DE1930050A1 - Method and device for defrosting evaporators - Google Patents

Description

Dr. ^

Emhart Corporation

950 Cottage Grove Road Munich, June 4, 1969

Bloomfield, Connecticut, USA (Attorney File M-755)

Method and device for defrosting evaporators

It is often desirable to cool air going through or around
a refrigerator compartment using two or more evaporators. It is also important in many cases to keep the cooling space and the cooled air at a substantially uniform temperature 1. At the same time it is necessary to de-ice the evaporators from time to time, ie the snakes and ribs of the verj

to remove frost and ice and thereby a continuous | to ensure borrowed mode of operation with good efficiency.

Up to now the evaporators have usually been de-iced in such a way that ' that electrical heating elements have been used or that warm cooling!

gas fed directly to the evaporator by a compressor j became. In such systems, components often have to be used which are relatively expensive to install and operate. Aside from that' the de-icer used usually to the

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To increase the temperature of the evaporator and / or the air in contact with the evaporator far above the value that is required is to melt the frost and ice from the coils and ribs of the evaporator. It is then necessary dissipate this heat by additional expenditure on cooling.

In known systems, the liquid refrigerant that is fed to the evaporators working in the cooling cycle comes from a conventional condenser and collector, or it is condensate that is wholly or partially received by the evaporator that is currently being defrosted by the warm refrigerant gas flowing through it . In such an installation the temperature of the liquid refrigerant ,, which is supplied to the cooling evaporator is generally close to 25 ⁰ C to 2_6 ° C or higher. This has the consequence that at least part of the latent heat which is absorbed during the evaporation of the refrigerant is obtained from a temperature decrease of the liquid refrigerant entering the evaporator through the expansion valve.

The invention is intended to provide a method and a device which avoid this loss of cooling capacity. The inventive method is characterized in that to a liquid refrigerant of more than 0 ⁰ C ohne.expandieren, through-a .in an. Entelsungs cycle working first evaporator led w.ir, d ^ _% to. “To increase the tempera uir of the serpents and ribs of the first evaporator that cooled in this way

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Refrigerant to a second evaporator operating in a cooling cycle is supplied and evaporated, and then the direction in which the refrigerant flows through the two evaporators is reversed to defrost the second evaporator and let the first evaporator operate in the refrigeration cycle.

According to the invention, the liquid refrigerant that is supplied to an evaporator operating in a cooling cycle is first passed through another evaporator operating in a defrosting cycle. In this way, heat is removed from the liquid refrigerant by melting the frost and ice on the coils and ribs of the evaporator to be defrosted and at the same time the temperature of the liquid refrigerant is reduced so that it enters the evaporator operating in the cooling cycle at a reduced temperature ; this increases the heat absorption capacity and the thermal efficiency of the cooling cycle. Since the evaporator that is defrosted supports the effect of the condenser used in the system, the condenser can also be downsized. The improved efficiency of the refrigeration cycle ¹ provides' in the same manner the possibility of the (desired cooling effect. With a smaller amount of liquid refrigerant to achieve, so that the compressor can be reduced. At the same time none of the evaporator used needs during defrosting to unnecessarily high Temperatures of being heated, and the risk of the temperature of the air that

8AO ORtGiHAL

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the evaporator flows around and is fed to the refrigerator, disadvantageously increasing, is switched off. '

Based on the drawings, a preferred embodiment; the invention explained in more detail. Show it:

Fig. 1

a schematic view of a cold room,

Pig. 2 is a circuit diagram of a cooling system for cooling the Cold room in the Pig. I.

In Fig. 1, a cooling space with an insulated housing 2 is shown.

placed, in the front wall of which an access opening 4 is provided

i see is. The space 6 inside the housing is filled with air. cools, which by means of a fan 12 alternately via a | damper 8 and an evaporator 10 is performed. The air flows! via that evaporator (in the figure via the evaporator 8), j. which works in the cooling cycle, and then arrives at an outlet opening opening 14, where it forms an air curtain 16. The air can also be expelled directly into the space 6 to be cooled. the Air is then drawn into a return port Ϊ8 at the bottom of the Housing sucked and through a return line 20 to the fan 12 supplied.

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The evaporators 8 and 10 are surrounded by an insulating wall 2β von- j separated from one another so that they are arranged in chambers 22, 24 lying next to one another. The upper chamber 22, in which the Evaporator 8 is located, movable throttle or closing members 28 are assigned, while the lower chamber 24, in which the Verj damper 10 is similar throttle or closing elements 50 trains-j

are arranged. As shown in the figure, the vaporizer works: 8 in a cooling cycle while the lower evaporator 10 is operating in a defrost cycle. At that time, those of Chamber are 22 associated closing members 28 open so that air coming from the fan 12 over the coils and ribs of the evaporator 8 and can flow through the collection chamber 52 to the outlet port l4.Glelc the closing elements 30 assigned to the chamber 24 are closed at the same time, to prevent air from flowing over the evaporator 10 while the evaporator 10 is being defrosted. This ensures that the relatively warm or not cooled Air next to the evaporator 10 does not mix with the air flowing through the chamber 22 and around the evaporator 8 and thereby the temperature of the air supplied to the cold room increases.

