Patent Application
20140352339
This application is directed to heat ventilation air conditioning (HVAC) heat pump systems.
Heat pump (HP) systems have gained wide commercial use since their first introduction into the HVAC market because of their operational efficiency and energy savings, and it is this efficiency and energy savings that appeals to consumers and is most often the deciding fact that causes them to choose HPs over conventional HVAC furnace systems. During the winter, a HP system transfers heat from the outdoor air heat exchanger to an indoor heat exchanger where the heat is used to heat the interior of the residence or building. The consumer uses a thermostat to select a temperature set-point for the interior. The HP then operates, using heat transferred from the outside, to warm the indoor air to achieve the set-point. As a result, the consumer enjoys a heating capability, while saving energy. Though auxiliary heating systems, such as electric or gas furnaces can be used in conjunction with the HP, this is typically done only for a brief period of time in order to achieve the set-point in extremely cold conditions.
One embodiment of the present disclosure is a HP system that comprises an indoor blower/heat exchanger system (ID) system, an outdoor fan/heat exchanger and compressor (OD) system that are fluidly coupled together by a liquid refrigerant line. A liquid refrigeration line temperature sensor is coupled to the liquid refrigeration line and configured to provide a temperature of the liquid refrigeration line to the heat pump system. A controller is coupled to the liquid refrigeration line temperature sensor and configured to relate a temperature received from the liquid refrigeration line temperature sensor with a pressure of the compressor and change an airflow rate of the ID system to avoid a shutdown of the HP system that occurs when the compressor reaches a trip pressure of the compressor.
Another embodiment of the present disclosure is a heat pump system controller. This embodiment comprises a control board, a microprocessor located on and electrically coupled to the control board, and a memory coupled to the microprocessor and located on and electrically coupled to the control board. The memory has a program stored thereon that is configured to relate a temperature received from a liquid refrigeration line temperature sensor with a pressure of a compressor of a heat pump system and change an airflow rate of an indoor blower/heat exchange (ID) system of a heat pump (HP) system to avoid a shutdown of the HP system that occurs when the compressor reaches a trip pressure of the compressor.
Another embodiment presents a computer program product, comprising a non-transitory computer usable medium having a computer readable program code embodied therein, said computer readable program code adapted to be executed to implement a method of measuring and managing an indoor airflow rate of a heat pump system. The method comprises relating a temperature received from a liquid refrigeration line temperature sensor of a heat pump system with a pressure of a compressor of the heat pump system, and changing an airflow rate of an indoor blower/heat exchange (ID) system of the heat pump (HP) system to avoid a shutdown of the HP system when the compressor reaches a trip pressure of the compressor.
Reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
As noted above, HP units have gained wide use and are popular with consumers because they can reduce energy costs by using the heat in outdoor air to heat the space of an indoor structure, such as a residence or business. Though these HP units are typically very efficient in operation and energy savings, there is a drawback. The drawback is that the airflow from the blower of the indoor unit may feel cooler to an occupant than airflow from a HVAC furnace system that uses a gas or electric furnace to heat the air. Thus, the cooler register air from the HP system can make the occupant feel uncomfortably cool during the heating cycle.
To address this problem, the HP unit, as disclosed herein, includes a controller that is configured to run under a comfort mode function wherein the airflow from an indoor HVAC system is controlled in such a way as to make the airflow feel warmer to the user. When activated, this controller causes the airflow rate to decrease, which increases the temperature of the airflow. The resulting higher temperature airflow allows the occupant to feel warmer and more comfortable than when the unit runs in a normal operating mode, during which the airflow may feel cooler to the occupant.
In one embodiment, the controller includes a coded data table that relates indoor discharge air temperature as a function of outdoor ambient temperature, as illustrated in
As seen in
The embodiments of the controller of the present disclosure provide a controller that is coupled to a liquid refrigeration fluid line temperature sensor and is configured to prevent a shutdown of the compressor that occurs when it reaches predetermined, excessive discharge pressures. Using temperature data received from the temperature sensor, the controller may gradually increase the airflow rate, which, in turn, decreases the discharge pressure of the compressor to avoid a shutdown. Alternatively, the controller may be configured to automatically de-activate and return to a normal operation mode, which would also decrease the discharge of the compressor, and thereby, avoid a shutdown. Thus, the controller may either cause a decrease in the indoor flow rate to warm the discharged air, or it may increase the indoor airflow rate to prevent the compressor from reaching excessive trip pressures.
