This application relates to co-pending U.S. patent application Ser. No. 14/221,843, entitled SYSTEM FOR CONTROLLING OPERATION OF AN HVAC SYSTEM HAVING TANDEM COMPRESSORS, filed Mar. 21, 2014, which is hereby incorporated by reference.
Field of the Invention
The present invention relates to control systems used in heating, ventilation, and air conditioning (HVAC) systems and, more particularly, to a system for controlling operation of an HVAC system having a tandem compressor assembly.
Background
In an HVAC system, an evaporator removes heat from an enclosed space that is to be cooled. It is important to keep coils of the evaporator warm enough to prevent freezing of water condensation on the coils due to the low temperature of refrigerant within the coils. In other situations, the coils may become cold due to a low refrigerant charge. In some HVAC systems, a freeze stat is utilized to detect a freezing condition in the evaporator coils. In response to a freezing condition, a control system of the HVAC system shuts down the HVAC system to prevent damage to a compressor and other components of the HVAC system. What is needed are improved systems, devices, and methods for maintaining the evaporator of an HVAC system in an operational condition.
The present invention provides a system for operating an HVAC system with tandem compressors. In response to detection of a pre-freezing condition in evaporator coils of the HVAC system, a controller adjusts an operating condition of the HVAC system.
For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following Detailed Description taken in conjunction with the accompanying drawings, in which:
In the following discussion, numerous specific details are set forth to provide a thorough understanding of the present invention. However, those skilled in the art will appreciate that the present invention may be practiced without such specific details. In other instances, well-known elements have been illustrated in schematic or block diagram form in order not to obscure the present invention in unnecessary detail. Additionally, for the most part, details concerning well-known features and elements have been omitted inasmuch as such details are not considered necessary to obtain a complete understanding of the present invention, and are considered to be within the understanding of persons of ordinary skill in the relevant art.
Referring to
The HVAC system 1000 may utilize a second heat transfer media in the cooling and heating circuit 110. In some embodiments, the second heat transfer media (labeled “SHTM” in
In other embodiments, the HVAC system 1000 may utilize a different heat transfer media instead of air, for example water or other gas or fluid which transfers heat with refrigerant flowing in the evaporator 108 or condenser 104. In the case of the second heat transfer media being a fluid, the fluid moving devices 101, 103 used in
Referring to
The tandem compressor assembly 100 allows the first compressor 112 or the second compressor 114 to be operated while the other compressor 114 or 112, respectively, is turned off (referred to as a “one-compressor configuration”) during periods of low heat transfer demand. The tandem compressor assembly 100 also allows both compressors 112 and 114 to be operated at the same time (referred to as a “two-compressor configuration”) during periods of high heat transfer demand.
The tandem compressor assembly 100 may further be configured to operate in the one-compressor configuration in response to detection of an abnormal operating condition in the HVAC system 1000. For example, the tandem compressor assembly 100 may be operated in a one-compressor configuration in response to a detection of an abnormal temperature condition in the coils 105 of the evaporator 108.
In some embodiments, one or more of the compressors 112, 114 in the tandem compressor assembly 100 may comprise a variable capacity, allowing for further adjustment of heat transfer by the HVAC system 1000 to meet the environmental demands. For example, the tandem compressor assembly 100 may be operated in a first stage “Y1” and a second stage “Y2,” as referred to in
Referring to
Referring to
Referring to
Referring to
Referring to
The first temperature detecting device 122 and the second temperature detecting device 124 may be operationally connected to the coils 105 to detect and monitor the temperature of refrigerant in the coils 105 of the evaporator 108. The first temperature detecting device 122 and the second temperature detecting device 124 may allow the HVAC system 1000 to respond to an indication that the coils 105 are getting cold, for example nearing temperatures where condensation freezes on the coils 105, which effects performance of the HVAC system 1000. In response to an indication that the coils 105 are getting cold, the tandem compressor assembly 100 may be operated in a one-compressor configuration. The first temperature detecting device 122 and the second temperature detecting device 124 may also be utilized as a warning system to detect cooling evaporator coils in HVAC systems that operate with a single compressor.
