to create at least a first, second, third, and fourth position. In the first position, the first valve is in the closed position and the second valve is in the closed position. In the second position, the first valve is in the open position. In the third position, the first valve is in the open position and the second valve is in the open position. In the fourth position, the first valve is in a closed position and the second valve is in the open position.
In another aspect, a cooling system includes an air handling unit, a condensing unit, a suction line, a liquid line, and a valve system. The air handling unit is configured to distribute air and includes an evaporator. The condensing unit includes compressor and a condenser. The compressor is fluidly connected to the condenser by a condenser line configured to channel refrigerant from the compressor to the condenser. The suction line is configured to channel refrigerant from the evaporator to the compressor. The liquid line is configured to channel refrigerant from the condenser to the evaporator. The valve system includes a motor, a liquid-line valve, a suction-line valve, and a controller. The motor has a shaft. The liquid-line valve is connected to the shaft and is in fluid communication with the liquid line. The liquid-line valve includes a liquid-line channel therethrough and the liquid-line valve is rotatable to an open position, in which refrigerant flows through the liquid-line channel, and to a closed position, in which refrigerant is prevented from flowing through the liquid-line channel. The suction-line valve is connected to the shaft and is in fluid communication with the suction line. The suction-line valve includes a suction-line channel therethrough and the suction-line valve rotatable to an open position, in which refrigerant flows, using suction, through the suction-line channel, and to a close position, in which refrigerant is prevented from flowing through the suction-line channel. The controller is connected to the motor and is configured to, using the motor and the shaft, sequentially actuate the liquid-line valve and the suction-line valve to create at least a first, second, third, and fourth position. In the first position, the liquid-line valve is in the closed position and the suction-line valve is in the closed position. In the second position, the liquid-line valve is in the open position. In the third position, the liquid-line valve is in the open position and the suction-line valve is in the open position. In the fourth position, the liquid-line valve is in a closed position and the suction-line valve is in the open position.
Various refinements exist of the features noted in relation to the above-mentioned aspects of the present disclosure. Further features may also be incorporated in the above-mentioned aspects of the present disclosure as well. These refinements and additional features may exist individually or in any combination. For instance, various features discussed below in relation to any of the illustrated embodiments of the present disclosure may be incorporated into any of the above-described aspects of the present disclosure, alone or in any combination.
Corresponding reference characters indicate corresponding parts throughout the drawings. Although specific features of various embodiments may be shown in some drawings and not in others, this is for convenience only. Any feature of any drawing may be referenced and/or claimed in combination with any feature of any other drawing.
The following detailed description illustrates embodiments of the disclosure by way of example and not by way of limitation. It is contemplated that the disclosure has general application to cooling systems in which refrigerant is pumped between exterior and interior spaces, including industrial, commercial, and residential applications.
In operation, return air 106 is pulled from structure 102 by blower 114 into plenum 116. Thermostat 122 may direct that blower 114 be turned on at all times or only when a cooling or heating request is present. Evaporator 192 is located within plenum 116 above blower 114. Evaporator 192 is placed in series with blown air 107 from blower 114 so that when cooling is desired, evaporator removes heat from blown air 107, thereby generating a cool supply air 132. It will be appreciated that HVAC system 100 may include heating components as well, such as a burner (not shown).
In an example, a split-type air conditioning system is shown including a condensing unit 178 located in an area 101 outside of structure 102. Condensing unit 178 includes a compressor 180, a fan 182, a condenser 184, and a condensing unit control module 196. Condensing unit control module 199 is operatively coupled to main control module 108 and is configured to control the operation of compressor 180 and fan 182. Compressor 180 is fluidly connected to evaporator 192 by means of a suction line 138. Compressor 180 is also fluidly connected to condenser 184 by means of a compressor discharge line 140. Condenser 184 is connected to evaporator 192 by means of liquid line 142. Expansion device 188 is coupled along liquid line 142 between condenser 184 and evaporator 192. Each of the suction line 138, compressor discharge line 140, and liquid line 142 are in fluid communication with one another such that refrigerant 136 cycles through each line 138, 140, 142 during a single cooling cycle of HVAC system 100.
Refrigerant 136 may be, for example, traditional, nonflammable HVAC refrigerants such as, for example, CFCs, HCFCs, HFCs, and the like. In alternative embodiments, refrigerant 136 may be mildly flammable, such as, for example, refrigerants with an ASHRAE designation of A2L, like difluoromethane and 1,3,3,3-tetrafluoropropene. In further embodiments, refrigerant 136 is any refrigerant that can be used with HVAC system 100 as described herein.
