US2468626A - Refrigerating apparatus - Google Patents

Description

April 26, 1949, c. D. GRAHAM REFRIGERATING APPARATUS Filed July 16, 1945 2 Sheets-Sheet 2 IIIIIF Patented 1949 UNITED s'rAra anrniosaarmd arrm'rus Charles D. Graham,-Dayton, Ohio, alsignor General Motors Corporation, Dayton, Ohio, a

corporation ofDelaware Application July 10, 1945, 861181 No. 605,248

19 Claims. (Cl. 251-3) This invention relates to refrigerating apparatus and more particularly to an improved control arrangement for a reverse cycle air conditioning system. Y

It is an object of this invention to provide an improved reverse cycle refrigerating system which may be used efliciently to supply heat during extreme cold weather.

r A further object of this invention is to eliminate the danger of freeze-up of the evaporator of a reverse cycle system when the outside temperature falls below the temperature at which condensate would freeze on the evaporator.

Still another object of this invention is to reduce the size of the refrigerating apparatus required for supplying year-around air condi.-

tioning.

Another object of this invention is to provide invention will be apparent from the followin description, reference being had to the accom panying drawings, wherein a preferred form of the present invention is clearly shown.

In the drawings:

Fig. 1 of the drawing diagrammatically shows a preferred embodiment of my invention;

Fig. 2 is a fragmentary view diagrammatically showing the refrigerant flow connections through the reversing valve device during the heating cycle; and

Fig. 3 diagrammatically shows a modified arrangement in which the change-over from heatting to cooling is accomplished by the shifting of suitable air dampers.

The desirability of year-around air condition= ing utilizing a reverse cycle refrigeration system has long been recognized; but numerous problems have limited the use of reverse cycle air conditioning to relatively few installations. One of the problems in the use of a reverse cycle air conditioning system is that the evaporator of an ordinary reverse cycle system condenses moisture out of the outside air and this moisture freezes on the surface of the evaporator thereby reduc-, ing the emciency of theevaporator to a point that the system becomes ineffective when maximum heating is required. Another disadvantage of the ordinary reverse cycle system is that its capacity decreases as the need for heating increases. Under favorable conditions a reverse cycle system has a high performance factor; but as the out-door temperatures decrease and the need for heating increases the performance facv 2 I tor rapidly decreases. I have found that by supplying an adequate amount of auxiliary heat in the outside air stream ahead of the evaporator energy supplied to an electric heater placed in a room will yield approximately 3415 B. t. u.s of

heat whereas'the same amount of electrical energy supplied to the compressor of a reverse cycle I refrigerating system will yield 15,000 B. t. u.s of heat or even more so long as the outside air temperature does not drop much below F. From the above it is apparent that the performance factor of a reverse cycle system is very nearly 5 under favorable conditions. However, asthe outside air temperature decreases, the performance factor of the reverse cycle system. will decrease unless some means is provided for maintaining the temperature of the air flowing over the evaporator substantially constant. In the reverse cycle air conditioning system set forth herein a large variable capacity auxiliary heater is provided for maintaining the temperature of the outside air flowing over the evaporator substantially uniformly at 55 F. even though the outside air temperature falls below this value.

Referring now to Fig. 1 of the drawing wherein I have shown a preferred embodiment of my invention, the enclosure to be conditioned has been designated by the reference numeral it. Air is withdrawn from the enclosure Ill through the duct i2 and is mixed with fresh air supplied through the fresh air inlet I s before being discharged into the conditioning chamber 05. A heat exchange unit is is disposed within the chamber It for either heating or cooling the air as will be explained more fully hereinafter. purposes of illustration I have shown afan unit 20 disposed within the air conditioning chamber it for circulating air through the chamber It. The conditioned air is discharged into the closure it through theduct 22 in which there is I located anauxiliary heater 23 for a purpose explained hereinafter.