In some embodiments, the first temperature detecting device 122 and the second temperature detecting device 124 comprise a freeze stat having a switch configured to sense the temperature of the refrigerant in the coils 105. The switch of the freeze stat may change states when the freeze stat senses a pre-set temperature.
Each temperature detecting device 122, 124 may be configured to detect a different temperature condition in the coils 105 and generate a signal to the controller 128. For example, a first temperature threshold of the first temperature detecting device 122 may be set at a temperature indicative of a pre-freezing condition. A pre-freezing condition may comprise the temperature of the exposed outer surface of the coils 105 at or approaching a temperature at or near the freezing point of water condensation collecting on the outer surface of the coils 105. The surface temperature of the coils 105 may correspond or relate to the temperature of the refrigerant flowing within the coils 105. For example, a pre-freezing condition may comprise the refrigerant flowing within the coils 105 at 39 degrees Fahrenheit, which may cool the exposed outer surface of the coils 105 to at or near 39 degrees Fahrenheit. In other embodiments, a pre-freezing condition may comprise a rate of decrease in temperature (i.e. cooling) of refrigerant in the coils 105.
A second temperature threshold of the second temperature detecting device 124 may be set at a temperature indicative of a freezing condition. A freezing condition may comprise the temperature of the exposed outer surface of the coils 105 at or below the freezing point of water condensation collecting on the outer surface of the coils 105, such as about 29 (twenty-nine) degrees Fahrenheit. The temperature thresholds of the temperature detecting devices 122, 124 may be pre-selected, pre-programmed, or adjustable to accommodate response by the controller 128 to detection of an abnormal temperature condition in the coils 105.
Normal temperature conditions of refrigerant within the coils 105, when the HVAC system 1000 is operating to meet a demand, are within the range 40-60 degrees Fahrenheit. The controller 128 may infer from the state of the first temperature detecting device 122 and the second temperature detecting device 124 that the refrigerant temperature in the coils 105 is within the range of normal temperature conditions when neither the first temperature detecting device 122 nor the second temperature detecting device 124 signals that the temperature of the coils is at a pre-freezing or freezing condition, respectively.
The indication of a pre-freezing condition in the coils 105, which may in some embodiments fall at the lower end of the range of normal temperature conditions, may prompt the controller 128 to take action to address the risk of a freezing condition. In some embodiments, a normal temperature condition may comprise a pre-freezing temperature that is trending warmer. For example, the temperature of refrigerant in the coils 105 may be measured at 38 degrees Fahrenheit at a first time and measured at 40 degrees Fahrenheit at a second time, indicating that the refrigerant is warming in response to operating state of the HVAC system toward normal conditions.
In other embodiments, the first temperature detecting device 122 and the second temperature detecting device 124 may comprise other types of sensing devices which directly or indirectly sense refrigerant temperature. For example, the first temperature detecting device 122 or the second temperature detecting device 124 may comprise a temperature sensor or a pressure detecting device. Each temperature detecting device 112, 124 of the temperature detecting assembly 130 may comprise a different type of device than the other devices.
Referring to
Referring to
Referring to
A first freeze stat 154 and a second freeze stat 156 may be mounted onto evaporator coils 158 of the evaporator 150. The freeze stats 154, 156 may be configured to operate in the manner shown and described in
Referring to
In operation 200 of the method 2000 shown in
The HVAC system 1000 may operate at a full capacity comprising the capacity of the first stage Y1 plus the second stage Y2, as shown in operation 200. In other embodiments, the initial operational state may comprise operation at a reduced capacity, for example, the capacity of the first stage Y1. It will be understood that this method 2000 may be implemented in HVAC systems that do not utilize multi-stage operation.
In operation 202, the first compressor 112 (referred to as “C1”) and the second compressor 114 (referred to as “C2”) may be operating jointly to meet the first demand of the initial state of the HVAC system 1000. The first fluid moving device 101, for example an outdoor fan (“ODF”), and the second fluid moving device 103, for example an indoor fan (“IDF”) may be operating at a “NORMAL SETTING” configured to accommodate the first demand of the initial state. The NORMAL SETTING may comprise a speed setting for each fan IDF and ODF configured to meet the first demand in the initial operational state.