In an example operation of HVAC system 100, during the cooling of blown air 107, evaporator 192 is filled a low pressure, low temperature refrigerant 136 in the liquid form. As blown air 107 passes across the coils of evaporator 192, blown air 107 is cooled and refrigerant 136 within the coils is heated, generating a refrigerant 136 having a low temperature and low pressure in gas form. Refrigerant 136 is then drawn from evaporator 192 to compressor 180 within condensing unit 178 using suction line 138. During this process, refrigerant 136 is drawn from inside structure 102 to outside area 101. Compressor 180 rapidly compresses refrigerant 136, generating a high temperature, high pressure refrigerant 136. High temperature, high pressure refrigerant 136 in gas form is channeled through compressor discharge line 140 into condenser 184, where refrigerant 136 is channeled through a series of condenser coils 181. As refrigerant 136 travels through condenser coils 181, outside air 183 is drawn through the outside of the condenser coils 181 using fan 182, which cools and condenses the refrigerant 136. The medium temperature, high pressure liquid refrigerant 136 is then channeled through liquid line 142 back into structure 102 and to expansion device 188, causing refrigerant 136 to expand entering the evaporator 192 and lowering both the temperature and pressure of the liquid refrigerant 136. This low temperature, low pressure liquid refrigerant 136 is then channeled through evaporator to begin the air cooling process again. The above example operation of the cooling system of HVAC system 100 is described for illustrative purposes, but the phases of the refrigerant and the operation conditions of HVAC system 100 can vary according to a number of factors, such as the type of refrigerant used.
In this example, at least a portion of suction line 138 has a larger diameter than liquid line 142. More specifically, in an embodiment, suction line 138 is about ¾ inch to about 1 inch in diameter and liquid line 142 is about ¼ inch to about ½ inch in diameter. In further embodiments, suction line 138 us about ⅞ inch in diameter and liquid line 142 is about ⅜ inch in diameter.
HVAC system 100 includes a suction-line valve 202 located along suction line 138 between evaporator 192 and compressor 180. Suction-line valve 202 is configured to control the flow of refrigerant through suction line 138 and into compressor 180. In an embodiment, suction-line valve 202 is a ball valve having a suction-line valve body 206 and a suction-line valve ball 208 rotatable within suction-line valve body 206. Suction-line valve ball 208 has a first end 212, an opposing second end 214, and a suction-line valve channel 210 running between the two ends 212, 214. Suction channel 210 is configured to channel fluid from first end 212 to second end 214 when ball valve is in an open position. Specifically, in an embodiment, suction-line valve channel 210 is configured to channel refrigerant 136 through suction-line valve ball 208 when suction-line valve ball 208 is in an open position. Suction-line valve ball 208 is also configured to prevent the flow of refrigerant 136 through suction-line valve 202 when suction-line valve ball 208 is in a closed position (i.e. when suction-line valve ball 208 is rotated such that fluid cannot flow through suction-line valve channel 210; shown in
HVAC system 100 also includes a liquid-line valve 204 located along liquid line 142 between condenser 184 and evaporator 192. Liquid-line valve 204 is configured to control the flow of refrigerant 136 through liquid line 142 to expansion device 188 and evaporator 192. In an example embodiment, liquid-line valve 204 is a ball valve having a liquid-line valve body 216 and a liquid-line valve ball 218 rotatable within liquid-line valve body 216. Liquid-line valve ball 218 has a first end 222, an opposing second end 224, and a liquid-line valve channel 220 running between the two ends 222, 224. Liquid-line valve channel 220 is configured to channel fluid from first end 222 to second end 224 when ball valve is in an open position. More specifically, liquid-line valve channel 220 is configured to channel refrigerant 136 through liquid-line valve ball 218 when liquid-line valve ball 218 is in an open position. Liquid-line valve ball 218 is also configured to prevent the flow of refrigerant 136 through liquid-line valve 204 when liquid-line valve ball 218 is in a closed position (i.e. when liquid-line valve ball 218 is rotated such that fluid cannot flow through liquid-line valve channel 220; shown in
Suction-line valve 202 and liquid-line valve 204 are operatively coupled to an actuator 228 configured to actuate both valves 202, 204. Actuator 228 is also coupled to main control module 108. Main control module 108 controls the operation of actuator 228, which, in turn, controls the actuation of valves 202, 204. Specifically, actuator 228 is configured to rotate suction-line valve ball 208 and liquid-line valve ball 218 within their respective valve bodies 206, 216. Main control module 108 is configured to control the rotation of suction-line valve ball 208 and liquid-line valve ball 218 using actuator 228. In some embodiments, main control module 108 and/or actuator 228 may be configured to independently control the operation of suction-line valve 202 and liquid-line valve 204. Alternatively or in addition, in some embodiments, main control module 108 and/or actuator 228 may be configured to actuate both valves 202, 204 simultaneously.
