|Publication number||US3170304 A|
|Publication date||Feb 23, 1965|
|Filing date||Sep 26, 1963|
|Priority date||Sep 26, 1963|
|Publication number||US 3170304 A, US 3170304A, US-A-3170304, US3170304 A, US3170304A|
|Inventors||Hale Harry T|
|Original Assignee||Carrier Corp|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (4), Referenced by (35), Classifications (8)|
|External Links: USPTO, USPTO Assignment, Espacenet|
Feb. 23, 1965 H. T. HALE REFRIGERATION SYSTEM CONTROL Filed Sept. 26, 1963 IN V EN TOR.
HARRY T. HALE. 3%
1 compressor is inoperative.
3,170,304 REFRIGERATION YSTEM CGNTROL Harry T. Hale, Bridgeport, N.Y., assignor to Carrier Corporation, Syracuse, N.Y., a corporation of Delaware Filed Sept. 26, 1963, Ser. No. 311,716
3 Claims. (Cl. 62155) This invention relates to a control arrangement for refrigeration systems, and 'more particularly to a control arrangement for refrigeration systems operable to selectively heat and cool.
Reverse cycle refrigeration systems, commonly referred to as heat pumps, may includean arrangement for defrosting the system outdoor coil to restore systernefficiency impaired through the formation of frost and ice thereon. While outdoor coil defrosting arrangements may assume various forms, a problem attendant with all forms is that of control, control of defrost initiation, duration, and termination in order that the outdoor coil may be eifectively defrosted when necessary in the shortest possible time.
A usual method of defrosting the outdoor coil of a reverse cycle refrigeration system operating on the heating cycle is to revert to cooling cycle operation. By this arrangement, relatively hot gaseous refrigerant discharged from the system compressor is directed to the outdoor coil. However, operation of the system on the cooling cycle to effect removal of frost and ice from the outside coilinterrupts the heating cycle and extracts heat from the area being conditioned. In systems Whichutilize this method for defrosting the outdoor coil, the system may 7 start up on the defrost or cooling cycle in response to a demand for heat. This is undesirable and unnecessary.
With the above discussion in mind, it is a principal object of the present invention to provide a new and improved defrost control arrangement for reverse cycle refrigeration systems.
It is a further object of the present invention to provide a control arrangement and method of control for a re- United States Patent attest Patented Feb. 23, 1965 ice up of the system on the defrost cycle when the compression means is energized.
The invention further relates to a method of operating a reverse cycle refrigeration-system selectively energizable to heat and cool an enclosure having means for removing frost accumulated on the outdoor coil in which the steps consist in sensing outdoor coil conditions, periodically.
closing a switch for a relatively short interval, actuating the frost removing means on the occurrence of an outdoor coil condition during. closure of the switch, bypassing the switch to maintain actuation of the frost removing means upon opening of the switch at the expiration of the relatively short interval, sensing energiz ation of the system compressor, and limiting actuation of the frost removing means to periods when the system compressor is energized to prevent start-up of the system on the defrost shown for the purpose of illustrating this invention an verse cycle refrigeration system effective to prevent startup of the system on the cooling or defrostcycle in response to a demandfor heat.
It is an additional object; of the present invention to provide an improved control arrangement and method of control for a reverse cycle refrigeration system effec tive' to prevent the defrost controlling mechanism from r V assuming a defrost initiatingposition while the system This invention relates to a control arrangement for a reverse cycle refrigeration system having compression means, an outdooor coil, refrigerant metering means, and
an indoor coil' connectedin refrigerant flow relationship operable upon energization of the compression means to cool, and reverse means effective to connect the compres-' sion means, indoor coil, refrigerant metering means, and outdoor coil in refrigerant flow relationship operable upon energization of the compression meansito heat, comprising in combination means for defrosting the outdoor coil including first 'rneans actuated in response to a predetermined outdoor coilrcondition to ready thedefrosting means for operation, second means periodically actuated to ready the defrostingmeans for operation, the defrosting meansbeingresponsive to thesimultaneous actuation of the first and second means to defrost the outdoor coil, the second means being'adapted to terminate outdoor coil defrost after a predetermined time interval,
the first means intervening to terminate outdoor coil defrost during the predetermined time interval n response to a second outdoor coil condition, and means forrenair-to-air heat pump employing a refrigeration system operable under the reverse cycle principle. In apparatus of this type, a first heat transfer coil is disposed within the areato be conditioned by the heat pump and a second coil is located outside the area, usually in the ambient.
