SU879202A1 - Bromium-litium absorption unit for producing heat and refrigeration - Google Patents

Description

The invention relates to the field of refrigeration, and more specifically to bromide lithium absorption units for the production of heat and cold.

Known bromistolithium absorption units for generating heat and cold, containing a weak solution superheater, a multi-stage heat regenerator between superheated self-evaporating and heated weak solution with condensate collectors in each stage, a block of absorbers and evaporators, high and low pressure, in which the low pressure absorber has thermal contact with a high pressure evaporator, and the heat exchange surfaces of the high pressure absorber and low pressure evaporator are respectively included in the qi circulation circuits of heat and cold consumers, coolers installed on the line of strong solution between the regenerator and the high pressure absorber and between the latter and the low pressure absorber, and pumps for strong and weak solutions and heat and coolants [1].

A disadvantage of the known units is their low efficiency due to the high metal consumption, since absorbers and evaporators. high and low pressures are made in the form of separate apparatuses.

The aim of the invention is to increase efficiency by reducing metal5 capacity.

This goal is achieved by the fact that the block of absorbers and evaporators is made in the form of a heat exchanger, consisting of a package of plates with curly interlayers forming cavities with plates divided into three compartments, two of which are communicated with each other, and the communicating compartments in adjacent cavities serve respectively, with absorbers ¹⁵ and high and low pressure evaporators, and the remaining compartments are included respectively in the circulation circuits of consumers of cold and heat. In addition, separators are installed in the communicating compartments between the evaporators and the high and low pressure absorbers, and irrigation bars for solution and condensate are placed above the latter in the same apparatus.

In FIG. 1 schematically shows the proposed unit; in FIG. 2 - block absorbers and evaporators of high and low pressure.

The unit contains a superheater 1 of a weak ³⁰ solution, a multi-stage regenerator 879202 heat absorber 2 between an overheated self-evaporating and heated weak solution with condensate collectors 3 in each stage, a block of 4 absorbers and high and low pressure evaporators, a heat consumer 5, a consumer 6 cold, coolers 7 and 8, installed on line 9 of a strong solution and on line 10 of a weakened solution (after a high pressure absorber), a pump 11 for a weakened solution, a pump 12 for a weak solution, a pump 13 for supplying condensate to the evaporator high pressure pump 14 for coolant, pump 15 for coolant, pump 16 for recirculation of condensate in a low pressure evaporator, plates 17-22, forming cavities with curly gaskets 23-26, divided into compartments 27-32, separator 33 between compartments 27 and 28, respectively serving as a high pressure absorber and a high pressure evaporator, a separator 34 between compartments 30 and 31, respectively serving as a low pressure evaporator and a low pressure absorber, and irrigation bars 35 and 36, respectively, for condensate and solution in and the evaporator and the low-pressure absorber (similar strips in compartments 27 and 28 are not shown in the drawing). In addition, the unit contains a vacuum pump 37, gaskets 38 and 39, and pressure plates 40 and 41, between which plates with gaskets are clamped.

Compartments 29 have thermal contact with compartments 30 and are included in the consumer circuit 6 of the cold. The compartments 32 have thermal contact with the compartments 27 and are included in the circulation circuit of the consumer 5 heat. Compartments 28 are in thermal contact with compartments 31, the first of which serve as a high pressure evaporator, and the second as a low pressure absorber.

The operation of the unit is as follows.

The weak solution from the compartments 31 is taken by the pump 12 and fed through a pipeline passing through all the stages of the regenerator 2 to the superheater 1. Here, the weak solution is overheated at high pressure by an external heat source, for example, exhaust hot gases. Then, the superheated weak solution is sequentially throttled in the steps of regenerator 2, while the solution self-evaporates and the water vapor formed condenses in the pipeline of the weak solution, heating the latter, and the condensate obtained is collected in collectors 3. From the last stage of regenerator 2, a strong solution is introduced through line 9 through cooler 7 into a high-pressure absorber (compartments 27), in which, with the help of irrigation bars (not shown in the drawing), the film flows down the plates, absorbing the condensate vapors leaving through the separator 33 of the high pressure evaporator (compartments 28). The condensate from the regenerator 2 enters the high-pressure evaporator, in which, flowing down along the surface of the plates, it evaporates due to the supply of absorption heat released to the low-pressure absorber (compartments 31). The remaining non-evaporated condensate from the high-pressure evaporator is pumped 13 to the low-pressure evaporator (compartments 30), in which the plate surface is irrigated with the help of strip 35 and is evaporated by supplying heat from the coolant that enters the compartments 29 from the consumer 6 of cold. The resulting vapors are absorbed in the low pressure absorber (compartments 31) to form a weak solution and the cycle repeats.