Referring to
In operation 206a, the controller 128 may respond to detection of an abnormal temperature condition by initiating a restart cycle 201 to return the HVAC system 1000 to normal operating conditions, e.g. operations 200 and 202. The restart cycle 201 may comprise one or more adjustments of one or more operating conditions of the HVAC system configured to raise the temperature of the refrigerant in the coils 105 to prevent freezing. The adjustments of the restart cycle 201 may allow the cooling period provided by the HVAC system 1000 to be extended by avoiding a complete and prolonged shutdown of the compressors 112, 114.
In some embodiments, the controller 128 may adjust the rate of heat transfer between the refrigerant flowing in the HVAC system 1000 and the environment. For example, the controller 128 may modify the speed of one or both of the first fluid moving device 101, for example an outdoor fan, and the second fluid moving device 103, for example an indoor fan. In some embodiments, the speed of the IDF is increased by 10% and the speed of the ODF is decreased by 10% from the NORMAL SETTING of the initial state. The adjustment of speed may be varied to accommodate the rate of heat transfer to the coils 105, other environmental conditions, and demands on the HVAC system 1000.
The controller 128 may monitor the temperature condition of the refrigerant in the coils 105. The controller 128 may receive a signal from the first temperature detecting device 122 indicating that the temperature in the coils 105 is no longer in an abnormal condition. For example, the switch of the first temperature detecting device 122 may return to a closed position or remain closed after a reset from the open position, indicating that the temperature is above the pre-freezing condition threshold (e.g. 39 degrees Fahrenheit). The controller 128 may return operation of the HVAC system 1000 to its initial state at operations 200 and 202 to complete the restart cycle 201.
Alternatively in operation 206b shown in
Alternatively in operation 206c shown in
Operation 206c may be used as an alternative to operation 206a if, for example, the pre-freezing condition threshold is set closer to the freezing point in the coils 105. Other factors may contribute to selection of one of the operations 206a, 206b, or 206c, as alternatives to one another, including but not limited to detection of an abnormal rate of change of temperature in the coils 105 or an abnormal pressure in the coils 105 or other portion of the circuit 110.
In operation 208 shown in
Following the initiation of operations 206a, b, or c, the second temperature detecting device 124 may report to the controller 128 that the temperature of refrigerant in the coils 105 has not reached a freezing condition. The controller 128 may continue operations 206a, b, or c for a time period (referred to as an “Override Time” and shown as operation 216) to allow the HVAC system 1000 to return to normal operating conditions (e.g. operations 200, 202), and complete the restart cycle 201. In some embodiments, the controller 128 may override during the Override Time the control logic employed to operate the HVAC system 1000 during normal operating conditions.
Referring to
In some embodiments, the Override Time is preset time period configured to allow time for the temperature of the refrigerant in the coils 105, and other operating conditions of the HVAC system 1000 to return to normal. In some embodiments, the Override Time may comprise about an hour. In other embodiments, the Override Time may be calculated by the controller 128 based on the known operating state of the HVAC system 1000, the demand on the HVAC system 1000, and other environmental conditions.
Detection of a freezing condition in the coils 105 by the second temperature detecting device 124, in operation 208, may indicate that the actions taken in operation(s) 206a, b, or c were not effective in preventing a drop in temperature of the refrigerant in the coils 105 from a pre-freezing condition to a freezing condition. The controller 128, in operation 210 shown in
Referring to
Referring to
Following operation 210, the controller 128, in operation 212, may operate the HVAC system 1000 in a one-compressor configuration, i.e. with either the first compressor 112 on and the second compressor 114 off, or vice versa. Operation 212 may continue for a one-compressor time period. This one-compressor time period may be preset or calculated by the controller 128 to allow time for the refrigerant in the coils 105 to return to at least a pre-freezing condition.
The selection of which compressor 112, 114 to operate in the one-compressor configuration may depend on the capacity of the compressor 112 or 114 and the required demand on the HVAC system 1000. For example, one compressor may comprise a larger total capacity, which may be utilized to meet the demand on the HVAC system 1000, instead of the smaller capacity compressor.
In some embodiments, the speed of the IDF and ODF may be additionally set at the NORMAL SETTING. In other embodiments, the speed of the IDF and ODF may be adjusted from the NORMAL SETTING to meet demand requirements or to adjust heat exchange to respond to the pre-freezing condition in the coils 105.