In embodiments of first rotation configuration 250 and second rotation configuration 252, suction-line valve ball 208 and liquid-line valve ball 218 may be the same size or may be substantially similarly size. However, in some embodiments, suction-line valve channel 210 has a larger diameter than liquid-line valve channel 220. More specifically, in some embodiments, suction-line valve channel 210 has a diameter that is about the same or less than the diameter of suction line 138 and liquid-line valve channel 220 has a diameter that is about the same or less than the diameter of liquid line 142. In some embodiments, suction-line valve channel 210 is about ¾ inch to about 1 inch in diameter and liquid-line valve channel 220 is about ¼ inch to about ½ inch in diameter. In further embodiments, suction-line valve channel 210 is about ⅞ inch in diameter and liquid-line valve channel 220 is about ⅜ inch in diameter.
In first position 302 of rotation sequence 300, both suction-line valve 202 and liquid-line valve 204 are in a closed position, preventing refrigerant 136 from flowing through channels 210, 220, respectively. More specifically, in first position 302, valve balls 208, 218 are rotated within valve bodies 206, 216 such that channels 210, 220 are open only to the sides of valve bodies 206, 216. In operation, while rotation sequence 300 is in first position 302, all or most of refrigerant 136 is contained between suction-line valve 202 and liquid-line valve 204 fluidly upstream of suction-line valve 202 and fluidly downstream of liquid-line valve 204. As such, in the first position, all, substantially all, or most of refrigerant 136 is located in outside area 101 and within condensing unit 178. Advantageously, in some embodiments, when rotation sequence 300 is in first position 302, flammable refrigerant 136 is removed from structure 102, decreasing the risks to structure 102.
In second position 304, suction-line valve 202 is in the closed position, preventing fluid from flowing therethrough, and liquid-line valve 204 is open, allowing refrigerant 136 to travel from first end 222 to second end 224 of liquid-line valve channel 220. Accordingly, in second position 304, refrigerant 136 begins to travel from condensing unit 178 in outside area 101 into structure 102. In other embodiments, both suction-line valve and liquid-line valve are in the open position in second position 304. In third position 306, both suction-line valve 202 and liquid-line valve 204 are in an open position, allowing refrigerant 136 to flow through channels 210, 220, respectively. Accordingly, in operation, when rotation sequence 300 is in second position 304 and third position 306, refrigerant 136 flows through liquid line 142 from condensing unit 178 to expansion device 188 and evaporator 192. In these two positions 304, 306, evaporator 192 cools blown air 107 to generate cool supply air 132.
In fourth position 308, suction-line valve 202 is open, allowing refrigerant 136 to flow from first end 212 to second end 214 of suction-line valve channel 210, while liquid-line valve 204 is closed, preventing refrigerant from traveling therethrough. In operation, in fourth position 308, refrigerant 136 is pumped down out of structure 102 and into condensing unit 178. In this example, most of the refrigerant 136 is removed from structure 101 while rotation sequence 300 is in fourth position 308. In other embodiments, 75% or more of refrigerant 136 is removed from structure 101 while rotation sequence 300 is in fourth position 308. In further embodiments, 90% or more of refrigerant 136 or, alternatively, substantially all of refrigerant 136 is removed from structure 101 while rotation sequence 300 is in fourth position 308.
After fourth position 308, rotation sequence 300 returns to first position 302. Operationally, returning to first position 302 means that most, 75% or more, 90% or more, or substantially all of refrigerant 136 is removed from structure 102 and moved to outside area 101 between suction-line valve 202 and liquid-line valve 204 fluidly upstream of suction-line valve 202 and fluidly downstream of liquid-line valve 204 and at least partially within condensing unit 178. Accordingly, one full rotation sequence 300 represents one cooling cycle of HVAC system 100 that includes one full pump-down procedure to remove most, 75% or more, 90% or more, or substantially all of the refrigerant from structure 102.