Compressor it) discharges relatively hot gaseous refrigerant through discharge line 11 to the reversing means 7 12, preferably a four-way reversing valve, which is employed for the purpose of reversing refrigerant flow, through a portion of the system in order to obtainthe desired heating and cooling effects. From reversing means 12, controlled by the operation of the solenoid 13 in a mannerlater to be described, the hot gaseous refrigerant flows during cooling cycle operation through line 14 to outdoor heat exchange coil 15 wherein condensation of the gaseous refrigerant occurs as ambient air is passed over the surface of outdoor coil 15 by fan 20. t
The condensed liquid refrigerant flows from coil 15 through suitable expansion means 16 to indoor heat ex-,
change coil 17, serving as an evaporator during the cooling cycle. Line 22 having check valve control 27 operable to permit flow'in the direction shown by'the solid line arroW provides a path for refrigerant flow around expansion means 28. The expansion means 16 provides the requisite pres'surefdrop between the heat exchange coils in the refrigeration system during cooling cycle operation. In indoor heat exchange coil' 17, refrigerant is vaporizedas heat is extracted from the streamof. air delivered over the indoor coil by fan .21. Vaporousrefrigerant.
- so formed flowsfihrough I line 18 to reversing valve 12 dering the defrostingmeans inoperable in response to de-' energization of the compression means to pre'ventfstartfrom whence the refrigerant flows through suction line 7 19 back to compressor lilto complete the refrigerant flow cycle.
drive mechanism, for, example, 26 respectively.
Toheatthe area to' be treated, the reversing valve 12 is actuated to place linelfi in communication with dis-- 7 7 Under these circumstances heat front the hot gaseous refrigerant flowing into coil 17. is rejected to the air within the area to be treated. ,flhe rejection of heat from the refrigerant converts the'gaseous refrigerant vto liquid, refrigerantwhich flows throughv eXpan-} f sion means 28 to outdoor coil 15, Which'now functions charge line 11 Each of the rinses and 21 may be driven by suitable electric motors 25 and ar ans as an evaporator. Line 29 having check valve control 31 operable to permit flow of refrigerant in the direction shown by the dotted line arrow, provides a path for refrigerant flow around expansion means The vaporous refrigerant created in outdoor coil is" as a result or" heat transfer between the refrigerant and the amoient air fiows through reversing valve 12 into suction line 19 back to compressor Expansion means 2:; provides the requisite pressure drop between heat exchange coils in the refrigeration system during heating cycle operation. i
A suitable low pressure cutout control 23 may be connected to the suction line 19. Low pressure cutout control 23 actuates a switch in the electrical circuit as will be later described.
As above noted, the refrigeration system may he incapable of providing sufiicient heat to the area to be treated during heating operation, especially when the heat pump is used in geographical areas which are subject to low outdoor ambient temperatures. An auxiliary heater fat-which consists of a suitable high resistance wire through which current is adapted to be selectively passed may be used to provide supplementary'heat. Thusthe air, heated to a certain de ree by being induced through heat exchange coil 17 by fan 21, is further heated by being passed over resistance wire 24 which is energized upon closing of switch 1%. I
Referring to FIGURE 2 of the drawings, a suitable source of alternating current (not shown) is adapted to supply current via leads Ll and L2 to a primary control circuit. It will be understood that the system can opcrate on three-phase current, if it is suitably modified.
The motor 36 for driving compressor 19 is energized when contacts 31 and 32 are closed. A contactor coil 35 for closing contacts 31 and 32 is provided.