With the present disclosure, it has been recognized that a strong correlation exists between the liquid refrigeration line temperature of the HP system and the discharge pressure of the compressor, as illustrated in
As seen from
One embodiment of the controller as implemented in a HP system 400 is illustrated in
The HP system 400 further includes an indoor (ID) system 435 that comprises an indoor heat exchanger 440, equipped with an indoor blower 445, which in certain embodiments, may be a conventional, variable speed blower, and an indoor system controller 450. The indoor system controller 450 may be coupled to the ID system 435 either wirelessly or by wire. For example, the indoor system controller 450 may be located on a housing (not shown) in which the blower 445 is contained and hard wired to the blower 445. Alternatively, the indoor system controller 450 may be remotely located from the blower 445 and be wirelessly connected to the blower 445. The indoor system controller 450 may also be optional to the system, and when it is not present, the indoor system 435 may be controlled by an indoor thermostat.
The HP system 400 further includes a liquid refrigeration line temperature sensor 455 that is coupled to the controller 405 for communications therewith. In one embodiment, the liquid refrigeration line temperature sensor 455 may be located on a refrigeration line that exits the heat exchanger 415. The liquid refrigeration line temperature sensor 455 may obtain a temperature reading by sensing the outer surface of the refrigeration tubing. In most cases this reading will be very close to the temperature of the liquid refrigerant within the tubing, given the good thermally conductivity of the refrigerant tubing to which the senor 455 is attached. However, in other embodiments, the temperature sensor 455 may be located at other locations on the liquid refrigeration line.
The HP system 400 further includes a thermostat 460, which, in certain embodiments may be the primary controller of the HP system 400. The thermostat 460 is preferably an intelligent thermostat that includes a microprocessor and memory with wireless communication capability and is of the type described in U.S. Patent Publication, No. 2010/0106925, application Ser. No. 12/603,512, which is incorporated herein by reference. The thermostat 460 is coupled to the outdoor controller 430 and the indoor controller 450 to form, in one embodiment, a fully communicating HP system, such that all of the controllers or sensors 405, 430, 450, 455, and 460 of the HP system 400 are able to communicate with each other, either by being connected by wire or wirelessly. In one embodiment, the thermostat 460 includes the controller 405 and further includes a program menu that allows a user to activate the controller 405 program by selecting the appropriate button or screen image displayed on the thermostat 460. In other embodiments, the controller 405 may be on the same board as the outdoor controller 430 or the indoor controller 450. Thus, the controller 405 may be located in various locations with respect to the HP system 400.
In general, the compressor 425 is configured to compress a refrigerant, to transfer the refrigerant to a discharge line 465, and, to receive the refrigerant from a suction line 470. The discharge line 465 fluidly connects the compressor 425 to the outdoor heat exchanger 415, and the suction line 470 fluidly connects the indoor heat exchanger 440 to the compressor 425 through a reversing valve 475. The reversing valve 475 has an input port 480 coupled to the discharge line 465, an output port 482 coupled to the suction line 470, a first reversing port 484 coupled to a transfer line 486 connected to the outdoor heat exchanger 415, and a second reversing port 490 coupled to a second transfer line 492 connected the indoor heat exchanger 440. As understood by those skilled in the art, the transfer lines 486, 492 allow for the reversal of the flow direction of the refrigerant by actuating the revering valve 475 to put the HP system 400 in a cooling mode or a heating mode. One skilled in the art would also appreciate that the HP system 400 could further include additional components, such as a connection line 494, distributors 496 and delivery tubes 498 or other components as needed to facilitate the functioning of the system.