Following the initiation of operation 212 shown in
Continued detection of a freezing condition in the coils 105 by the second temperature detecting device 124, in operation 214, may indicate that the actions taken in operation(s) 210 or 212 or both were not effective in preventing a freezing condition in the coils 105. The controller 128, in operation 210, may respond to continued detection of freezing condition, for example by shutting down both the first compressor 112 and the second compressor 114 and modifying the speed of the IDF.
After expiration of the one-compressor time period in operation 212 shown in
In response to a determination that the ON compressor is operating normally in operation 219, the controller 128 may issue an alarm (operation 220 shown in
In response to a determination that the ON compressor is malfunctioning in operation 219, the controller 128, in operation 221, may re-initiate operation 212 operating the HVAC system 1000 in a one-compressor configuration. The initial ON compressor (i.e. C1) may be shut down and the other compressor (i.e. C2) may be operated as the ON compressor in the one-compressor configuration.
Referring to
The alarm of operation 220 may be generated in conjunction with other operations of the method 2000, shown in
The alarm of operation 220 may comprise an electronic communication. The communication may comprise a textual or visual summary of data regarding operation of the HVAC system 100, including a characterization of temperature of the refrigerant in the coils 105, such as a chart, graph, or table. The communication may also include information regarding the operability of the compressors 112, 114, and any other information collected or calculated based on the operations of method 2000.
The communication may be sent to a display, stored in memory, or communicated directly to a third party. Referring to
The HVAC system 1000 may be operated in one or more restart cycles in response to detection of pre-freezing condition in the coils 105. In operation 214, for example, determination that the actions taken by the controller 128 in operations 210 or 212 or both or other actions taken in the restart cycle 201 were not effective in preventing a freezing condition in the coils 105 in a first restart cycle may prompt the controller 128 to initiate a second restart cycle. The initiation of a second restart cycle may be instead of or in conjunction with generation of an alarm in operation 220.
The second restart cycle may contain some or all of the operations of the first restart cycle 201 (e.g. shown in
It will be understood by persons of ordinary skill in the art that the controller 128 may comprise one or more processors and other well-known components. The controller 128 may further comprise components operationally connected but located in separate in locations in the HVAC system 1000, including operationally connected by wireless communications. For example, the controller 128 may comprise a first controller unit located on an outside portion of the HVAC system (where the compressor and condenser may be), a second controller unit located on an inside portion (where the evaporator may be), a thermostat for monitoring environmental conditions (on a wall of an enclosed space), and a control unit accessible for user input (embodied on a hand-held wireless unit). The controller 128 may further comprise a timing function for measuring the time periods disclosed herein.
Having thus described the present invention by reference to certain of its preferred embodiments, it is noted that the embodiments disclosed are illustrative rather than limiting in nature and that a wide range of variations, modifications, changes, and substitutions are contemplated in the foregoing disclosure and, in some instances, some features of the present invention may be employed without a corresponding use of the other features. Many such variations and modifications may be considered desirable by those skilled in the art based upon a review of the foregoing description of preferred embodiments. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
4105064 | Del Toro | Aug 1978 | A |
4157649 | Bussjager | Jun 1979 | A |
4474026 | Mochizuki | Oct 1984 | A |
4506516 | Lord | Mar 1985 | A |
20060174640 | Caskey | Aug 2006 | A1 |
20070234746 | Puranen | Oct 2007 | A1 |
20070251251 | Wojdyla | Nov 2007 | A1 |
20080116289 | Lochtefeld | May 2008 | A1 |
20080276637 | Lifson | Nov 2008 | A1 |
20090084120 | Meier | Apr 2009 | A1 |
20100024452 | Lifson | Feb 2010 | A1 |
20100071391 | Lifson | Mar 2010 | A1 |
20100186433 | Galante | Jul 2010 | A1 |
20100251738 | Takegami | Oct 2010 | A1 |
20110314845 | Lifson | Dec 2011 | A1 |
20120167602 | Taras | Jul 2012 | A1 |
20130098086 | Sillato | Apr 2013 | A1 |
Number | Date | Country | |
---|---|---|---|
20150267953 A1 | Sep 2015 | US |