A timer motor 37 for controlling energization of corn press-or. motor 3i in response to a demand for heating or cooling is provided. Timer motor 37 drives a suitable switch actuating mechanism, such as cam means operative to move timer switches 39 and 4t) between the position shown in solid lines in FIGURE 2 ofthe drawings and that shown in dotted lines. Timer switch 39, when in the solid line position, connects contactor coil. 35 in series with control switch 42 and switch 43 across leads L1 and L2. Timer switch as, whenin the solid line position, connects timer motor 37 in series with switch 49 across leads L3. and L2. switch 43 and opening switch 49 is provided parallel to contactorcoil 35' across leads L1 and L2 in series with control switch 4-2 and switch 43. Timer switch 39, when in the dotted line position, bypasses switch 43. Timer switch 56*, when in thedotted line position, connects timing motor 37 in series with control switch 42 across leads Lll and L2. 7 a V Gutdoor fan motor 25 is connected in series with a v control switch d and defrost switch 55 across leads L1 and L2. Reversing valve solenoid :13 is connected'across leadsLl and L2 in series with defrost switch 55 and reversing valve switch 56. 1 g
A defrost relay coil 58 adapted when energized to initiate defrosting of outdoor coil 15 .is connected'in series with defrost thermostat across leads'Ll and L2. De-
A relay coil 59 for closing.
ner to be more fully explained hereinafter. Indoor fan motor 26 is connected in series with indoor fan switch '72 across leads L1 and L2.
The secondary control circuit may be electrically connected to the primary control circuit by means of a transformer '74. Included in the secondary circuit is a room thermostat '75 comprising a two-stage heating thermostat and a single-stage cooling thermostat. The first stage of a heating thermostat 76 is in series with reversing valve relay 77. The second stage heating thermostat 79 is in series across outdoor thermostat 81 and resistance heater relay 82. When energized, relay 82 closes switch 1% to energize resistance heater 24. Defrost relay switch 85 is disposed across heating thermostats 76 and 79. Switch 36 is closed during the defrost operation to energize the resistance heater 24 in a manner to be more fully eX- plained hereinafter.
Also provided in the secondary control circuit are fan switch 37 which may be manually moved from an automatic position shown in solid line to a continuous operating position, shown in dotted line, and indoor fan relay 9d in series therewith.
A control relay 92 is in series across the secondary circuit with a first low pressure switch 83 and cooling thermostat Low pressure switch 83 is normally closed. A circuit connecting a second low pressure switch S4 and defrost relay switch in series parallels low pressure switch 83. Closure of switches 34 and 85 bypasses low pressure switch 33. Low pressure switches 33 and 84 are opened and closed respectively in response to a predetermined suction pressure as sensed by low pressure cutout control 23.
Operation During cooling operation, the cooling thermostat 80 of the room thermostat '75 will close in response to a predetermined demand for cooling. Assuming that the indoor fan switch arm 87 is in the solid .ine position permitting automatic operation thereof, indoor fan relay )0 is energized to close indoor fan relay switch 72 in the primary control circuit thus energizing indoor fan motor 26.
At the same time fan control relay 92 is energized to close control switches 42 and 54. A first circuit is completed via lead Lil, normally closed defrost relay switch 55, control switch and lead L2 to energize outdoor fan motor 25. A econd circuit is completed via lead LL control switch 42, timer switch 39, in dotted line position, and lead L2 to energize relay coil 5%. Relay coil 56 closes switch 43 and opens switch A third circuit is completed via lead Lil, control switch 42, timer switch 46 and lead L2 to energize the timer motor 37. After a predetermined interval, the witch actuating mechanism driven by timer motor 37 moves timer switches 39 and 46 to the solid line position.
frost timing motor 62 is connected in series across leads I timer switch and is connected across leads L1 and L2 in series with defrost timer switch 64, defrostirelay coil 58, and defrost thermostat 60. Defrost timer switch 65,
normally open, and defrost switch 64, normally closed, are adapted to be periodically closed and opened respectively for a short duration in a predetermined sequence by the defrost timermotor driven mechanism in a manto drive compressor 19.
to the solid line position places timer motor 37 in series Movemcntof timer switch tothe solid line position completes a circuit from' lead Ll through control switch 12 and switch 43 to lead L2 to energize contactor coil 35. Contaetorcoil 35 closes compressor control contacts 31 and 32 to'energize the compressor motor 30 Movement of timer switch 4-5) with switch d9, now open, to tie-energize the timer motor. During cooling operation, compressor 10 forwards 'high pressure vaporized refrigerant through reversing Operation ofthe system on the heating cycle is in Conitiated by closure of the first. heating stage 76 of the room thermostat 75 in response to a demand for heating Closure of first heating stage 76 energizes reversto energize reversing valve solenoid 13 to move reversing valve 12 to the heating position upon energization of compressor whereby refrigerant in discharge line 11 passes through line 18 to indoor heat exchange coil 17.