The controller 405 is configured or programmed with an algorithm and data that relates a temperature received from the liquid refrigeration line temperature sensor with a pressure of the compressor and change an airflow rate of the ID system to avoid a shutdown of the HP system that occurs when the compressor reaches its trip pressure. The trip pressure is the pressure beyond which the unit should not be operated. Thus, in many instances, HP units will have trip pressure switches that will shut down the HP unit once a predetermined high pressure is reached. The high pressure limit can vary from one type of HP unit to the other. For example, the high pressure limit of a particular HP 4 ton unit may be 590 psig.
In one embodiment, the controller 405 is coupled to a conventional primary controller that is coupled to the ID system 435 (
In another embodiment, the controller 405 is programmed with data that relates the trip pressure of the compressor 425 with a temperature of the liquid refrigeration line, as obtained from the liquid refrigeration temperature sensor 435. This correlated data may be obtained either by testing different compressors at different readings of compressor discharge and liquid refrigeration line temperatures, or it may be obtained through computer modeling software. Once obtained, however, a liquid refrigeration line temperature at it relates to a trip pressure of a compressor can be achieved and used during HP system operation to avoid the compressor's shut-down.
In another embodiment, the controller 405 may be configured to change the airflow rate when the liquid refrigeration line temperature is less than a predetermined maximum temperature of the liquid refrigeration line. In an aspect of this embodiment, the predetermined maximum temperature indicates a pressure that is equal to or less than a trip pressure of said compressor 425. The maximum temperature, and thus the related pressure, can be chosen such that a cushion or an extra margin for error is configured into the controller to avoid getting too close to the trip pressure, thereby assuring that the actual trip pressure will not be reached during operation.
In yet another embodiment, the controller 405 is further configured to store a trip pressure that occurs during operation of the HP system 400. In one aspect of this embodiment, the controller 405 is further configured to read and store a temperature of the liquid refrigeration line upon the occurrence of the trip pressure and use that stored temperature as an indication of the trip pressure and regulate the airflow rate based on the stored temperature. In such embodiment, once the trip pressure has occurred and the pressure and related temperature has been stored in the memory of the controller, certain embodiments provide a controller that then operates the airflow pursuant to the actual stored numbers in place of the table. This embodiment allows for even a more accurate operation of the HP unit.
Accordingly, if the controller reduces the airflow in attempt to make the occupant feel warmer and the compressor discharge pressure gets too close or comes to stored value of the trip pressure as determined from the stored temperature, the controller will either increase the airflow to reduce the pressure or de-activate the function completely. Again, as with other embodiments, the controller may have a sub-routine that reduces the actual stored values for both the pressure and temperature and reduces them to provide for airflow reduction or de-activation at values just less than those stored to ensure that the trip pressure is not reached again.
In another embodiment, the controller 405 may be embodied as a series of operation instructions that direct the operation of the microprocessor 505 when initiated thereby. In one embodiment, the controller 405 is implemented in at least a portion of a memory 510 of the controller 405, such as a non-transitory computer readable medium of the controller 405. In such embodiments, the medium is a computer readable program code that is adapted to be executed to implement a method of measuring and managing an indoor airflow rate of the HP system 400. The method comprises relating a temperature received from a liquid refrigeration line temperature sensor of a heat pump system with a pressure of the compressor 425 of the HP system 400 and changing an airflow rate of the indoor blower/heat exchange (ID) system 435 of the HP system 400 to avoid a shutdown of the HP system 400 when the compressor 425 reaches a trip pressure.
Indoor airflow=comfort airflow+n*(normal airflow−comfort airflow), where n is some positive fractional number
If the temperature reading is less than the mean temperature, then the comfort function will continue to run until the temperature reading from the sensor becomes greater than a minimum temperature. If during this portion of the cycle, the liquid refrigeration line temperature becomes greater than the minimum temperature, then the controller will reduce the indoor airflow as follows:
Indoor airflow=comfort airflow+(n−x)*(normal airflow−comfort airflow), where x is some fractional number less than n
As long as the liquid refrigeration line temperature is less than the minimum temperature, the unit will continue to run in the comfort mode until the set-point programmed into the thermostat is achieved.
Those skilled in the art to which this application relates will appreciate that other and further additions, deletions, substitutions and modifications may be made to the described embodiments.