The system can be operated in this way until the evaporator 8 is covered with ice and frost. When the evaporator 8 is then to be defrosted, the closing elements 28 are closed and the closing members 30 open, the evaporator 10 works then in cooling mode, while the evaporator 8 is being defrosted. In this

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In this way, a continuous flow of cooled air can be ensured to the outlet opening 14 in front of the access opening 4 to generate an air curtain 16 and to allow cooled air to circulate in the cooling space 6. -

The cold room shown in Fig. 1 is preferably equipped with a cooling system as described in Pig. 2 is shown schematically operated. The refrigeration system includes a compressor j54, a condenser j56j, a collector 38 and a dryer 40. Since the evaporator 8 operates in a cooling cycle, the refrigerant compressed by the compressor ~ $ K flows to the condenser j? 6 and collector 38 and then arrives at the dryer 40 , from where the liquid refrigerant flows through a line 42 to a two-way valve 44. As indicated by the arrows in FIG. 2, the valve 44 is initially set such that the liquid refrigerant flows through the line 46 to the coils of the evaporator 10. The temperature of this liquid refrigerant is then above ⁰ ° C. or approximately at room temperature, for example between 20 ° C. and 26 ° C. At the same time, the temperature of the coils and ribs of the evaporator 10, which are covered with frost or ice, is not above 0 Cj; it can be, for example, -32 ⁰ C or below. The liquid refrigerant entering from the line 46 into the evaporator 10 is thus cooled by the coils and ribs of the evaporator 10, the temperature of these coils and ribs being sufficiently increased - by the ice on them - and frost coating to -scKmeiZ ^ efi, -s ^r öaaQ the evaporator LO is defrosted. The GE-

-cooled liquid refrigerant exiting the evaporator 10, then has a temperature of about minus 1 ° C to +5 ⁰ C and i flows through a Äaslaßleitung 48 and a bypass line 50 52. a Verteilervenfcil In this way, the cooled liquid refrigerant the expansion valve 5 ^ belonging to the evaporator 8

fed. The cooled liquid refrigerant is in the evaporator

8 evaporates, and since its temperature had previously been reduced in the evaporator 10, the temperature of the liquid refrigerant entering the expansion valve 54 is substantially reduced and is approximately between minus 1 C and + 5-C. The heat absorption capacity of the refrigerant is increased, so that by its expansion in the coils of the evaporator 8, the temperature of the coils and fins of this evaporator 8 is reduced to a value ί which is considerably lower than the temperature that the coils and fins would assume if the liquid refrigerant supplied to the expansion valve 54 had had room temperature, for example approximately 2> C to 26 ° C., in the usual manner. Accordingly, there will be a smaller amount of expanding; Refrigerant is required to maintain a desired low temperature and the amount of evaporated refrigerant flowing back to the compressor is reduced. A compressor with smaller dimensions and lower capacity can therefore be used _:

be turned.

• The evaporated refrigerant gas emerging from the evaporator 8 flows through the line 56, the valve 62 and the return line 64 into the compressor> 4, in order to be compressed again and

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to be chilled in the condenser ~ $ 6. The, plant can in this
Way operated until the snakes and ribs
Evaporator 10 are defrosted and no longer exert a noticeable cooling effect on the liquid refrigerant supplied to evaporator 8. The mode of operation is then reversed and the evaporator 8 then operates in a defrosting cycle while the evaporator 10 is switched to cooling. This reversal takes place by switching the two-way valves 44, 62 and the distribution valve 52; the liquid refrigerant then flows from the collector 38 and dryer I 40 through the line 42 and the two-way valve 44 into the line
56, which serves to bring the uncooled refrigerant to the snakes
and to supply fins of the evaporator 8. The j by the snakes gene of the evaporator 8 flowing liquid refrigerant is then used \ to deice these snakes and ribs and thereby!

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the temperature of the liquid degenerating from the evaporator 8

Refrigerant reduced accordingly. The liquid refrigerant cooled in this way flows through the line 66, which the
Expansion valve 5Λ bypasses. The liquid refrigerant flows through; the distribution valve 52, which is now adjusted so that the liquid refrigerant through the line 56 and the expansion valve
58 flows into the coils of the evaporator 10. The cooled liquid refrigerant then expands in the coils of evaporator 10 and flows back through line 46 and valve 62 into line 64 and compressor J54. Accordingly, the
Evaporator 8 defrosts while evaporator 10 is being cooled,

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In addition, in such a reverse mode of operation of the system, the closing element 28 of the evaporator 8 is closed and the closing element J) O of the evaporator 10 is open, so that the air conveyed by the fan 12 through the lower space 24 and via the Schlan-j gene and ribs of the cooling evaporator 10 to the outlet opening 14 flows. Since the closing element 28, which is assigned to the space 22 and the evaporator 8, is closed during this time, no air can flow through the evaporator 8 and mix with the air flowing over the evaporator 10 and through the space 24. The defrosting of the evaporator 8 therefore does not result in the temperature of the air flowing through the outlet opening 14 and through the cooling space 6 being increased or changed.

