CS266073B1 - Cooling device - Google Patents

Abstract

The solution concerns compressor cooling circuits, working with a change in the state of the circulating medium and, in contrast to the devices used so far, it allows the use of natural cold in the vicinity of the condenser. The cooling compressor circuit consists of an evaporator, a steam pipe, a closing element, a compressor, an oil separator, a closing element, a condenser, a collector, a discharge pipe, a closing element, a vapor-liquid exchanger, a dehydrator and an expansion element, after which the discharge pipe opens into a scrubber. The closing elements are controlled by a thermostat, operating depending on the temperature around the condenser, when the temperature drops, the thermostat gives a signal to close the closing elements of the compressor circuit and open the closing elements of the natural circuit. This opens a natural gravity circuit consisting only of the evaporator, condenser, steam pipe and discharge pipe, with the heat transfer medium vapor flowing through the branch pipe on the steam pipe and the liquefied heat transfer medium flowing through the branch pipe on the discharge pipe.

Description

The invention relates to a refrigeration device with a refrigeration compressor circuit, which can be switched to natural circulation with the use of natural cold when the outdoor temperature drops. It can be used especially in large warehouses of fruits and vegetables, in air conditioners, in cooling liquids, etc.

Previously used ctil.ι <11 <· (The devices use high cooling eyes even under conditions where the outdoor temperature is lower than in a refrigerated environment and their construction does not allow the use of natural cold.

These shortcomings are eliminated by the device according to the invention, which consists of an evaporator located below the steam line condenser, a compressor in front of which a shut-off element is inserted, a liquefied medium discharge line and an expansion element behind which the liquefied medium discharge line is fed to the evaporator the pipe is provided in front of the shut-off element with a branch pipe in which another shut-off element is inserted, the branch pipe being connected to the condenser inlet, usually again connected to the steam pipe, before it opens into the condenser. the liquefied medium discharge pipe is provided with a branch pipe provided with a closing element and connected to the inlet to the evaporator. This makes it possible to use a gravity cooling circuit when closing the shut-off element in front of the compressor and to use a compressor cooling circuit when closing the shut-off element in the branch pipe. The choice of one of these cooling circuits is simultaneously made possible by opening or closing one of the closure elements inserted in the heat transfer medium condensate drain line, extending further into the vapor-liquid exchanger and to the element expander, or located in the branch line from the heat exchange medium condensate drain line. The closing elements are generally provided with an electrical control connected to a thermostat which responds to the temperature around the condenser. When the ambient temperature of the condenser is higher than the required condensing temperature, the thermostat closes the shut-off elements on the natural cooling circuit, so the refrigeration compressor circuit is active, and vice versa of the compressor refrigeration circuit and the natural gravity circuit is in operation, consisting only of the evaporator, the condenser and the connecting pipes.

The advantages of the device according to the invention lie in the possibility of using natural cold by shutting down the compressor refrigeration circuit when the ambient temperature of the condenser decreases. This saves the energy required to drive the compressor and reduces wear on active compressor components. By placing the condenser in a higher position, a reduction in condensing pressure is achieved at the same time, which is as great as the weight of the liquid refrigerant column that had to be transported to the evaporator above. This also reduces the energy requirements for compressor performance.

One of the possible embodiments of the device according to the invention is shown in the accompanying drawing.

From the evaporator 2 a steam line 2 is led vertically, provided with a shut-off element 3, located before connecting the steam line 2 to the compressor 4, from the discharge of which the steam line 2 continues to the oil separator 5, from which it continues through the shut-off element 6 and opens into the condenser. 2 / which is air-cooled and is located outside the refrigerated environment at a higher level than the evaporator ^{from the} condenser 2 · d 2 ^e downwardly led out of piping 9 discharge the condensed heat transfer medium. The discharge line 9 is provided with a collector 8, a closing element 22, a vapor-liquid exchanger 11, a filter dehydrator 12 and an expansion element 22 ' ^behind which the discharge line 2 opens into the evaporator 2. This closes the compressor refrigeration circuit. The natural gravity cooling circuit is enabled on the one hand by a branch pipe 16 provided with a shut-off element 14, which is led out of the steam line 2 in front of the shut-off element 2 and adjoins the steam line 2 again behind the shut-off element 6 in the flow direction of the heat transfer medium. In addition, the natural gravity cooling circuit is enabled by a branch pipe 17 from the discharge pipe 2 of the liquefied heat transfer medium. The branch line 22 is provided with a closing element 15 and connects to the discharge line 2 of the liquefied heat transfer medium before it enters the evaporator 2. The function of the device is as follows: When using the compressor circuit the shut-off element 2 to the compressor 4 and after compression are conveyed via an oil separator 5 and an open shut-off element 6 to a condenser 7, in which they condense and flow into a collector 8 ^from which they flow down a pipe 9 via an open shut-off element 10, vapor-liquid exchanger 11 , filter dehydrator 12 I I'.num I <1 oinelil II Z | .M dc burner I. Exchanger. II ρΛ ι π k .η and II na | e <h>i><lv / uléc t pot pot i libí 9 included in order to liquefy the remainder of the vapors which were not condensed in the condenser 7 and to increase the volume refrigeration. In the case of a compressor refrigeration circuit, the closing elements 14, 15 are closed and, conversely, the closing elements 3, 6, 10 are open. When the ambient temperature of the condenser reaches below the desired value, the thermostat 18 gives a signal to open the closing elements 14, 15 and vice versa to close the closing elements 2, 6, 10. This closes the compressor circuit and opens the natural gravitational circuit (circuit) that the evaporated heat exchange medium exits through the steam line 2 ^{from the} evaporator 2 via the open shut-off element 14 to the condenser 7, where the heat transfer medium condenses and proceeds through the collector 8 to the discharge line 2 and further through the open shut-off element 15 and the discharge line 17 to the evaporator 2. elements 2, 10, .21, 15 are generally used electromagnetic

Claims (5)

OBJECT OF THE INVENTION A refrigeration device comprising a refrigeration circuit consisting in particular of an evaporator, a steam line, a compressor, in front of which a shut-off element, a condenser, a liquefied medium discharge line and an expansion element are inserted, followed by a liquefied medium discharge line. located at a higher level than the evaporator, characterized in that the steam pipe (2) is provided in front of the shut-off element (3) with a branch pipe (16) in which another shut-off element (14) is inserted, the branch pipe (16) being connected to the inlet to the condenser (7), from which the discharge line (9) of the liquefied heat exchange medium opens, with the inlet to the evaporator (1). Cooling device according to claim 1, characterized in that the discharge line (9) of the liquefied heat transfer medium is provided with a branch pipe (17) provided with a closing element (15), the branch pipe (17) being connected to the inlet to the evaporator (1). ). 3. Cooling device according to claim 1, characterized in that the branch line (16) from the steam line (2) is reconnected to the steam line (2) and these lines (16, 2) thus have a common supply to the condenser (7). , wherein a closing element (6) is inserted in the flow direction of the vapors of the heat exchange medium before connecting the branch pipe (16) to the steam pipe (2). 4. Cooling device according to claim 2, characterized in that the discharge line (9) of the liquefied heat transfer medium is provided with a closing element (10) downstream of the branch line (17). 5. Cooling device according to items 1 to 4, characterized in that the closing elements (3, 14, 6, 15, 10) are provided with an electrical control connected to a thermostat (18) which reacts to the temperature around the condenser (7).