Vapor compression refrigeration, air conditioning and heating (heat pump) systems have long been plagued with less than optimum operating efficiencies due to an inadequate or excessive working fluid charge within the system. Vapor compression air conditioning and heat pumps systems, for example, typically are designed to operate with a working fluid charge which provides a small amount of sub-cooling of the working fluid in its condensed state. However, initial installation, servicing and repair operations are difficult to carry out with respect to providing a proper fluid charge within the system. For example, when removing fluid or adding fluid to the system, there is often inadequate control of flow of the fluid (refrigerant) resulting in an excessive charge of fluid to a system or a system which is undercharged. Historically, it has been necessary to add or subtract fluid and operate the system to “wait and see” if the system comes into a balanced condition or achieves the desired amount of sub-cooling of the fluid in its condensed state. However, the present invention overcomes the inaccuracies and excessive delays in providing properly charged vapor compression air conditioning systems, in particular.
The present invention provides a vapor compression air conditioning (heating, cooling or both heating and cooling) or refrigeration system adapted for optimum operating efficiency with respect to the proper quantity or charge of working fluid disposed in the system. The present invention also provides a method, particularly, for adding working fluid to a vapor compression-type air conditioning or refrigeration system. However, a method of extracting fluid is also contemplated.
In accordance with one aspect of the present invention, a vapor compression air conditioning or refrigeration system is adapted for connection to a fluid adding or fluid extracting unit which may include at least one reservoir of working fluid and one or more conduits for connection to fluid conduits associated with the working fluid compressor of the air conditioning system. A fluid flow restrictor device may be provided in one or more conduits adapted to be connected to the so-called low pressure side of a compressor as well as the high pressure side for adding fluid to or removing fluid from the system circuit, respectively. The flow restrictor device may be adapted for throttling fluid flow in one direction while providing for substantially unrestricted flow of fluid in an opposite direction. The flow restrictor devices may be connected to a portable fluid adding and fluid extracting unit or the devices may be permanently connected to the working fluid conduits associated with or connected to the compressor of a vapor compression air conditioning or refrigeration system.
In accordance with another aspect of the present invention, a vapor compression-type air conditioning system or refrigeration system is adapted to include a control circuit or controller and associated instrumentation which monitors the operating condition of the system during a working fluid charge adding or extracting process to calculate actual sub-cooling of the working fluid as it leaves a condenser unit of the system. The controller is operable to provide a suitable output signal indicating the need to remove additional fluid, add additional fluid or indicate no action needed. Still further, the controller may be adapted to automatically shutoff the flow of working fluid to the system when an optimum operating or selected operating condition is reached.
In accordance with yet a further aspect of the present invention, an improved method is provided for adding working fluid to or subtracting working fluid from a vapor compression air conditioning or refrigeration system which achieves an optimum fluid charge, or at least a fluid charge providing a selected amount of sub-cooling of the working fluid flowing in the system.
Those skilled in the art will further appreciate the above-mentioned advantages and superior features of the invention as well as other important aspects thereof upon reading the detailed description which follows in conjunction with the drawings.
In the description which follows like elements are marked throughout the specification and drawings with the same reference numerals, respectively. The drawing figures are not necessarily to scale and certain features may be shown in generalized or schematic form in the interest of clarity and conciseness.
Referring to
The compressor 16 is connected to heat exchanger 14 acting as a condenser by way of a high pressure discharge conduit 18 and condenser 14 is connected to heat exchanger 12, acting as an evaporator unit, by way of a further high pressure conduit 20 and an expansion device 22. Typically, the heat exchanger 12, expansion device 22 and a portion of a conduit 24 interconnecting the compressor 16 with the heat exchanger 12 are located within the interior of a structure being cooled. A system controller 26 is operably connected to certain components including an indoor fan or blower, not shown, and a second portion 28 of the controller is provided for controlling on and off operation of compressor 16 and for controlling flow of air over heat exchanger 14 by way of a motor driven fan 30. A heat exchange medium other than forced air may be used to control heat exchange by one or both of the heat exchangers 12 and 14. When used as an air conditioning or heat pump system, the system 10 also includes a thermostat 32 connected to controller units 26 and 28. Controller unit 26 is also connected to a source of electrical power via conductor means 36 and for communicating such power to controller unit 28.
Conduit 24 is considered a so-called low pressure conduit leading to compressor 16 for delivering working fluid thereto for compression to a higher pressure. Conduit 24 includes a suitable releasable connector 25a associated therewith disposed in proximity to the compressor 16 and including a one way poppet valve 25c, or so-called Schrader valve known in the art, for conducting refrigerant fluid to or from the system 10, which fluid may be one of several types known to those skilled in the art and used as the working fluid in vapor compression systems. A second releasable connector 27a is connected to high pressure conduit or so called liquid line 20, but may be connected to conduit 18, alternatively. Connector 27a includes a Schrader valve 27c. Conduit 18 is connected to the so-called high pressure side of compressor 16 for conducting heated vapor to heat exchanger 14 for at least partial condensation therein and then discharge to conduit 20.
