This application is not federally sponsored.
The instant disclosure relates generally to heating, ventilation, and air conditioning systems and methods and, more particularly but without limitation, to heat pump systems and control methods.
Modern reversible heat pump systems are designed with improved efficiency and reduced energy consumption to comply with the heating, air conditioning, and ventilation industry trends, sustainability initiatives, and governmental regulations to increase efficiency thresholds in both heating and cooling modes of operation. In particular, integration of the water heating option into the heat pump design in commercial and residential applications (in place of electric or gas heaters) is becoming increasingly popular and allows for more efficient energy utilization to reduce an overall building waste heat disposal. However, due to limitations imposed by the system design and operating conditions, the cycle schematics that integrate the water heating option known to date are relatively costly, complex, inflexible in operation, and less reliable. They also employ extra refrigerant charge and often lack desirable control options and features. There exists a need, therefore, to solve these problems.
A heat pump and water heating system for conditioning a space and heating water is disclosed, comprising: (a) a heat pump refrigerant circuit comprising a refrigerant circuit that fluidly interconnects: (i) a compressor having a discharge outlet and a suction port; (ii) a source heat exchanger; (iii) a space heat exchanger; (iv) an expansion valve positioned between the space heat exchanger and the source heat exchanger; (v) a reversing valve positioned on the discharge side of the compressor and configured to alternately direct refrigerant flow from the discharge outlet of the compressor to the one of the source heat exchanger and the space heat exchanger and to alternately return flow from the other of the source heat exchanger and the space heat exchanger to the suction port of the compressor; (vi) a water heater heat exchanger positioned on the discharge side of the compressor between the compressor and the reversing valve; (vii) a water heating valve on the discharge side of the compressor; (viii) a water heater heat exchanger bypass line connecting the water heating valve and the refrigerant line between the water heater heat exchanger and the reversing valve and configured to alternately direct at least a portion of refrigerant from the discharge outlet of the compressor to one of the bypass line or the water heater heat exchanger; and (b) controls for operating the heat pump and water heating system in response to the space conditioning demands and the water heating demands.
The water heating valve may be a regulating valve and the system controls may operate the regulating valve in response to the water heating demands to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line. The water heating valve may be a rapid cycle valve and the system controls may operate the rapid cycle valve in response to the water heating demands to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line. The water heating valve may be a pulse width modulation valve and the system controls may operate the pulse width modulation modulating valve in response to the water heating demands to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line.
The water heating valve may be a 3-way valve. The water heating valve may be a pair of conventional 2-way valves. The water heating valve may be positioned upstream the water heating heat exchanger with respect to the refrigerant flow. A check valve may be positioned downstream the water heating heat exchanger with respect to refrigerant flow. The water heating valve may be positioned downstream the water heating heat exchanger with respect to refrigerant flow.
The heat pump and water heating system may include a bypass circuit around the source heat exchanger, where the bypass circuit around the source heat exchanger may include a bypass refrigerant line and a bypass valve. The heat pump and water heating system may include a bypass circuit around the space heat exchanger, where the bypass circuit around the space heat exchanger may include a bypass refrigerant line and a bypass valve. The heat pump system may be one of water-to-air, water-to-water, air-to-water, and air-to-air system. The heat pump and water heating system may include air and water circulation devices assisting in heat interaction for space conditioning and water heating, where at least one of the compressor and the water circulating or air circulating devices may be a variable capacity device.
A method is disclosed for operating a heat pump system for conditioning a space and heating water wherein the heat pump system comprises a water heater heat exchanger, a water heater heat exchanger bypass line, and a water heater valve configured to direct refrigerant from the discharge side of the compressor in the heat pump system in selected relative percentages through the water heater heat exchanger and the water heater heat exchanger bypass line. The method includes operating the water heater valve in response to the space conditioning and water heating demands to adjust the selected relative percentages of refrigerant being directed through the water heater heat exchanger and the water heater heat exchanger bypass line.