Anoutside air duct 2 5 is provided within which an air circulatingfan unit 28, a conventional motor-compressor unit 28, aheating coil 30 and aheat exchange unit 32 are arranged in the order shown. Theheat exchange unit 32 is connected to the motor-compressor unit 28 through therefrigerant line 34 whereas the heat exchange unit I8 is connected to the motor-comrpressor unit "by the refrigerant line 38. A

For

'restrictor 44 is provided in the refrigerant line .46 which connects the coils I8 and 32. The

fixed restrictor serves to control the flow of ree frigerant in either direction with the result that either one of the heat exchange units I8 and 32 may be used to evaporate refrigerant and the other may be used to condense refrigerant .in accordance with practice which is now well known.

When it is desired to operate the system as a cooling system the heat exchange unit I8 serves as an evaporator and theheat exchange unit 32 serves as a condenser. When it is desired to operate the system as a heating system thechangeover valve 40 is shifted from the position in which it is shown in Fig. 1 to the position in which it is shown in Fig. 2, so as to cause the heat exchange unit I8 to serve as a condenser and theheat exchange unit 32 to serve as an evaporator. The capacity of the system is such that when only a small amount of heating is required the reverse cycle system will supply the necessary amount of heat without the addition of any auxiliary heat by either theheating unit 23 or theheating unit 30. As the outside air temperature decreases. and the amount of heat required increases it becomes desirable to supply auxiliary heat to theheater 30. For purposes of illustration I have shown theheater 30 in the form of a steam coil whereas the arrangement of the system is such that electric heat, gas heat or any other form of heat maybe used' to advantage. It will be noted that the arrangement of the ducts is such that outside air only flows over the motor-compressor unit and all of the air which flows over theheating unit 30 is discharged into the outside atmosphere. This arrangement has several advantages. One of the advantages auxiliary heat during the heating season.

of placing theheater 36 directly in theoutside 7 air duct 24 is that the heat can be furnished by the combustion of gas, oil or solid fuel directly in the air stream thereby eliminating the inefficiencyof the usual heat transfer medium. The arrangement of the various heat exchange units and the air ducts is such that the duct 24 may be remote from the chamber I6 and the heat exchange unit I8 may be mounted directly in the enclosure to be conditioned, if desired.

In the arrangement shown in Fig. 1 of the drawing the supply of heat to theheating unit 30 is controlled by three valves, 50, 52 and 54, which are arranged as shown. The master valve is controlled by thethermostat 56 located in the space to be conditioned and is adapted to be opened Whenever thethermostat 56 calls for either heating or cooling. Thethermostat 56 also controls the motor-compressor unit 28 and is adapted to deenergize the motor-compressor unit 28 when neither heating nor cooling is required.

This master valve then serves to shut 01f the heat when the main system is shut down. Thevalve 54 is controlled by athermostat 60 placed directly between theheater 30 and theheat exchange unit 32. Thethermostat 60 tends to maintain a temperature at approximately 55 at the inlet to theheat exchange coil 32. Thus, as the temperature of the air reaching thecoil 32 falls below 55, thevalve 54 tends to open but as the temperature in creases above 55 thevalve 54 closes. By virtue of this arrangement thevalve 54 will remain closed at all times during the summer season when the 4 outside temperatures are high and cooling only is required. Thevalve 52 which is arranged in parallel with thevalve 54 is controlled by athermostat 62 located within the conditioned space. Whenever the temperature in the conditioned space drops considerably below normal thereby indicating that the capacity of the heating system should be increased to take care of an abnormal load, thevalve 52 begins to open irrespective of the temperature of the air flowing over thethermostat 60. Thevalve 52 is primarily useful when the outside temperature is above 55" and it is desired to quickly heat up the enclosure I6 such as when the apparatus is first turned on after a period of non-use. Thus during normal continuous operation of the system thevalve 52 may never be called upon to open unless the air temperature within the conditioned space becomes abnormally low. Thevalves 52 and 54 could be replaced by a single valve controlled jointly bythe temperature of the air inthe conditioned space and at the inlet to the evaporator.

The refrigeration cycle may be reversed either manually or automatically in accordance with usual practice. For purposes of illustration, I have shown athermostat 64 located in the conditioned space, II] for operating the diagrammatically shown change-overvalve device 40.

Theheater 23 located in the conditionedair duct 22 may be of any well known type and may be used either for reheating the air during the cooling season or it may be used for supplying Theheater 23 also may be used to heat air for the space I!) if for any reason the refrigeration system is out of operation and heat is required.