Accordingly, working fluid flowing out of the heat exchanger 14 through conduit 20 to expansion device 22 is typically in liquid form and the pressure and temperature of such fluid may be sensed by respective temperature and pressure sensors 40 and 42, as shown in
Referring further to
Referring to
As previously mentioned, flow restrictor devices 72 may be interposed in conduits 62 and 66, as illustrated or mounted on and connected to conduits 24 and 20. One preferred arrangement for the devices 72 is to be interposed in the conduits 62 and 66, as indicated in
If it is desired to evacuate working fluid from the system 10 in the event of a fluid overcharge, conduit 66 may be connected to conduit 20 via connector parts 27a and 27b and the arrangement of the flow restrictor device 72 interposed in conduit 66 is such as to provide restricted flow of fluid from conduit 20 to conduit 66 so that control of evacuation of working fluid from the system 10 may be more closely maintained than if there was substantially no restriction to flow of fluid from conduit 20 to conduit 66. When evacuating fluid, valve 67 is opened, valve 65 or valves 60 and 63 are closed, and fluid flows from conduit 66 through valve 67 and conduit 69 to recovery reservoir 70. Accordingly, the flow restrictor devices 72 may be arranged as illustrated in
Accordingly, the devices 72, whether mounted permanently on system 10 in communication with the conduits 24 and 20, or mounted on a fluid charge adding and evacuation apparatus, such as the apparatus 54, assist in providing an improved method for adjusting the charge of working fluid in a vapor compression system, such as the system 10 or an equivalent. Thanks to the provision of the programmable controller unit 44, including part 45, a process may be carried out for adding a charge of working fluid to the system 10 or evacuating a portion of the charge of working fluid from the system 10 to provide the desired degree of sub-cooling of the fluid as it exits a heat exchanger, such as the condenser 14. By monitoring the temperature and pressure of the fluid flowing through the conduit 20, for example, restricted flow of fluid into or out of the system allows for adjusting a steady state operating condition and the desired degree of sub-cooling of the fluid.
In accordance with a preferred process of the present invention, the controller unit 44, 45 is operable to monitor the addition or subtraction of working fluid with respect to the system 10 by causing the controller to enter the so-called charging mode at step 100, see
At step 108, controller unit 44, 45 reads the fluid pressure and temperature and calculates the actual fluid sub-cooling or a pressure representation thereof. The process proceeds to step 112 to determine if the actual sub-cooling of the working fluid is greater than or less than a so-called target sub-cooling condition and a charge error is calculated at step 114. If the charge error indicates excessive sub-cooling at step 116, a suitable indicator is illuminated, such as one of the indicators 46 or 48, or a message is provided at visual display 48a, indicating the need to reduce the charge of working fluid in the system 10, as indicated at step 118. Such may be carried out by pumping fluid or allowing the bleeding of fluid through device 72 connected to conduit 66 for recovery into the reservoir 70. Thanks to the restriction of fluid flow through the device 72 connected to conduit 66 the rate of change of sub-cooling can be closely monitored. In fact, as the process continues to monitor removal of fluid until the total charge is correct at step 120 and the process repeats itself, the controller 44 may generate a suitable control signal or a visual or audible signal.
However, if it is determined at step 116 that recovery or evacuation of working fluid from system 10 is not required but addition of fluid is required, such as indicated at step 122, controller unit 44 may energize valve 60,
If no addition of working fluid is required at step 122, a suitable indicator is illuminated, such as indicator 46, or a message is displayed at display 48a at step 128 advising the operator or user to cease adding fluid to or removing fluid from the system 10, as indicated at step 130. The process is then completed as indicated at step 132. Operation of the valves 63, 65 and 67 to allow flow of fluid between reservoirs 56 and 70 and the system 10, as required by the process described above, is believed to be within the purview of one skilled in the art.
Referring briefly to
In the arrangement of
Accordingly, in accordance with the systems and process described above, vapor compression air conditioning and refrigeration systems may be properly charged with working fluid to prevent flooding of the compressor, provide a faster method of charging and greater accuracy of obtaining the proper charge of working fluid in a system of the types described. Although preferred embodiments of a system and method have been disclosed in detail herein, those skilled in the art will appreciate that various substitutions and modifications may be made without departing from the scope and spirit of the appended claims.
This is a divisional application of the prior filed and co-pending U.S. patent application Ser. No. 11/486,874 filed Jul. 14, 2006 and entitled “System And Method For Controlling Working Fluid Charge In A Vapor Compression Air Conditioning System” which is incorporated herein by reference for all purposes.
Number | Date | Country | |
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Parent | 11486874 | Jul 2006 | US |
Child | 12650249 | US |