The selected relative percentages of the refrigerant being directed through the water heater heat exchanger and the water heater heat exchanger bypass line may be in the range from zero percent to one hundred percent. The space conditioning demand may take a priority over water heating demand.
The water heating valve may be a regulating valve, and the method may include operating the regulating valve in response to the water heating demands of the space to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line. The water heating valve may be a rapid cycle valve, and the method may include operating the rapid cycle valve in response to the water heating demands of the space to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line. The water heating valve may be a pulse width modulation valve, and the method may include operating the pulse width modulation valve in response to the water heating demands of the space to adjust the relative amount of refrigerant flow directed through the water heater heat exchanger and the water heater heat exchanger bypass line. The water heating valve may be a 3-way valve. The water heating valve may be a pair of conventional 2-way valves.
The water heating valve may be positioned upstream of the water heating heat exchanger with respect to the refrigerant flow. The check valve may be positioned downstream of the water heating heat exchanger with respect to refrigerant flow. The water heating valve may be positioned downstream of the water heating heat exchanger with respect to refrigerant flow.
The heat pump system may include a bypass circuit around the source heat exchanger and the bypass circuit around the source heat exchanger may include a bypass refrigerant line and a bypass valve. The heat pump system may include a bypass circuit around the space heat exchanger and the bypass circuit around the space heat exchanger may include a bypass refrigerant line and a bypass valve. The heat pump system may be one of water-to-air, water-to-water, air-to-water, and air-to-air system. The heat pump system may include air and water circulation devices assisting in heat interaction for space conditioning and water heating and the at least one of the compressor and the water circulating or air circulating devices may be a variable capacity device.
The accompanying drawings, which are incorporated into and form a part of the specification, illustrate one or more embodiments and, together with this description, serve to explain the principles of the disclosure. The drawings merely illustrate various embodiments of the disclosure and are not to be construed as limiting the scope of the instant disclosure.
The instant disclosure discloses a heat pump and water heater system having a simplified, reliable, flexible and inexpensive design that provides five distinct modes of operation that can be extended to numerous combinations thereof. In at least one embodiment, this is accomplished in principle by the addition of a water heating heat exchanger and a refrigerant bypass line around the water heating heat exchanger. A three-way valve allows the refrigerant flow through the bypass line to be actuated and controlled. The refrigerant circuit configurations in cooling and heating modes of operation for the conditioned space disclosed herein can integrate water heating with the space conditioning or employ water heating independently from the space conditioning. Furthermore, the system design is not susceptible to the refrigerant charge migration common in conventional systems. The system provides an advantage of requiring a lower refrigerant charge amount (which may be critical for the conversion to the low global warming refrigerants), provides enhanced efficiency in all modes of operation, and allows for an extended operational envelope.
Referring to
The compressor 102 may be a variable capacity compressor, such as a variable speed compressor, a compressor with an integral pulse width modulation option, or a compressor incorporating various unloading options. These types of compressors allow for better control of the operating conditions and manage the thermal load on the heat pump system 100.
The source heat exchanger 106 may be a refrigerant-to-water, refrigerant-to-brine, or refrigerant-to-air heat exchanger and is not limited to any particular heat exchanger type or configuration. The associated fan or pump (not shown) may be of a variable flow type, such as being driven by a variable speed motor, a pulse width-modulated motor, or an ON/OFF cycling motor, to enhance operation and control of the heat pump system 100.
The expansion device 108 may be an electronic expansion valve, a mechanical expansion valve, or a fixed-orifice/capillary tube/accurator. The expansion device 108 may have bi-directional design or may be replaced by a pair of unidirectional expansion devices with the associated check valve bypass options to provide refrigerant re-routing when the flow changes direction throughout the refrigerant cycle.