Suction-line valve 202 and liquid-line valve 204 are located in outside area 101 and outside of condensing unit 178 such that valves 202, 204 are accessible without entering condensing unit 178. With valves 202, 204 located outside of the condensing unit 178, a service technician can access valves 202, 204, and thus refrigerant 136, while refrigerant 136 is contained within condensing unit 178 between suction-line valve 202 and liquid-line valve 204 (i.e. when valves are in first position 302). Accordingly, a Schrader valve or other service valves are not required to service at least some embodiments of HVAC system 100. In alternative embodiments, valves 202, 204 are located within at least a portion of condensing unit 178. In some of these embodiments, valves 202, 204 are accessible within condensing unit 178 through a service access panel (not shown).
Valves 202, 204 are actuated in parallel, such that both valve balls 208, 218 rotate at substantially the same speed throughout one full rotation sequence 300. In alternative embodiments, valves 202, 204 may be actuated sequentially or their actuation may be offset. Further, channels 210, 220 may have alternative configurations, such as, for example, slots instead of round holes.
Valve actuation system 400 may include a position sensor 408 configured to determine the angular position of suction-line valve ball 208 and liquid-line valve ball 218 within suction-line valve 202 and liquid-line valve 204, respectively. Position sensor 408 may be, for example, a rotary and/or angular encoder or a Hall-effect device. If position sensor 408 is an encoder, it may be a magnetic or optical encoder and it may be configured to provide either absolute or incremental output, or both. In other embodiments, position sensor 408 may be any sensor that allows for valve actuation system 400 to function as described herein. As illustrated, position sensor 408 is located on shaft 404 within motor 402. However, it will be appreciated that position sensor 408 may be located anywhere valve actuation system 400 that allows position sensor 408 to function as described herein.
In the illustrated embodiment and as described above, motor 402 is operatively coupled to main control module 108 and main control module 108 controls the operation of motor 402 and, by extension, shaft 404 and valves 202, 204. However, other configurations are contemplated within the scope of this disclosure. In some embodiments, motor 402 and/or valves 202, 204 may be operatively coupled to a separate controller (not shown) distinct from main control module 108. This separate controller may in turn be controlled by main control module 108 or may operate independent of main control module 108. For example, valves 202, 204 may be operatively coupled to a cam and switch system or other similar system configured to control the operation of valves 202, 204.
A motor wire 502 operatively couples main control module 108 to motor 402. Main control module 108 is configured to control the operation of motor 402 and, by extension, actuation of valves 202, 204. In an embodiment, when thermostat 122 has a reading above a particular set point, thermostat 122 transmits a signal to main control module 108, which, in turn, activates motor 402 to begin actuating valves 202, 204 according to rotation sequence 300. The actuation of valves 202, 204 according to rotation sequence 300 causes refrigerant 136 to be pumped into structure 102 to cool air 107 before refrigerant 136 is pumped down from structure 102 back into condensing unit 137. The cycle is repeated as necessary to maintain the temperature at the thermostat 122 set point.
A sensor wire 504 operatively couples main control module 108 to motor position sensor 408. Sensor wire 504 enables position sensor 408 to transmit position information of shaft 404 to main control module 108. Based on the information received from position sensor 408, main control module 108 can change an operation of motor 402, such as, for example, increasing or decreasing the speed of motor 402. In some embodiments, the information from position sensor 408 can be used diagnostically in order to determine a defect in the actuation of valves 202, 204 and/or a defect in motor 402, such as wear or contamination in motor 402 or shaft 404. If a defect is detected, main control module 108 is configured to perform an additional operation, such as, for example, terminate operation of motor 402 or notify the operator of an error.
Motor 402 may be a direct current (DC) motor, a stepper motor, or an alternating current (AC) motor. Motor 402 may include position sensor 408. In some embodiments, the time between two positions of shaft 404 may be determined and the detected time difference compared to an expected value can indicate an error has occurred in valve operation system 500, such as wear or contamination in motor 402 or shaft 404. In embodiments where motor 402 is a stepper motor, main control module 108 may be configured to monitor the number of steps performed by motor 402 versus the position of shaft 404. Using the number of steps compared to the position, main control module 108 can detect errors that may occur. For example, if the number of steps recorded by control module 118 does not correspond to the expected position of shaft 404, the detected difference can indicate an error has occurred in valve operation system 500. If an error is detected based on readings from position sensor 408 and/or the number of steps, main control module 108 is configured to perform an additional operation such as, for example, terminate operation of motor 402 or notify the operator of an error.