The economic efficiency of the proposed unit is expressed in the reduction of capital costs associated with a decrease in the metal consumption of the unit, as well as in the reduction of the amount of expensive crystalline lithium bromide charged into the unit.

Claims (2)

rator 2 heat between superheated self-evaporating and heated weak solution 00 condensate collectors 3 in each stage, block 4 of absorbers and high and low pressure evaporators, heat consumer 5, cold consumer 6, coolers 7 and 8 installed on line 9 of strong solution and lines 10 of the weakened solution (after the high-pressure absorber), pump 11 for the weakened solution, pump 12 for the weak solution, pump 13 for supplying condensate to the high-pressure evaporator, pump 14 for the heat carrier, pump 15 for the coolant, pump 16 for recirculating condensate in a low pressure evaporator, plastias 17-22, forming cavities with curly gaskets 23-26, divided into compartments 27-32, separator 33 between compartments 27 and 28, serving as a high pressure absorber and high pressure evaporator, separator 34 between compartments 30 and 31, serving as a low pressure evaporator and a low pressure absorber, respectively, and irrigation strips 35 and 36, respectively, for condensate and solution in the evaporator and in a low pressure absorber (similar strips B compartments 27 and 28 for h The drawing is not shown). In addition, the unit contains a vacuum pump 37, gaskets 38 and 39, and pressure plates 40 and 41, between which the plates from the gasket 29 are clamped, have thermal contact with compartments 30 and are included in the cold circuit of consumer 6. The compartments 32 have thermal contact with the compartments 27 and are included in the heat consumer circuit 5. The compartments 28 are in thermal contact with the compartments 31, the first of which serve as a high-pressure evaporator, and the second - with a low-pressure absorber. The operation of the unit is carried out as follows. A weak solution from compartments 31 is taken up by pump 12 and supplied through a pipeline passing through all stages of the regenerator 2 to superheater 1. Here, the finished solution is overheated at high pressure by an external heat source, such as flue gases, then the overheated weak solution is successively throttled | x of the regenerator 2, at the same time the solution self-evaporates and the resulting water vapor condenses on the pipeline of a weak solution, heating the latter, and the resulting condensate is collected in collections 3. From In the steps of the regenerator 2, a strong solution is introduced through line 9 through cooler 7 to the high-pressure absorber (compartments 27), in which, using irrigation strips (not shown), the film flows through the plates, absorbing condensates through the separator 33 of the high pressure evaporator (compartments 28). Condensate from regenerator 2 enters a high-pressure evaporator, in which the stack over the surface of the plates evaporates by supplying heat of absorption absorbed in air (and pressure) (compartments 31). The remaining un-vaporised condensate from the high-pressure evaporator is fed by pump 13 to the evaporator low pressure (compartments 30), in which with the aid of a strip 35 it irrigates the surface of the plates and at the same time evaporates due to the supply of heat from the coolant, which enters the compartments 29 from the cold consumer 6. The resulting vapors are absorbed into the absorber Low pressure (compartments 31) with the formation of a weak solution and the cycle repeats. The economic efficiency of the proposed unit is reflected in a decrease in capital expenditures associated with a decrease in the metal intensity of the unit, as well as a decrease in the amount of expensive crystalline lithium bromide charged to the unit. 1. Bromide-lithium absorption unit for heat and cold production, containing a weak solution superheater, a multistage heat regenerator between superheated self-evaporating and a heated weak solution with condensate collectors in each stage, a block of high and low pressure absorbers and evaporators, in which the low pressure absorber has thermal contact with the high pressure evaporator, and the heat exchange surfaces of the high pressure absorber and low pressure evaporator are respectively included in the consumer circuits heat and cold, coolers installed in the line of strong solution between the regenerator and the high-pressure absorber and between the last and the low-pressure absorber About pressure, and pumps for soft and weak solutions of heat and coolants, characterized in that, in order to increase efficiency by reducing metal consumption, the block of absorbers and evaporators is made in the form of a heat exchanger apparatus consisting of a package of plastids with shaped pads forming cavities with plates divided into trn compartments, two of which communicate with each other, and the communicating compartments in the adjacent cavities serve as absorbers and evaporators of high and low pressure, respectively, and the remaining compartments loves  respectively, in the circulation contours of consumers of cold and heat. 2. A unit according to claim 1, characterized in that separators are installed in the communicating compartments between evaporators and high and low pressure absorbers, and over the latter in the same apparatuses irrigation planes for solution and condensate are located. The source of information taken into account in the examination: 1. Patent of Germany No. 2158617, cl. F 25 V 15/02, published 1977. / //