The switching of the closing elements 28, J> 0 and the valves 44, 52 and 62 can be controlled by a device which is set to '

the temperature of the liquid refrigerant used in the de-icing j queues working in operation and flows to the serpentine working in cooling mode, responds. For this purpose are Thermon

State 70, 22 in contact with bypass lines 50, 66 or; placed in any other suitable place to solenoids! 74, 76 or the like, which are used to control the valves 44, 52 and

62 are provided to operate. Furthermore, the shepherd's organs 28j 30, which ^ control the flow through chambers 22, 24 electrical.means such as the solenoids 74, 76 are operated, at the same time as the switching of the valves 44, 52 and 62, by which the operation is reversed. If desired, Solenoids can of course also be used in a common electric

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Circuit are arranged so that they are operated simultaneously , and the correct, desired mode of operation of the plant controlling valves and throttling devices is ensured.

The cooling method according to the invention could of course also with Another type of cold room or refrigeration system can be used. A larger number of vaporizers could also be combined can be used with each other, and the invention could also be used to cool several at different locations arranged cooling devices to control.

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Claims (1)

PatentonwSH © Dr. Ing. H. Neg? -. C3-nV Dipl.! Πν ·. K. H ~ -: k Dipl. P; .y- V ^; . Sd.'uifz 8 Munich -. S, i ^ oearf str. 23 Tel. 538OS86 Emhart Corporation Cottage Grove Road Munich, June 4th, 1969 Bloomfield, Connecticut, USA (Attorney File M-7J55) Claims 1. j method for defrosting the coils and ribs of evaporators working alternately and one after the other in cooling mode and defrosting mode, characterized in that a liquid refrigerant which has a temperature above 0 ⁰ C is passed through a first evaporator working in a defrosting cycle and without expansion thereby, with simultaneous cooling of the liquid refrigerant, the temperature of the coils and ribs of the first evaporator is increased sufficiently to thaw frost and ice deposits that the refrigerant cooled in this way is fed to a second evaporator operating in a cooling cycle and evaporated therein, and that then the direction in which the refrigerant flows through the two evaporators is reversed in order to defrost the second evaporator and let the first evaporator work in the cooling cycle. 2. The method according to claim 1, characterized in that the Direction in which the refrigerant flows through the two evaporators, depending on a rise in temperature of the liquid, 90985t / 1362 sigen refrigerant leaving the evaporator being defrosted is reversed. ^. A method according to claim 1 or 2, wherein the air of the two Evaporator is cooled and fed to a cold room, characterized in that during the defrosting of the first evaporator Air is passed over the second evaporator and fed into the cold room until the temperature of the liquid refrigerant, that flows through the second evaporator, that thereafter increases the direction in which the refrigerant passes through the two evaporators flows, is reversed, and that at the same time the air flow from the second evaporator to the refrigerator compartment is interrupted and Air is supplied to the cold room via the first evaporator. 4. Device for performing the method according to one of the preceding Claims, characterized by a device (42,44,56), the liquid refrigerant of more than 0 ° e dem first evaporator (8) supplies a device (48,52,56,58) without the refrigerant evaporating in the first evaporator which supplies the liquid refrigerant exiting from the first evaporator (8) to the second evaporator (10) in order to in the second Evaporator to be evaporated, and a device (44, 52,62) showing the direction in which the refrigerant the two Evaporator flows through, reversed. yU9öb1 / 136 2 5 · Device according to claim 4, characterized by one of the temperature of the liquid refrigerant-dependent control device (70, 72), which reverses the direction of the refrigerant controls. 6. Apparatus according to claim 4 or 5- for performing the method according to claim 3, characterized by a device (44,62,52,70,72,74,76) indicating the direction of flow of the refrigerant periodically reversing through the two evaporators, and a device (12,28,50,32M), the air over the in the cooling cycle working evaporator (8jlO) passes and the refrigerator (6) feeds. 7. Apparatus according to claim 6, characterized in that the two evaporators (8,10) are arranged in separate chambers (22,24) are that each chamber is assigned at least one closing element (28, 30), and that a device is provided, which opens the closing member of the chamber in which the evaporator operating in the cooling cycle is arranged, so that cooled Air can flow through the cooled chamber to the cooling space, and at the same time the closing member of that chamber closes in which the evaporator operating in the defrosting cycle is arranged. T / T362 ^ ' 8. Apparatus according to claim 7> characterized in that .the «reversal of direction of the refrigerant flow through the two evaporators and the opening and closing of the closing elements is controlled by a control device (70,72,7 ^ 76) which is on
is responsive to a rise in temperature of the liquid refrigerant. 909851/136 2 Blank page