Motor 402 may include a gear train, such as a simple or planetary gear train. In some embodiments, the gear train may provide additional torque to shaft 404, which in turn provides additional torque to suction-line valve 202 and liquid-line valve 204 in order to rotate suction-line valve ball 208 and liquid-line valve ball 218.
As shown in
It will be appreciated that the configuration of valves 202, 204, motor 402, and shaft 404 shown in valve operation systems 500, 600, 700 are provided for illustrative purposes and that other configurations are contemplated within the scope of this disclosure. For example, as illustrated by valve operation system 800 in
Valve configuration 900 is configured to perform rotation sequence 300 and pump down refrigerant 136 from structure 102 at the end of each cooling cycle. Specifically, the pump down process (i.e. the transition from fourth position 308 to first position 302) causes refrigerant 136 to be isolated within condensing unit 178 between suction-line valve 202 and liquid-line valve 204. If, during a service process, a technician desires to monitor pressures or remove or replace refrigerant, valves 902, 904 may be used to access refrigerant 136 isolated within condensing unit 178. It will be appreciated that one or both valves 902, 904 may be used to access refrigerant 136. It will also be appreciated that suction-line valve 202 and/or liquid-line service valve 904 may be placed in other positions within HVAC system that allow access to refrigerant while stored in condensing unit 178.
Embodiments of the cooling systems described help reduce and/or mitigate potential risks associated with the flammability of certain refrigerants by pumping down the refrigerant within the cooling system from an interior space to an exterior module between each cycle of the cooling system. Accordingly, the cooling systems described allow for the use of at least mildly flammable refrigerants and thus provide the ability to replace refrigerants with high GWP with refrigerants with lower GWP, reducing the potential environmental impacts of the cooling systems. Further, actuation of valves within the cooling systems allows for refrigerant stored in a condensing unit to flow into a structure in a controlled manner, preventing flooded start conditions and reducing or alleviating the need for the compressor to start under pressure. In some embodiments, the traditional service valves are replaced altogether, reducing the overall cost associated with adding the pump down functionality to the HVAC system.
It will be appreciated that the above embodiments that have been described in particular detail are merely example or possible embodiments, and that there are many other combinations, additions, or alternatives that may be included.
As used herein, the terms “about,” “substantially,” “essentially” and “approximately” when used in conjunction with ranges of dimensions, concentrations, temperatures or other physical or chemical properties or characteristics is meant to cover variations that may exist in the upper and/or lower limits of the ranges of the properties or characteristics, including, for example, variations resulting from rounding, measurement methodology or other statistical variation.
When introducing elements of the present disclosure or the embodiment(s) thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” “containing” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. The use of terms indicating a particular orientation (e.g., “top”, “bottom”, “side”, etc.) is for convenience of description and does not require any particular orientation of the item described.
As various changes could be made in the above constructions and methods without departing from the scope of the disclosure, it is intended that all matter contained in the above description and shown in the accompanying drawing[s] shall be interpreted as illustrative and not in a limiting sense.
Number | Name | Date | Kind |
---|---|---|---|
3237642 | Tomson | Mar 1966 | A |
4365659 | Yoshida | Dec 1982 | A |
5277032 | See | Jan 1994 | A |
5437304 | Delcroix | Aug 1995 | A |
5915402 | Mitchell, II | Jun 1999 | A |
6197195 | Booth | Mar 2001 | B1 |
6338255 | Richard et al. | Jan 2002 | B1 |
6843070 | Suharno | Jan 2005 | B1 |
8001783 | Dale | Aug 2011 | B2 |
9366347 | Diehl et al. | Jun 2016 | B2 |
10344883 | Brazas | Jul 2019 | B2 |
20050252556 | Williams | Nov 2005 | A1 |
20190186769 | Zimmermann | Jun 2019 | A1 |
20190353260 | Jenks | Nov 2019 | A1 |
20200011580 | Matsuda | Jan 2020 | A1 |
Number | Date | Country | |
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20210254875 A1 | Aug 2021 | US |