In the modification shown in Fig. 3, the space to be conditioned is designated by the reference numeral I0 and the air conditioning chamber isgenerally designated by the reference'numeral I2. The central section of the chamber I2 is divided into two airflow passages I4 and I6. An evaporator I8 is arranged in the passage I6 whereas a condenser is arranged in the passage I4. The evaporator I8 and thecondenser 80 form a part of a refrigerating system which also includes the motor-compressor unit 82 which serves to withdraw refrigerant vapor from'the evaporator I8 andto discharge compressed refrigerant into thecondenser 80. The refrigerant flows from thecondenser 80 to the evaporator I8 through the refrigerant line 84 within which there is provided a conventional refrigerant flow control device 86. The refrigerant flow control device 86 may be of the fixed restrictor type, the th'ermostatic expansion valve type or of any other type which suitably serves to control the flow of refrigerant from the condenser to the evaporator.

A mixture of return air and fresh air-to be conditioned is supplied to the chamber I2 through the air duct 88 which has a return air inlet opening at 90 and a fresh air inlet opening at 92 as shown. A pivoteddamper 94 is provided at the outlet of the air duct 88 for directing the air to be conditioned either into the airflow passage I6, in which the evaporator I8 is located, or into the airflow passage I4 in which the condenser 8.0 is located. A pair ofdampers 96 and 98 are provided for directing outside air which enters the chamber I2 at I00 into one or the other of the passages I4 and I6. Thedampers 94, 96 and 98 are operated in unison and are so constructed and arranged that they serve to direct the air to passages. When the dampers ll, and 00 are arranged as shown by the solid lines in Fig. 3, the air-leaving the duct 00 is directed over the evaporator and the outside air is directed over the condenser 00. By moving these dampers into their dotted line positions, the incoming air to be conditioned is directed over the condenser 00 so as to be heated and the outside air, which supplies some or all of the heat, is directed over the evaporator I0 and is thereafter discharged into the outside atmosphere. A somewhat similar set of dampers I02, I04 and I00 is provided for directing the air leaving the possages I4 and 15. When the dampers I02, l0l and I00 are arranged as shownby the solidQlin'es in Fig. 3, the cooled air leaving the evaporator I0 is directed into the space 10 and the heated air leaving thecondenser 80 is directed to the Outside through the outlet I01. These dampers are so constructed and arranged that when the dampersoccupy the positions indicated by the dotted lines, the heated air is discharged into the space vl0 and the cooled air into the outside atmosphere through the outlet I01. Thedampers 94, 06, 98, I02, I04 and I08 are adapted to be operated in unison and maybe controlled manually or antomatically. In the event that automatic controls are used for operating these dampers, the control would preferably respond to the temperature of the air within the conditioned space, or to the combination of inside and outside air temperatures. A pair of fan'units I08 and H0 are provided as shown for propelling the air through the passages It and 16 respectively. In order to operate the refrigeration system with a high performance factor and inorder to prevent freezeup of the evaporator I8 during cold weather, I have provided a heating unit II2 which corresponds in function and operation to the heating .unit described in connection with the system shown in Figs. 1 and 2. The flow of heating medium to theunit 2 is controlled by a set of at the inlet to the evaporator I8. The valve I52 is controlled by a'thermostat I55 arranged within the enclosure 10 and serves to open the valve I52 when the temperature within the enclosure I0 falls below a predetermined value such as F. The valve I50 and the motor-compressor unit 82 are both controlled by the thermostat I64 located in the space 10. The thermostat ltd is arranged to turn on the motor-compressor unit 82 and to open the valve I50 whenever the temperature within the space I0 falls below or goes above the temperature range sought to be maintained within the space It.

By virtue of the above described arrangement, none of the air heated by the heating unit H2 is ever discharged into the conditioned space 10. This being the case, it is possible to use any form of direct heat for heating air flowing through thepassage 16. A heating unit I23 is provided in the conditioned air duct I05 and is intended to correspond in construction and operation to the correspondingunit 23 provided in the system shown in Fig. l. The heating unit I23, likethe'unit 23, may be used for reheating the air during the cooling cycle or it may be used for supplying heat to the air being discharged into the space 10 duramps ing'theheatingseason. Theheatingimitsfl and I23 may be manually controlled orautobe automatically controlled temperature or humidity.