Closure of reversing valve switch 85 energizes control relay 92 to close control switches 4-2 and 54. Closure of control switch 42 effects energization of compressor motor 30 after a predetermined interval of time as described heretofore. gization of outdoor fan motor in the manner described heretofore.
Under the heating cycle of operation, refrigerant flows from indoor coil 17 through refrigerant metering means 16 to the outdoor coil 15. Heat rejected to the air passing over the indoor heat exchange coil warms the air being supplied to the area being conditioned. The hot vaporized refrigerant discharged from compressor 10 is condensed in the indoor coil 17. The refrigerant vaporized in outdoor coil as a result of heat-transfer between the refrigerant and the ambient air flows through reversing valve 12 into suction line 19 back to compressor 10.
During heating cycle operation, ambient conditions may be such that a coating of frost and/or ice forms on outdoor coil 15. The defrost control means depicted in FIGURE 2 are operable to sense this accumulation of frost and/or ice and in response thereto, to temporarily reverse the system to cause the system to act on the defrost cycle to remove the accumulated frost and/ or ice.
Defrost timer motor 62 operates continuously. Periodically the switch actuating mechanism driven by the defrost timer motor closes defrost timer switch 65 for a brief interval. When defrost thermostat 60 senses a need for defrost and closes, a circuit is completed at the closure of defrost timer switch 65 via lead L1, defrost timer switches 64 and 65, defrost thermostat 60, compressor control switch 32, and lead L2 to energize defrost relay 58. Defrost relay 58 closes defrost relay switch 70 to provide a holding circuit therefor and opens defrost rclay switch 55 to de-energize reversing valve solenoid 13 and outdoor fan motor 25. At the same time, defrost relay 58 closes defrost relay switch 86 to permit energization of the auxiliary resistance heater 24 in a manner to be more fully explained hereinafter.
De-energizat-ion of reversing valve solenoid 13 permits reversing valve 12 to move to the position shown in FIG- URE l. of the drawings whereby hot gaseous refrigerant from the compressor 1%. is passed directly to outdoor coil 15 to remove frost and ice accumulated thereon.
As noted, during the defrost cycle, defrost relay switch 55.is open and outdoor fan motor is accordingly d e-energized. It is," however, desirable that the indoor fan be operative, to provide a loaded evaporator whereby evaporator head pressure is maintained to insure the discharge of relatively hotgaseous refrigerant from the compressor. Continued operation of indoor fan 21 during the-defrost cycle is assured in the following manner. The build-up of ice on outdoor coil 15*results in a drop in suction pressure. At a predetermined suction pressure, low pressure cutout 23 will open switcl1 83 and close switch 84. Closure of switch 84 maintains the circuit through indoor fan relay 90 to keep indoor fan control switch 72 and the indoor fan motor 26 u operating. 1
i Upon removal-ofthe frost and ice from outdoor coil 15, defrost thermostat ea opens. Additionally, normally Closure of control switch- 54-eifects enernisrn within a predetermined time after closure of timer switch 65. If defrost thermostat 64 opens within the predetermined time before timer switch 64 opens, defrost relay .58 is tie-energized to terminate the defrost cycle in a manner to be described hereinafter. Should defrost thermostat 6% not open within the predetermined time before timer switch 64 is opened by the defrost timer motor 62, the opening of timer switch 64 de-energizes defrost relay 53 to terminate the defrost cycle. Deenergization of defrost relay 58 upon the opening of either defrost thermostat 66 or defrost timer switch 64, permits defrost relay switch 55 to close completing a circuit from lead L1 through switch 55, reversing valve switch 56, and compressor control switch 32 to lead L2 to energize reversing valve solenoid 13 to move reversing valve 12 to the heating position. A circuit is completed from'the lead L1 through defrost relay switch 55 h the scope of the following claims.
closed timer switch 64'is opened for a brief interval by 1 the defrost timer motor driven switch actuating mecha and control switch 54 to lead L2 to energize outdoor fan motor 25.
