RU180821U1 - REFRIGERATING UNIT FOR PROVISIONAL STORAGE - Google Patents

Abstract

The utility model is intended for ship refrigeration systems. The objective and technical result of the utility model is to increase the efficiency of the refrigeration unit for provision storerooms at two temperature levels - minus (18 ± 2) ° С and (3 ± 2) ° С. For this, the installation is equipped with a gas-jet an ejector, the input of the high-pressure medium of which is connected to the output of the high-temperature evaporator, the input of the low-pressure medium of the ejector is connected to the output of the low-temperature evaporator, and the outlet diffuser is connected to the suction line ressora.Takzhe installation provided with an additional duct mounted with a normally closed electromagnetic valve connecting the low pressure inlet of the ejector with the medium diverter cone. 2 s.p. f-ly, 1 il.

Description

The utility model relates to refrigeration, mainly to ship refrigerant refrigeration units of provision storerooms at two temperature levels - minus (18 ± 2) ° С and (3 ± 2) ° С (one of the temperature standards adopted in ship refrigeration systems).

Known refrigeration unit [Patent No. 5555736. USA, Refrigeration system and method, IPC F25B 049/02, York International Corporation; Wills F.E., Norbeck D.K. Claim 06/05/1995, publ. September 17, 1996], containing a freezer and a refrigerator.

The main disadvantage of this analogue is the cooling of the refrigeration chamber due to the operation of the freezer, which increases energy consumption and reduces the efficiency of the cycle.

According to the analysis of scientific and technical literature [Zakharov Yu.V. Marine refrigeration units. - Moscow, Transport, 1967, 272 p., P. 129-130; Patent No. 9453668, USA, Refrigeration cycle apparatus and refrigerant circulating method. IPC F25B 1/00, F25B 41/04, F25B 41/00, F25B 1/06, F25B 19/02, Mitsubishi Electric Corporation; Higashiiue Shinya, Nomoto So. Claim 01/26/2011, publ. 09/27/2016; Pat. Application No. 2008-139019, Japan, Ejectorcycle / Ejectorcycle, IPC F25B 1/00, F25B 5/02, F25B 5/04, Denso Corp .; Watanabe Hiroshi et al. 01/21/2008, publ. 06/19/2008. Passed into patent No. 4577365 on 09/03/2010; A.S. No. 879193, USSR, Refrigeration unit, MPK F25B 1/00, F25B 5/00, Omsk Synthetic Rubber Plant. Nesvitsky A.A. Claim 02/05/1979, publ. 11/07/1981] the closest to the claimed utility model in terms of technical nature and the technical result achieved is a refrigeration unit, the description of which is given in the monograph [Zakharov Yu.V. Marine refrigeration units. - Moscow, Transport, 1967, 272 p., P. 129-130], containing a compressor, a refrigerant condenser, two evaporators with solenoid (electromagnetic) and thermostatic valves in front of them, and a refrigerant pressure regulator. In this installation, the refrigerant boiling pressure in a high-temperature evaporator is maintained by the self-regulating refrigerant pressure regulator.

This refrigeration unit is selected as a prototype. The disadvantages of the prototype include throttling on the suction line of the compressor from the pressure of the high temperature evaporator to the refrigerant pressure in the low temperature evaporator, which occurs in the pressure regulator, which reduces the efficiency of the cycle.

The objective of the utility model is to create the design of a refrigeration unit for provision pantries at two temperature levels with increased cycle efficiency.

This task is carried out by the fact that in a known refrigeration system comprising a compressor, a refrigerant condenser, first and second evaporators, electromagnetic valves and thermostatic valves installed in front of the evaporators and a self-regulating refrigerant pressure regulator installed after the first evaporator, a gas jet is installed in parallel with the pressure regulator an ejector, the input of a high-pressure medium of which is connected to the output of the first evaporator, the outlet diffuser of the ejector is connected to the compressor suction line, the input is not the pressure head of the ejector is connected to the outlet of the second evaporator, the installation is equipped with an additional pipe connecting the input of the low pressure medium of the ejector to the outlet diffuser, and an electromagnetic valve is installed on the pipe.

For unambiguous correlation of design features, the second evaporator is adopted and executed low-temperature.

The solenoid valve on the auxiliary pipe is normally closed, as when operating in normal installation mode, it must be closed.

The technical result of the utility model is to increase the efficiency of the refrigeration cycle.

An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model, made it possible to establish that the applicant did not find a source characterized by signs that are identical to all essential features of the utility model. The definition from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed us to establish a set of significant distinguishing features in relation to the technical result considered by the applicant in the claimed device, set forth in the utility model formula.

Therefore, the claimed utility model corresponds to the sign of "novelty."

The figure shows a diagram of a refrigeration unit for provision pantries according to technical solutions of a utility model.