While the form oi. embodiment of the invention as herein disclosed, constitutes a preferred form,

it is to be understood that other forms might be adopted, as may come-within the claims which follow.

What is claimed is as follows:

- 1. Apparatus for heating air for an enclosure comprising in combination, a first heat exchange unit, a second heat exchange unit, means for transferring heat from one of said units to the other of said units. means for flowing a first stream of air in thermal exchange with said first heat exchange unit and for discharging said stream of air into said enclosure, means fori'lowing a second stream of air in thermal exchange with said second heat exchangeunit and for discharging, said second stream of air into the outside atmosphere, heating means for supplying heat to said second stream of air before said second stream of air flows in thermal exchange with said second heat exchange unit, and means responsive to the requirements for heat in said enclosure for energizing said heating means.

2. Apparatus for either heating or cooling air .for an enclosure comprising in combination, a

charging said stream of air into said enclosure,

means for flowing a second stream of air in thermal exchange with said second heat exchange unit and for discharging said second stream of air to the outside atmosphere, heating means for supplying heat to said second stream of air before said second stream of air flows in thermal exchange with saidsecond heat exchange unit,

means responsive to the requirements for heat in said enclosure for energizing said heating means, said first and second heat exchange units forming a part of a volatile refrigerant system includinga compressor, means for reversing the flow of refrigerant through said first and second heat exchange units, and means for controlling" beaten" the flow of refrigerant between said change units.

3. In an air conditioning unit for an enclosure,

a condenser, an evaporator, means to transfer heat from said evaporator to said condenser, means for flowing air to be conditioned in thermal exchange with said condenser so as to heat said air, means for discharging the heated air into said enclosure, means for flowing air in thermal exchange with said evaporator, means for discharging said last named air into the outside atmosphere, means for heating said last named air before said air is used for heating said evaporator, and means responsive to the temperature of the air in said enclosure for controlling said last named means. a r

4. In an-air conditioning system of the reverse cycle type, a volatile refrigerant system having a heat absorbing element and a heat dissipating element, means for flowing a first stream of air in thermal exchange with said heat absorbing element, means for flowing a second stream of air in thermal exchange with said heat dissipating element, means for heating said first stream scope of the of air prior to its contact with said heat absorbing element, and means responsive to the temperature of the air leaving said heating means for controlling the operation of said heating means.

5. In combination, means forming a first air duct, means forming a second air duct, a refrigerating system having a condenser in said first air duct and an evaporator in said second air duct, means for circulating outside air in through said second air duct and over the evaporator, said second duct bein so constructed and arranged as to discharge the air flowing therethrough into the outside atmosphere, means for circulating air to be conditioned in over said condenser and out into the space to be conditioned, a first heating means in said second duct arranged to heat the air flowing in said second duct before contacting the evaporator, and a second heating means arranged in said first duct at a point beyond said condenser for heating air leaving said condenser.

6. In combination, means forming a first air duct, means forming a second air duct, a refrigerating system having a condenser in said first air duct and an evaporatorin said second air duct, means for circulating outside air in through said second air duct and over the evaporator, said second duct being so constructed and arranged as to discharge the airfiowing therethrough into the outside atmosphere, means for circulating air to be conditioned in over said condenser and out into the space to be conditioned, a first heating means in said second duct arranged to heat the air flowin in said second duct before contacting the evaporator, and a second heating means arranged in said first.duct at-ra point beyond said condenser for heating air leaving said condenser,

said refrigerating system including a compressor mounted in said second air duct so as to be cooled by the air flowing through said second air duct. 7. In combination, means forming a first air duct, means forming a second air duct, a refrigcrating system having a condenser in said first air duct and an evaporator in said second air duct, means for circulating outside air in through said second air duct and over the evaporator, said second duct being so constructedand arranged as to discharge the air flowing therethrough into the outside atmosphere, means for circulating air to be conditioned in over said condenser and out into the space to be conditioned, a first heating means in said second duct arranged to heat the air flowing in said second duct before contacting the evaporator, and a second heating means arranged in said first duct at a point beyond said condenser for heating air leaving said condenser, said refrigeratin system including a compressor mounted adjacent the inlet of said second air duct for partially heating the air flowing in thermal exchange with said evaporator.