The space heat exchanger 110 may be a refrigerant-to-air, refrigerant-to-water or refrigerant-to-brine heat exchanger and is not limited to any particular heat exchanger type or configuration. In the case of the exemplary air-to-refrigerant heat exchanger shown in the drawings, the associated air management system may be a fan 120 of any known type and may be equipped with a variable flow capability feature, such as being driven by a variable speed motor 121, to enhance operation and control of the heat pump system 100. Alternately, the motor 121 may be a pulse width modulated motor or an ON/OFF cycling motor. Of course, in the case of a water-to-refrigerant or brine-to-refrigerant heat exchanger, the fan 120 and motor 121 are replaced by a pump and a motor that may incorporate similar variable capacity capability.
The heat pump system 100 includes a water tank heater loop 122 for heating water in the structure (not shown). A pump 124 circulates water through the loop 122 and a water heater heat exchanger (WHHX) 126. The pump 124 may have a variable flow capability, such as being driven by a variable speed motor, pulse width modulated motor, or ON/OFF cycling motor, to better control operating conditions for the heat pump system 100 and water temperature within the water tank (not shown). The water heater heat exchanger 126, which is typically a refrigerant-to-water heat exchanger, is connected in-line between the discharge side of the compressor 102 and the 4-way reversing valve 104. The water heater heat exchanger 126 operates as a desuperheater and a condenser when it is engaged within the active refrigerant circuit of the heat pump system 100.
A 3-way valve 128 interposed between the compressor 102 and water heater heat exchanger 126 allows the system control 132 for the heat pump system 100 to command the operation of the loop 122. A bypass line 130 (WHHX bypass) connects the 3-way valve 128 to the outlet side of the water heater heat exchanger 126 to direct at least a portion of refrigerant around the water heater heat exchanger 126 when the water tank heater loop 122 is not actuated. In at least one embodiment, the 3-way valve 128 is a modulating type and can be controlled by a stepper motor (not shown) permitting the system control 132 for the heat pump system 100 modulate the percentage of the refrigerant flow directed through the bypass line 130 thus allowing for a better control of operating conditions for the heat pump system 100 and improved operation of the water heater heat exchanger 126.
Alternately, the 3-way valve 128 may be replaced by a pair of conventional valves, such as a pair of rapid cycle solenoid valves, or by a rapid cycle three-way valve. Furthermore, to prevent refrigerant migration while switching between different modes of operation, a check valve (not shown) may be positioned downstream the water heater heat exchanger 126 with respect to the refrigerant flow. Additionally, the 3-way valve 128 may be positioned at the exit of the water heater heat exchanger 126 with respect to the refrigerant flow.
The heat pump system 100 has five distinct modes of operation that are primarily controlled by the 4-way valve 104 and the 3-way valve 128, while augmented by the multiple variable capacity devices, such as compressors, fans and pumps, integrated into the system. These modes of operation are space cooling only, space cooling and water heating, space heating only, space heating and water heating, and water heating only. Additionally, the heat pump system 100 may adjust operation in any of the modes depicted above and exactly match the space conditioning and water heating requirements without excessive ON/OFF cycling that negatively impacts system reliability and fluctuations in operating conditions.
In the space cooling mode of operation depicted in
The 4-way valve 104 is configured to connect the refrigerant to the source heat exchanger 106 through the refrigerant line 112c. In this mode, the source heat exchanger 106 is operating as a condenser to desuperheat, condense, and subcool the refrigerant and rejects heat from the refrigerant system to the environment (not shown).
Downstream the source heat exchanger 106, the refrigerant flows through the expansion device 108, where it is expanded from a high pressure to a lower pressure and its temperature is reduced. The refrigerant is then directed to the refrigerant line 112d and the space heat exchanger 110 that is acting as an evaporator and superheater in the cooling mode of operation, while removing heat and reducing humidity in the conditioned space (not shown). Downstream of the space heat exchanger 110, refrigerant line 112e connects the space heat exchanger 110 to the 4-way valve 104, which is configured to direct the refrigerant to the suction port 114 of the compressor 102 through the refrigerant line 112f to complete the refrigerant circuit.