The refrigeration unit contains the main components: compressor 1, freon condenser 2, first and second evaporators 3, 4, solenoid valves 5, 6 and thermostatic valves 7 and 8 installed in front of the evaporators, pressure regulator “to yourself” 9, gas-jet ejector 10, additional pipeline 11, with an installed solenoid valve 12.

The input of the high-pressure medium of the ejector is connected to the output of the first evaporator, the outlet diffuser is connected to the suction line of the compressor, the input of the low-pressure medium is connected to the output of the second evaporator.

An additional pipeline connects the inlet of the low-pressure medium of the ejector to the outlet diffuser.

Some fittings, automation and communication devices, standard for refrigeration units and not essential for explaining a utility model, are not shown in the diagram. Also, provisioning pantries, in which evaporators are located, are not shown, as non-equipment installations.

The refrigeration unit according to the proposed utility model works as follows.

Compressor 1 compresses the refrigerant vapors and feeds them to condenser 2, where they are cooled by water and liquefied. Further, the freon passing electromagnetic valves 5, 6 expands in thermostatic valves 7, 8 and reduces its temperature. Further, in evaporators 3, 4, the liquid phase of the freon boils and cools the air. After the first evaporator 3, the hFC in the gas state enters the inlet of the high-pressure medium of the gas-jet ejector 10 at a constant boiling pressure of the evaporator 3, which is maintained by the pressure regulator 9. After the second evaporator 4, the hFC in the gas state is supplied to the inlet of the low-pressure medium of the ejector 10. When the ejector is in operation in the outlet diffuser of the ejector above the freon pressure at the inlet of the low-pressure medium of the ejector, i.e. higher pressure after the second evaporator 4. Thus, the suction pressure of the compressor, ceteris paribus, is higher than when the prototype. Freon in the gas state enters the compressor 1, and then the cycle repeats. The solenoid valve 12 on the auxiliary pipe 11 is closed.

When the evaporator 3 is turned off, for example, during repair or loading and unloading operations in the provisions storeroom where the evaporator 3 is located, in order to exclude additional hydraulic resistance of the ejector in the path of the refrigerant from the evaporator 4, the electromagnetic valve 12 opens. Opening the electromagnetic valve 12 allows bypassing the ejector avoid unauthorized reduction of compressor suction pressure 1.

When the evaporator is switched off, 4 switching in the refrigeration unit circuit is not required, because the operating mode of the evaporator 3 and compressor 1 is supported by a pressure regulator 9.

According to the proposed utility model, thermal and structural calculations are carried out according to well-known methods, positive results are obtained that justify the claimed technical results.

Evaluation of the effectiveness of the refrigeration unit was carried out by the refrigeration coefficient ε

where Q ₀ is the cooling capacity of the installation, W;

N _k - power consumption of the compressor, W, for a refrigeration unit with the following parameters:

- air temperature supported by evaporators - minus (18 ± 2) ° and (3 ± 2) ° С;

- the required cooling capacity at the temperature level minus (18 ± 2) ° С - 0.8 kW; at the level of (3 ± 2) ° С - 1.7 kW;

- refrigerant - Freon 134a;

- cooling water temperature - (32 ± 2) ° С.

Given the real conditions of the state of the freon at the inlet to the compressor and the design, the refrigeration coefficient of the installation according to the prototype scheme is 1.2 ÷ 1.4, according to the scheme of the proposed utility model - 1.8 ÷ 2.0.

All technical means of the utility model are described or known at the date of application.

Scroll compressors, water-cooled freon condensers, various types of freon evaporators, self-adjusting bellows pressure regulators, solenoid valves of various sizes are produced by the Applicant's own production for marine refrigeration and climatic equipment, including refrigeration units of provision pantries.

Thus, the above information indicates the following conditions are met when using the claimed utility model:

- a tool embodying the claimed utility model in its implementation, is intended for industrial use, namely, in a refrigeration unit for provision storerooms;

- for the claimed utility model in the form in which it is described in the independent clause of the stated utility model formula, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed.

Therefore, the claimed utility model meets the condition of "industrial applicability".

The implementation of the proposed device can improve the efficiency of refrigeration units for provision pantries.

Claims (3)

1. Refrigeration unit for provision pantries, containing a compressor, a freon condenser, first and second evaporators, electromagnetic valves and thermostatic valves installed in front of the evaporators, and a self-regulating refrigerant pressure regulator installed after the first evaporator, characterized in that it is parallel to the pressure regulator a gas-jet ejector is installed, the input of the high-pressure medium of which is connected to the output of the first evaporator, the outlet diffuser of the ejector is connected to the compressor suction line, the input is low PORN medium of the ejector is connected to the output of the second evaporator unit is provided with an additional conduit connecting the inlet with the low pressure environment of the ejector diffuser diverter, wherein the solenoid valve is installed on the pipeline. 2. Installation according to claim 1, characterized in that the second evaporator is a low-temperature evaporator. 3. Installation according to claim 1, characterized in that the solenoid valve on the auxiliary pipe is normally closed.

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