8. In an air conditioning system of the re-.

verse cycle type, a volatile refrigerant system having a heat absorbing element and a heat dissipating element, means for flowing a first stream of air in thermal exchange with said heat absorbing element, means for flowing a second stream of air in thermal exchange with said heat and the other of said air streams into the outside atmosphere.

9. Apparatus for either heating or cooling air for an enclosure comprising in combination, a first heat exchange unit, a second heat exchange unit, means for transferring heat from one of said units to the other of said units, means for flowing a first stream of air in thermal exchange with said first heatexchange unit and for discharging said-stream of air into said enclosure, means for flowing a second stream of air in thermal exchange with said second heat exchange unit and for dischargin said second stream of air into the outside atmosphere, heating means for supplying heat to said second stream of air before said second stream of air flows in thermal exchange with said second heat exchange unit, and means responsive to the requirements for heat in said enclosure for energizing said heating means, said first and second heat exchange units comprising parts of a reverse cycle refrigerating system having means for causing either one of said units to operate as a condenser and the other to operate as an evaporator.

10. In an air conditioning system, a first heat exchange unit, a second heat exchange unit, a refrigerant compressor, refrigerant flow connections between said heat exchange units and said compressor, said heat exchange, units, compressor and refrigerant flow connections forming a heat transfer system, means for flowing a first stream of air in thermal exchange with said first heat exchange unit, means for flowing a second stream of outside air in thermal exchange with said second heat exchange unit, means for discharging said first stream into an enclosure to be conditioned, means for discharging said second stream into the outside atmosphere, means for supplying heat to said second air stream before. contacting said second heat exchange unit whereby said heat is transferred by said heat transfer system into said first air stream, and means responsive to the temperature within said enclosure for controlling said means'for supplying heat.

11. In an air conditioning system, a first heat exchange unit, a second heat exchange unit, a refrigerant compressor, refrigerant flow connections between said heat exchange units and said compressor, said heat exchange units, compressor and refrigerant flow connections forming a heat transfer system, means for flowing a first stream of air in thermal exchange with said first heat exchange unit, means for flowing a second stream of outside air in thermal exchange with said second heat exchange unit, means for discharging said first. stream into an enclosure to be conditioned, means for discharging said second stream into the outside atmosphere, means for supplying heat to said second air stream before contacting said second heat exchange unit whereby said heat is transferred by said heat transfer system into said first air stream, means responsive to the temperature within said enclosure for controlling said means for supp yi heat, and means for reversing the flow of refrigerant through said heat exchange units so as to change the system from a heating system to a cooling system.

12. In an air conditioning system, a first heat exchange unit, a second heat exchange unit, a refrigerant compressor, refrigerant flow connections between said heat exchange units and said compressor, said heat exchange units, compressor and refrigerant flow connections forming a heat transfer system, means. for flowing a first stream of air in thermal exchange with said first heat exchange unit, means for flowing a second stream of outsidev air in thermal exchange with said second heat exchange unit, means for discharging said first stream into an enclosure to be conditioned, means for discharging said second stream into the outside atmosphere, mean for supplying heat to said second air stream before contacting said second heat exchange unit whereby said heat is transferred by said heat transfer system into said first air stream, means responsive to the temperature within said enclosure for controlling said means for supplying heat, and means for reversing the flow of refrigerant through said heat exchange units so as to change the system from a heating system to a cooling system, said temperature responsive means including means for preventing the heat supplying means from heating said second stream of air when cooling is required in said enclosure.

13. In an air conditioning system, a first heat exchange unit, a second heat exchange unit, a refrigerant compressor, refrigerant fiow connections between said heat exchange units and said compressor, said heat exchange units, compressor and refrigerant fiow connections forming a heat transfer system, means for flowing a first stream of air in thermal exchange with said first heat exchange unit, means for flowing a second stream of outside air in thermal exchange with said second heat exchange unit, means for discharging said first stream into an enclosure to be conditioned, means for discharging said second stream into the outside atmosphere, means for supplying heat to said second air stream before contacting said second heat exchange unit whereby said heat is transferred by said heat transfer system into said first air stream, means responsive to the temperature within said enclosure for controlling said means for supplying heat, and means for discharging said first stream of air into the outside atmosphere and said second stream into said enclosure when cooling is required in said enclosure.

