SU1760263A1 - Hydride refrigerator - Google Patents

Abstract

Purpose: refrigeration equipment, sorption refrigeration units. Summary of the Invention: The installation includes absorber generators 16, 17, filled with TIGT2, the heating surfaces 18, 19 of which are connected to the high pressure pipeline 9, the hydrogen desorption lines through valves 25, 26 are connected to the low pressure pipeline 12, and the hydrogen absorption lines through valves 27, 28 - with pipeline 9. At that, the mass ratio ABs, where A is one of the rare earth elements or their alloy, and B is one of the catalyst metals or their alloy, to the mass of TiGr2 is from 6.5 to 45, five. 1 il.

Description

The invention relates to refrigeration and can be used to create sorption refrigeration units.

A known absorption refrigeration unit comprising a generator-absorber filled with LaNUAl or ZzNi, with heat exchange surfaces inside, a generator-absorber filled with LaNi5 or TIFe, with a heat exchange surface in it, and a refrigerating chamber, and the cooling chamber connected to the heat exchanger inside the second generator absorber 1. The installation works as follows. The heat exchange surface of the second generator-absorber is supplied with air, which is cooled by taking off heat during the desorption of hydrogen from the LaNigHx or TiFeHx hydride. The hydrogen enters the first absorber-generator, where LaNtoA or ZZNI is absorbed. The cooled air enters the cooling chamber and cools it.

The advantage of installation is ease of manufacture and operation. The disadvantage is the impossibility of obtaining low temperatures, since the cooling temperature is limited by the hydrogen desorption pressure from LaNisHxiinn TiFeHx, as well as by the absorption pressure LaNUAl or ZZNL

A refrigeration unit is known that contains absorber generators filled with a mixture of components A and B in a ratio of 1: 3 to 2:17. where A is calcium or one of the rare-earth elements, and B is predominantly nickel, cobalt, alternately switched from high-pressure hydrogen desorption to low-pressure hydrogen sorption, water and nitrogen hydrogen coolers, set

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but

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in the high pressure pipeline, heat exchangers for cooling high pressure hydrogen with low pressure hydrogen and a throttle device separating high and low pressure pipelines 2.

The device works as follows. When one of the absorber generators is heated by an electrofire, the other is cooled by water at this time. During desorption, the hydrogen is cooled by a water heat exchanger, in a low pressure hydrogen heat exchanger, liquid nitrogen in the cooler and finally on another hydrogen low pressure heat exchanger. Then, expanding in the throttle device, hydrogen significantly lowers its temperature and cools the necessary equipment. After that, the hydrogen is adsorbed by the second absorber generator.

The advantage of this installation is the possibility of obtaining low temperatures (up to 25 K). The disadvantage is low efficiency due to the high energy costs of nitrogen liquefaction.

The aim of the invention is to increase the economics of the installation in obtaining cold at low temperatures by reducing the energy consumption for hydrogen cooling below the inversion temperature.

The goal is achieved by the fact that the installation includes absorber generators filled with TiGra, heating surfaces of which are connected to a high pressure pipeline, hydrogen desorption lines are connected to a low pressure pipeline, and hydrogen absorption lines are connected to a high pressure pipeline. The ratio of the mass of the intermetallic ABs, where A is one of the rare-earth elements or their alloys, and B is one of the metals of the catalysts or their alloys, to the mass of TiGrz is 6.5-45.5. High pressure hydrogen, desorbed by one of the absorber generators with ABs, cooled in a water cooler and a low pressure hydrogen heat exchanger, enters the heating surface of the absorber-absorber with TiGraHx, where further high pressure hydrogen is cooled due to the selection of desorption heat from it hydrogen from hydride TiGraHx. Then high pressure hydrogen, having cooled in the second low pressure hydrogen exchanger, enters the throttle device and then to the cooled object. From the cooled object, hydrogen is supplied through heat exchangers of low pressure hydrogen during the isolation of the absorber-absorber with ABB, cooled by water, where it is absorbed to form ABsHx hydride. The hydrogen released by TiGraHx also enters this generator-absorber through its hydrogen desorption line.

5At the same time part of the hydrogen

high pressure after the water cooler is taken to the hydrogen absorption line of the second absorber-generator with TIG g, which is cooled by water,

0 which leads to the formation of hydride TiGraHx. This ensures the continuity of the high pressure hydrogen cooling process.

Thus, in the proposed installation, the nitrogen cooler, operating at a significant cost of electricity, was replaced by a hydride cooler, which works more economically. Calculations show that at the same time energy consumption can be reduced from

0 0.4-0.42 kW per kW of cold to 0.32-0.36 kW per kW of cold.

The ratio of the mass of ABs to the mass of TiGr2 in the range from 6.5 to 45.5 allows cooling high-pressure hydrogen in the entire range of its temperatures in front of the absorber generators. If this value is over 45.5. The TiGra absorber generators may not provide the necessary cooling of high pressure hydrogen. If this value is less than 6.5, then this does not give an additional effect, since the temperature of high pressure hydrogen behind the TiGra absorber generators is limited by the hydrogen desorption pressure from TiGra and

5 by the pressure of its absorption ABs, i.e. getting a lower temperature still fails.