In the space cooling and water heating mode of operation depicted in
It will be understood that, if the 3-way valve 128 has regulating (modulating) capability, the refrigerant flow between the bypass refrigerant line 130 and the water heating heat exchanger 126 can be adjusted in any proportion from zero to one hundred percent (0%-100%), precisely satisfying the water heating demand typically defined and measured by the temperature transducer integrated into the water tank, reducing a number of ON/OFF cycles, and thus improving system efficiency and reliability. Such flexibility of the 3-way modulating valve 128 may be combined with other variable capacity devices of the heat pump system 100 described above.
In the space heating mode of operation depicted in
In the space heating and water heating mode of operation depicted in
It will be understood that the space heating requirements take the priority over the water heating and that water heating may be supplemented, if required, with a gas or electric heater (not shown). Furthermore, if the 3-way valve 128 has regulating (modulating) capability, the refrigerant flow between the bypass refrigerant line 130 and the water heating heat exchanger 126 can be adjusted in any proportion from zero to one hundred percent (0%-100%) precisely satisfying the water heating demand typically defined and measured by the temperature transducer integrated into the water tank, reducing a number of ON/OFF cycles, and thus improving system efficiency and reliability. Such flexibility of the 3-way modulating valve 128 may be combined with other variable capacity devices of the heat pump system 100 described above.
In the water heating only mode of operation depicted in
Returning now to
The control logic will be programmed to selectively operate the water heater heat exchanger loop or/and to at least partially bypass it using the three-way valve 128. The control logic preferably is set up to allow for the space conditioning as the higher priority over water heating. The refrigerant head pressure control, to ensure safe and reliable operation of the system components such as the 4-way reversing valve 104 and compressor 102, can be accomplished by adjusting the compressor speed, fan speed, pump speed, and the amount of refrigerant flowing through the water heater heat exchanger bypass refrigerant lines 130, 134 and 140.
The selective utilization of the water heating heat exchanger 126, in combination with the space heat exchanger 110 or the source heat exchanger 106 and air/water moving devices, such as the fan 120 and the water heater heat exchanger loop pump 124, respectively in the heating and cooling mode of operation, allows for the system performance (capacity and efficiency) optimization and dehumidification capability improvement.
As described above, the heat pump system 100 of the present disclosure offers many advantages and benefits. By way of example, as depicted above and illustrated in the P-h diagram of
The embodiments shown and described above are exemplary. Many details are often found in the art and, therefore, many such details are neither shown nor described herein. It is not claimed that all of the details, parts, elements, or steps described and shown were invented herein. Even though numerous characteristics and advantages of the present disclosure have been described in the drawings and accompanying text, the description is illustrative only. Changes may be made in the details, especially in matters of shape, size, and arrangement of the parts within the principles of the instant disclosure to the full extent indicated by the broad meaning of the terms of the attached claims. The description and drawings of the specific embodiments herein do not point out what an infringement of this patent would be, but rather provide an example of how to use and make the invention as defined by the appended claims. Likewise, the abstract is neither intended to define the invention, which is measured by the appended claims, nor is it intended to be limiting as to the scope of the instant disclosure in any way. Rather, the limits of the invention and the bounds of patent protection are measured by and defined in the following claims.
This application is a continuation of U.S. Nonprovisional application Ser. No. 17/129,558 filed on Dec. 21, 2020, which is a continuation of U.S. Nonprovisional application Ser. No. 15/634,434 filed on Jun. 27, 2017, which claims the benefit of U.S. Provisional Application No. 62/359,798 filed on Jul. 8, 2016. These applications are incorporated by reference herein in their entirety.
Number | Date | Country | |
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62359798 | Jul 2016 | US |
Number | Date | Country | |
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Parent | 17129558 | Dec 2020 | US |
Child | 17821020 | US | |
Parent | 15634434 | Jun 2017 | US |
Child | 17129558 | US |