DD282744A5 - ARRANGEMENT FOR CELL PROTECTION IN COLD STORAGE ROOMS WITH VERY DIFFERENT WEATHER LOADS AND TEMPERATURE DIFFERENCES BETWEEN EXTERNAL AND STORAGE AIR TEMPERATURE - Google Patents

Abstract

With an arrangement for providing cold storage in cold storage rooms with very different heat loads and temperature differences between Auszen- and storage room air temperature, the energetically economical provision of the need adapted Kaelteleistung when using conventional chlorofluorocarbon refrigerant is to be made possible. According to the invention, this object is achieved in that two mechanical refrigerant compressors, a condenser, an evaporator and an evaporator condenser are arranged and connected to each other by drilling lines, which can be switched by means of switchable valves at large temperature differences between Auszen and Lagerraumlufttemperatur, z. B. in frozen food storage, operating the system according to the cascade principle or at lower temperature differences than single stage Kaltdampfkabeltemaschine with optional use of one of the two compressors depending on the temperature difference between Auszen- and storage room air temperature and heat load is possible {Kaeltemittel; mechanical refrigerant compressors; Waermelast; Gefriergutlagerung; Cascade principle; Temperature differences; Chlorofluorocarbons hydrogen; Kaltdampfkaeltemaschine}

Description

Z. 'indungsgemäß this object is achieved in that two mechanical refrigerant compressor, a condenser, a V. Steamer and an evaporator condenser are arranged and connected to each other by pipes that with the help of switchable valves at high temperature differences between outdoor and storage room air temperature, eg. As in frozen food storage, operating the system according to the cascade principle or at lower temperature differences than single-stage cold steam refrigerator with optional use of one of the two compressors depending on temperature difference between outdoor and storage room temperature and heat load is possible.

Due to the different operating variants, different gradations of the cooling capacity are possible in accordance with the heat loads, with the compressors used always operating in an energetically favorable temperature and pressure range.

According to the heat loads occurring in various applications, different compressor assemblies can be used and the partial circuits can be operated with different refrigerants.

The latter allows in the case of the use of alternative refrigerants with proper tuning of the compressor types and the refrigerant pairings compensation of the energy disadvantages of the alternative refrigerant compared to conventional Kaltdampfkältemaschinenschaltungen with mechanical compressors.

A reduction in mass, which has a positive effect particularly in mobile systems, can be achieved by the common placement of the refrigerant compressors (1) and (2) in one housing. It is also beneficial if they are driven by a drive motor via switchable clutches.

embodiments

The invention will be explained in more detail below on two exemplary embodiments according to FIGS. 1 and 2.

In the drawings, Fig. 1 di. - "Order when operating the system with a refrigerant u.id Fig. 2 shows the arrangement when operating the system with two different lien ¬ ling refrigerants.

In the arrangement shown in Fig. 1 s nd the refrigerant compressor 1 and 2, t'er evaporator 3, the evaporator condenser 4, the condenser 5 and the expansion valve s valves 6 and 7 arranged as a compression refrigerating machine in cascade, wherein in both subcircuits I and II the same Refrigerant is used.

At low storage room air temperature in less -15 ⁰ C and high outside air temperatures greater than 30 ⁰ C, the refrigerant lines remain 8,9 and 10 blocked by the switchable three-way valves 11,12 and 13, so that the system operates on the principle of cascade and under the run temperature conditions a higher total cooling capacity is achieved compared to a single-stage chiller.

At low temperature differences between outside and storage room air temperature, the energy advantages of a cascade refrigeration machine over a single-stage system are no longer given. Under these conditions, the system can therefore be operated in one stage. By operating the switchable three-way valves 12 and 13, the refrigerant via the refrigerant line 9, the condenser 5, the Kältemitteueitung 10, the expansion valve 7, the evaporator 3 and the compressor 1 is performed. The refrigerant compressor 2 remains switched off in this mode, the evaporator condenser 4 and the expansion valve 6 are bypassed, so that the entire system operates in one stage using the refrigerant compressor 1.

By operating the switchable three-way valves 11 and 13, the system can be operated via the refrigerant lines 8 and 10AIs single-stage system using the refrigerant compressor 2. The refrigerant circuit is in this case performed over the compressed, the condenser 5, the refrigerant line 10, the expansion valve 7, the evaporator 3 and the refrigerant line 8. The refrigerant compressor 1 remains switched off in this mode, the evaporator condenser 4 and the expansion valve 6 are bridged.

The single-stage operation of the system with optional use of one of the two refrigerant compressors 1 or 2 ensures due to the different selectable compressor sizes a heat load corresponding adjustment of the cooling capacity in several stages.

FIG. 2 shows the arrangement when using two different refrigerants in the individual partial circuits I and II of the system.

Here, the condenser 15 and the evaporator 14 are provided with a separate wiring, which prevent mixing of the refrigerant used. Furthermore, the refrigerant pipes 8,9,10 and 16 and an additional expansion valve 17 and a check valve 18 are installed.