If during operation of the system on the heating cycle, the demand for heat exceeds that capable of being supplied by the system alone, second stage heating thermostat 79 of indoor thermostat 75 will close at a predetermined temperature. 'In series with the auxiliary heater relay 82 and thermostat 79 is an outdoor thermostat 81. Outdoor thermostat 81 closes in response to a predetermined outdoor temperature. Closure of both second stage heating thermostat 79 and outdoor thermostat 81 energizes auxiliary heater relay 32 to close switch energizing resistance heater 24 to provide supplementary heat.
The heretofore described defrost control arrangement causes the system to revert to cooling cycle operation. During cooling cycle operation, the indoor coil 17 functions as an evaporator. cycle that indoor fan 21 be maintained in operation. However, the air blown over the indoor coil 17 during defrost cycle operation is chilled resulting in discomfort to occupants of the room being conditioned.
In the present heat pump control arrangement, air discharged into the room by the indoor fan 21 during the defrost cycle is tempered. This is effected by maintaining the auxiliary heater relay 82 energized during defrost cycle operation. As noted heretofore, defrost relay switch 86 is closed on the defrost cycle. Closure of switch 86 completes a circuit through first stage heating thermostat 76 and defrost relay switch sew energize heater relay 82 to close switch ltltl and energize resistance heater 24.
By the novel control arrangement shown in FIGURE 2 of the drawings, the control circuitry for thedefrost cycle is made dependent for its energization upon actuation of the system compressor. This dependency is effected by the positioning of compressor control switch 32in series with the energizing circuit for defrost relay 5% andv reversing valve solenoid 13. With this arrangement should the defrost timer motor-driven switch .65 and defrost thermostat of simultaneously close while the unit is shut down, the'defrost relay coil 58 is not energized to close the holding switch 70 to lock the defrost control circuitry in defrost initiating condition. The unit therefore will not, upon closure of the first stage heating thermostat 76 in response to a demand for heat, start up on the defrost or cooling cycle.
It is understood that while the defrost control circuitry including defrost relay 5% and reversing valve solenoid 13 are illustrated in series with compressor control switch 32, the defrost control circuitry may be placed in series with the compressor control switch 31.
While I have described a preferred embodiment of the invention, it will be understood that the invention is not limited thereto, since it may be otherwise I claim: 3 p 1. In a control arrangement for a reverse cyclerefrigeration system having compression'means, an outdoor It is desirable during defrost embodied in coil, refrigerant metering m ans, and an indoor coil con- I nected in refrigerant flow relationship operable upon energization of the compression means to cool, reversing means effective to connect the compression means, indoor coil, refrigerant meterin! means, and outdoor coil in refrigerant flow relationship operable upon energization of the compression means to heat, the combination of means for defrosting the outdoor coil including first means actuated in response to a predetermined outdoor coil condition to ready said defrosting means for operation and second means periodically actuated to ready said defrosting means for operation, said defrosting means being responsive to the substantially simultaneous actuation of said first and second means to defrost said outdoor coil, said second means being adapted to terminate outdoor coil defrost after a predetermined time interval,
said first means intervening to terminate outdoor coil 7 said first switch, actuation of said second means closing said second switch, said regulating means including switch meansfor interrupting said compression means and defrosting means energizing circuits tode-energize said compression means and prevent completion of said dcfrostin" means energizing circuit on closure of said first and second switches during de-energization of said compression means, 3. The control arrangement according to claim 2 in which said defrosting means energizing circuit includes a third switch, said second means being operable to open said third switch within said predetermined time interval following closure of said first switch to terminate outdoor coil defrost.