Comparative analysis of the proposed technical solution with the prototype

0 showed that the differences are characterized by a combination of the following features: absorber generators filled with TiGra are included in the installation; heating surfaces of these absorbing generators

5 are connected to the high pressure pipeline of the installation; The hydrogen desorption lines of these absorber generators are connected to the low pressure pipeline of the installation, and the hydrogen absorption lines are connected to the high pressure pipeline of the installation; the ratio of the mass of ABs to the mass of TiGra is from 6.5 to 45.5. Since these characteristics allow to achieve a positive effect, they

5 meet the criterion of significant differences

Refrigeration units using a pair of ABs and TiGra intermetallides have not been found in the literature. He found. also, the mass ratio of AB and TiGra is in the range from 6.5 to 45.5. Known installation, in which the cooling occurs due to the process of desorption of hydrogen from the hydride (see, for example, ed. St. № 1019188). However, in comparison with it, the proposed technical solution uses TlGr2, and only it allows to obtain a positive effect. It is quite another to connect the heating surface, absorption lines and desorption lines of the absorber generators from TiGr2 to the installation pipelines. The authors, however, claim not the method of cooling due to the heat of hydrogen desorption, but the refrigeration unit containing the totality of the elements presented in the claims. Only a combination of these elements, and not they individually, will achieve the positive effect that is the aim of the invention. Thus, the above signs meet the criterion of novelty.

The drawing shows the scheme of the proposed refrigeration unit.

The refrigeration unit contains absorption generators 1, 2, filled with ABg, where A is one of the rare earth metals or their alloy, and B is one of the metal catalysts or their alloy. The absorber generators have heating surfaces 3, A and cooling 5, 6. The desorption lines through valves 7 and 8 are connected to high pressure pipeline 9, and the absorption lines through valves 10, 11 are connected to low pressure pipe 12. A water cooler 13 and low pressure hydrogen heat exchangers 14, 15 are installed on line 9. The installation includes generator-absorbers 16, 17, filled with TiGr2, whose heating surfaces 18, 19 are connected to high pressure pipeline 9 through valves 20, 21 and to throttle device 24 through valves 22, 23. Generator-absorber hydrogen desorption lines 16, 17 through valves 25, 26 are connected to a low pressure pipeline 12, and hydrogen absorption lines through valves 27, 28 are connected to a high pressure pipeline 9. Cooling surfaces 29, 30 are also located in the absorber generators 16, 17. A tank 31 is provided for draining liquid hydrogen.

The installation works as follows.

The source of heating of the generator-absorber 1 is turned on and at the same time water is supplied to the cooling-surface 6 of the generator-absorber 2. The high pressure hydrogen through valve 7 enters the high pressure pipeline 9. Cooled in water cooler 13 and

the low pressure hydrogen exchanger 14, through the valve 20 enters the heating surface 18 of the generator-absorber 16. Here, further high-pressure hydrogen is cooled by taking heat to desorb hydrogen from TiGraHx, which through the valves 25 and 11 enters the absorber 2. High pressure hydrogen through valve 22 enters the low pressure hydrogen heat exchanger 15, into the throttle device 24, and then as a liquid into the tank 31 and to the cooled equipment. Hydrogen evaporated during equipment cooling

5 enters the low pressure pipeline 12, where it passes through the second circuits of the heat exchangers 15 and 14, cooling the high pressure hydrogen, and is absorbed in the absorber generator 2. At the same time

0, part of the hydrogen from the high-pressure pipeline 9 is fed through the valve 28 into the generator-absorber 17, through which water is pumped through the cooled surface 29 of which.

After the generator-ab5 of the sorber 1 is completely discharged, it is turned on from the heating source, and water is switched to surface 5. The heating source of the generator-absorber 2 is turned on. High pressure hydrogen is fed through valve 8 to pipeline 9.

0 Hydrogen passed through the cooler 13. heat exchanger 14, valve 21, heating surface 19, valve 23, heat exchanger 15, is liquefied in the throttle device 24. Desorbed hydrogen is flowing through valves 26 and 10

5 enters generator-absorber 1. Part of the high-pressure hydrogen through valve 27 enters generator-absorber 16, which is cooled by water pumped through surface 30.

Thus, the proposed hydride – refrigeration unit allows to obtain a cold of low temperature at lower energy costs, since the nitrogen cooler is replaced by a hydride cooler.

Claims (1)

Claims of the invention A hydride refrigeration unit comprising adsorber generators filled with ABs hydride, where A is one of 0 rare earth elements or their alloys, and B - one of the metal catalysts or their alloys, which are connected to the sources of heating and cooling, heat exchange 5 surfaces and a throttle device separating high and low pressure pipelines, characterized in that, in order to increase efficiency in obtaining cold at low temperatures, the installation additionally contains adsorption generators filled with a higher equilibrium hydride pressure and connected to a low pressure pipe TJGr2 heating of which is basement, and hydrogen absorption lines The pipes to the pipeline are highly connected to the high pressure pipeline, and the main lines of hydrogen desorption. j 1 W .G.-ZffJX g yg Tygzk G: 29O K 74 $ 0 warts / tyuh For cooling equipment