If the system is operated as a cascade system at the corresponding temperature differences between the outside air and the room air temperature, the refrigerant lines 8, 9 and 16 remain closed by the switchable three-way valves 12 and 13. The pressurized refrigerant line 10 is blocked by the check valve 18. The cascade connection is formed by the plant components refrigerant compressors 1 and 2, Ve (damper 14, condenser 15, evaporator condenser 4 and the expansion valves 6 and 7. If the temperature and heat load conditions require the single-stage operation of the system, this is in turn achieved by the partial use of Compressor 1 or 2. In the first case, the pumping lines 9 and 10 are opened by actuation of the switchable three-way valve 12. With the refrigerant of the partial circuit I, starting from the compressor 1 via the three-way valve 12, the refrigerant line 9, the condenser 15, the Refrigerant line 10, the check valve 18, the expansion valve 7 and the evaporator 14 allows a single-stage operation.

The compressor 2 is out of operation.

In the single-stage operation of the system with the refrigerant of the partial circuit Il, the switchable three-way valve 13 is operated, so that the refrigerant circuit via the compressor 2, the condenser 15, the three-way valve 13, the refrigerant line 16, the expansion valve 17, the evaporator 14 and the refrigerant line 8 goführt. The compressor 1 does not work in this mode.

In contrast to the arrangement shown in FIG. 1, in the arrangement presented in FIG. 2 it is possible to use both compressors simultaneously in single-stage operation, which represents a further possibility for adapting the cooling capacity to the heat load.

Claims (3)

1. Arrangement for providing cold in cold storage rooms with very different heat loads and temperature differences between outdoor and storage room temperature, characterized in that two single-stage compression refrigeration with mechanical compressor via an evaporator condenser (4) energetically and by means of valves and disconnectable refrigerant lines (8), ( 9) and (10) for bypassing the compressor (1) or (2), the evaporator condenser (4) and the expansion valve (6) are materially coupled. 2. Arrangement according to claim 1, characterized in that in the sub-circuits (I) and (II) circulate different refrigerants, the evaporator (14) and the condenser (15) provided with a respective separate wiring and in the refrigerant line (16) an expansion valve (17) between the condenser (15) and the evaporator (14) and in the refrigerant line (10) a Venti '(18) are arranged. 3. Arrangement according to claim 1 and 2, characterized in that the refrigerant compressors (1) and (2) housed in a common housing and coupled by means of switchable couplings with a common drive motor. For this 2 pages drawings Field of application of the invention The invention relates to an arrangement for refrigeration provision in cold storage rooms with very different heat loads and temperature differences between Außsn- and storage room air temperature, as they are for. B. occur in transport storage rooms, cold storage, refrigerated containers and small refrigerated houses. Characteristic of the known state of the art It is known that according to the state of the art for cold provision in cold storage rooms Kaltdampfkältemaschinen be used with mechanical compressors. In these rooms occur due to the possible outside air temperatures and different storage goods (refrigerated and frozen) very different heat loads, which must be compensated by a correspondingly adapted cooling capacity of the chiller at often very different temperature differences between outdoor and storage room temperature - see: Drees, H. : Kühlanlagen.-Berlin: VEB Verlag Technik, 1987-. Due to the physical principles of cold steam chillers with mechanical compressors, they work energetically favorably only in a narrowly limited range of the temperature difference between outside and storage room air temperature. Jungnickel, H .: Basic Refrigeration / Aging, R .; Kraus, E.-Berlin: VEB Verlag Technik, 1985-. To condense the very different heat loads, the Be'reibon of the chiller is also often necessary outside of this energetically favorable application. The adjustment of the cooling capacity to the very different heat loads can be done by a power control on the compressor, but worsen the energy indicators of the chiller, especially in the partial load range. Another possibility of cooling capacity adjustment is a parallel arrangement of two refrigeration machines with mechanical compressors, as described by Schroth, H. H .: compact refrigeration set for the universal use of storage space and transport cooling. - In: air and refrigeration technology. - Berlin 24 (1988) 1, pp. 20-22 is presented, but which is associated with a large Vlaterialeinsatz. In the replacement of conventional chlorofluorocarbon refrigerants (CFCs), which is necessary for reasons of environmental protection, according to Morgenstern, J .: studies on the optimization of vehicle refrigeration rates with regard to energy and material economics as well as environmental compatibility. - College of Transportation Dresden, - Diploma thesis, 1989 - to be expected with a general deterioration of the energy indicators of the term used as alternative refrigerant hydrofluorocarbon (HFC), which has a negative impact on the energy efficiency of the chiller in conventional process control. Object of the invention The aim of the invention is to provide an arrangement for Kältebei delivery in cold storage rooms with very different heat loads and temperature differences between outdoor and storage room temperature ermf.gh ermf.gh the energetically economical provision of the required cooling capacity in the use of conventional Fluorohalohydrocarbons and novel, environmentally friendly fluorocarbon refrigerants 'CIIT. Explanation of the essence of the invention Object of the invention is to develop an arrangement for Kälteberei'.stellung in cold storage rooms with very different heat loads and temperature differences between outside · and storage room air temperature, the energetically economical provision of adapted to the needs cooling capacity with the use of conventional chlorofluorocarbons hydrocarbon refrigerants and new, more environmentally friendly hydrofluorocarbon refrigerants allows.