References Cited by the Examiner UNITED STATES PATENTS 2,143,687 1/39 Crago 62155 2,182,691, 12/39 Crago 62-160 2,847,833 8/58 Merrick 62-155 2,934,323 4/60 Burke 62155 ROBERT A. OLEARY, Primary Examiner. WILLIAM J. WYE, Examiner.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US2143687 *||May 20, 1937||Jan 10, 1939||Gen Electric||Defrosting control for heat pumps|
|US2182691 *||May 20, 1937||Dec 5, 1939||Gen Electric||Condition control system|
|US2847833 *||Sep 1, 1955||Aug 19, 1958||Carrier Corp||Defrost control for refrigeration systems|
|US2934323 *||Dec 3, 1956||Apr 26, 1960||Carrier Corp||Air conditioning apparatus|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US3273352 *||Jun 14, 1965||Sep 20, 1966||Carrier Corp||Refrigeration system defrost control|
|US3619722 *||May 4, 1970||Nov 9, 1971||Acme Ind Inc||Refrigeration protective system|
|US4137725 *||Aug 29, 1977||Feb 6, 1979||Fedders Corporation||Compressor control for a reversible heat pump|
|US4209994 *||Oct 24, 1978||Jul 1, 1980||Honeywell Inc.||Heat pump system defrost control|
|US4211089 *||Nov 27, 1978||Jul 8, 1980||Honeywell Inc.||Heat pump wrong operational mode detector and control system|
|US4232530 *||Jul 12, 1979||Nov 11, 1980||Honeywell Inc.||Heat pump system compressor start fault detector|
|US4246763 *||Oct 24, 1978||Jan 27, 1981||Honeywell Inc.||Heat pump system compressor fault detector|
|US4276751 *||Sep 11, 1978||Jul 7, 1981||Saltzman Robert N||Ice making machine|
|US4338790 *||Feb 21, 1980||Jul 13, 1982||The Trane Company||Control and method for defrosting a heat pump outdoor heat exchanger|
|US4598558 *||May 23, 1985||Jul 8, 1986||Thermal Concepts, Inc.||Heat pump and method|
|US4644759 *||Jun 30, 1986||Feb 24, 1987||Thermal Concepts, Inc.||Heat pump and method|
|US4843838 *||Dec 23, 1987||Jul 4, 1989||Allen Trask||Air-to-air heat pump|
|US7878006||Feb 1, 2011||Emerson Climate Technologies, Inc.||Compressor diagnostic and protection system and method|
|US7905098||Mar 15, 2011||Emerson Climate Technologies, Inc.||Compressor diagnostic and protection system and method|
|US8160827||Oct 30, 2008||Apr 17, 2012||Emerson Climate Technologies, Inc.||Compressor sensor module|
|US8335657||Jul 5, 2011||Dec 18, 2012||Emerson Climate Technologies, Inc.||Compressor sensor module|
|US8393169||Mar 24, 2008||Mar 12, 2013||Emerson Climate Technologies, Inc.||Refrigeration monitoring system and method|
|US8474278||Feb 18, 2011||Jul 2, 2013||Emerson Climate Technologies, Inc.||Compressor diagnostic and protection system and method|
|US8475136||Jan 11, 2010||Jul 2, 2013||Emerson Climate Technologies, Inc.||Compressor protection and diagnostic system|
|US8590325||Jul 12, 2007||Nov 26, 2013||Emerson Climate Technologies, Inc.||Protection and diagnostic module for a refrigeration system|
|US8964338||Jan 9, 2013||Feb 24, 2015||Emerson Climate Technologies, Inc.||System and method for compressor motor protection|
|US8974573||Mar 15, 2013||Mar 10, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9017461||Mar 15, 2013||Apr 28, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9021819||Mar 15, 2013||May 5, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9023136||Mar 15, 2013||May 5, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9046900||Feb 14, 2013||Jun 2, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring refrigeration-cycle systems|
|US9081394||Mar 15, 2013||Jul 14, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9086704||Mar 15, 2013||Jul 21, 2015||Emerson Climate Technologies, Inc.||Method and apparatus for monitoring a refrigeration-cycle system|
|US9121407||Jul 1, 2013||Sep 1, 2015||Emerson Climate Technologies, Inc.||Compressor diagnostic and protection system and method|
|US9140728||Oct 30, 2008||Sep 22, 2015||Emerson Climate Technologies, Inc.||Compressor sensor module|
|US20050235663 *||Apr 4, 2005||Oct 27, 2005||Pham Hung M||Compressor diagnostic and protection system and method|
|US20090071175 *||Mar 24, 2008||Mar 19, 2009||Emerson Climate Technologies, Inc.||Refrigeration monitoring system and method|
|DE2627526A1 *||Jun 18, 1976||Jan 13, 1977||Carrier Corp||Bewegliches ausdehnungsventil|
|EP0033781A2 *||Dec 23, 1980||Aug 19, 1981||Honeywell Inc.||Compressor fault detection and control system for a heat pump|
|WO1986003578A1 *||Dec 11, 1985||Jun 19, 1986||Thermal Concepts Inc||Heat pump and method|
|U.S. Classification||62/155, 62/161, 62/81, 62/160, 62/158|