14. In combination with a volatile refrigerant system having a pair of complementary heat exchange coils, means for flowing a first stream of air in thermal exchange with one of said coils, means for flowing asecond stream of air in thermal exchange with the other of said coils, means for discharging one of said streams into a space to be conditioned, a heating unit for heating one of said streams of air prior to ,its

ing unit controlling said heating unit.

15. In combination with a volatile refrigerant system having a pair of complementary heat 'exchange coils, means for flowing a first stream of air in thermal exchange with one of said coils, means for flowing a second stream of air in thermal exchange with the other of said coils, means for discharging one of said streams into a space to be conditioned, a heating unit for heating one of said streams of air prior to its contact with one of said coils, a supply line for supplying a heating medium to said heating unit, a first valve in said supply line, a second valve in said supply line, means for by-passing said second valve, a third valve controlling the flow through said bypassing means, means responsive to the temperature within said space for controlling said first valve, means responsive to the temperature within said space for controlling said second valve, and means responsive to the temperature of the air leaving said heating unit controlling said heating unit, one of said temperature responsive means including means for controlling said refrigerant system.

16. In combination with a volatile refrigerant system having a pair of complementary heat exchange coils, means for flowing a first stream of air in thermal exchange with one of said coils, means for flowing a second stream of air in thermal exchange with the other of said coils, means for discharging one of said stream-s into a space to be conditioned, a heating unit for heating one of said streams of air prior to its contact with one of said coils, a supply line for supplying a heating medium to said heating unit, a first valve in said supply line, a second valve in said supply line, means for by-passing said second valve, a third valve controlling the flow through said bypassing means, means responsive to the temperature within said space for controlling said first valve, means responsive to the temperature within said space for controlling said second valve, means responsive to the temperature of the air leaving said heating unit controlling said heating unit, and change-over means for causing either one of said heat exchange coils to reject heat picked up by the other of said heat exchange coils.

1'7. In combination with a volatile refrigerant system having a pair of complementary heat exchange coils, means for flowing a first stream or air in thermal exchange with one of said coils, means for fiowing a second stream of air in thermal exchange with the other of said coils, means for discharging one of said streams into a space to be conditioned, a heating unit for heating one of said streams'of air prior to its contact with one of said coils, a supply line for supplying a heating medium to said heating unit, a first valve in said supply line, a second valve in said supply line, means for by-passing said second valve, a third valve controlling the flow through said bypassing means, means responsive to the temperature within said space for controlling said first valve, means responsive to the temperature within saidspace for controlling said second valve, means responsive-to the temperature of the air leaving said heating unit controlling said heating unit, and change-over means for causing either one of said air streams to be discharged into said space.

18. In an air conditioning system for an enclosure, 9, first heat transfer unit and means for transferring heat between said heat transfer unit and said enclosure, a second heat transfer unit, a heating unit, means for flowing air first into heat exchange relationship with said heating unit and then in heat exchange relation with said second heat transfer unit and then discharging the air outside said enclosure, means for evaporating a volatile liquid in said second heat transfer unit and condensing the evaporated volatile liquid in said first heat transfer unit and returning the condensed volatile liquid to the second heat transfer unit for're-evaporati'on, and means for ren-' dering eflective said heating unit to heat the flowoutside atmosphere, means for circulating air to be conditioned over said condenser and out into the space to be conditioned, and heating means in said second duct arranged to heat the air flowing in said second duct before contacting the evaporator, said refrigerating system including a compressor mounted in said second air duct in advance of the evaporator so as to heat the air before contacting the evaporator.

CHARLES D. GRAH REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,942,295 Kerr et a1 Jan. 2, 1934 2,143,687 Crago Jan; 10, 1939 2,195,781 Newton Apr. 2, 1940 2,313,390 Newton Mar. 9, 1943

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