RU1802282C - Absortion refrigerating plant - Google Patents

Description

The invention relates to refrigeration equipment, in particular to heat absorbing heat transformers for producing cold.

The aim of the invention is to increase the efficiency of the installation, consisting mainly of standard equipment, during its year-round operation.

The drawing shows a diagram of the proposed absorption refrigeration unit.

The absorption refrigeration unit comprises a generator 1, a coil 2 for heating the generator, a rectifier 3, a reflux condenser 4, a coil 5 for returning the solution through the generator, a condenser 6, an aqueous supercooler. 7. steam supercooler 8, evaporator 9, inverted rectifier 10, inverted rectifier cooling coil 11, saturated solution pump 12, absorber 13, strong solution receiver 14, absorber cooling coil 15, return solution coil 16 through the absorber, strong solution pump 17 , heat regenerator 18, intermediate steam withdrawals 19-21, coil 22 for regenerator 18 heating, ejector 22, butterfly valves 24 and 25 non-return valve 26, shut-off valves 27, piping system and in particular pipelines 28 and 29 a cooling system for the condenser 6 and the absorber 13.

In the installation, these elements are connected as follows. The generator 1, equipped with a coil 2, through which the heating coolant circulates, is connected to the rectifier 3 and the reflux condenser 4, in addition, the generator 1 is also equipped with a return coil 5 of the solution supply, and the reflux condenser 4 is connected by a refrigerant line to the condenser 6 cooled by return water or air. The condenser 6 is connected to a water subcooler 7, cooled by fresh water, and a steam subcooler 8 and then through a throttle valve 24 q by an evaporator 9. The evaporator 9, intended for refrigeration, is connected by a steam line through a fuse 8 with an inverted rectifier 10. Reversed rectifier 10 contains a coil 11, through which fresh water is circulated, replenishing the cooling system 29 of the condenser 6 and the absorber 13. The bottom of the inverted rectifier 10 is connected via a pump 12 to the reflux condenser and 4. The receiver 14 located below the absorber 13. A rich liquor line is connected through a pump 17 and coil 16 to the entrance of vertical channels regenerator 18. The output of these channels

connected by a piping 28 of a strong solution to the cavity of the generator 1. The generator is connected by a pipeline of a weak solution through a return coil 5 and through

an ejector 23 with horizontal channels of the regenerator 18, At the outlet, these channels are connected through a throttle valve 25 to the cavity of the absorber 13. In addition, for operation in winter mode, the cavity of the absorber 13

connected by a steam line through a check valve 26 to the mixing chamber of the ejector 23, and the taps 19-21 of the intermediate steam of the regenerator 18 through the valves 27 are connected to different temperature zones

5 rectifier 3.

Installation works as follows.

A strong refrigerant solution boils in the generator 2 due to the heat circulating

0 through coil 2 of heating medium. The steam formed during boiling is fixed in the rectifier 3 and in the reflux condenser 4, and then liquefied in the condenser 5. The heat generated in this process is removed by water or

5 by air. The liquid refrigerant from the condenser 5 through the water subcooler 7, through the steam subcooler 8 and the throttle valve 24, enters the evaporator 9, where the cold action boils at low pressure. The steam formed, exchanging heat with liquid refrigerant in a subcooler 8, is sent to the inverted rectifier 10. Here, moving in countercurrent with the draining from the receiver

5 by 14 parts of a strong solution, steam decreases its concentration, and the merging solution increases its own. The heat released in this process is removed in the coil 11 with fresh water, which is used to replenish the cooling system 29 of the condenser 6 and the absorber 13. The solution 12 saturated in the rectifier 10 is pumped to the reflux condenser 4, while the weakened vapor enters the absorber 13, where it is absorbed

5 weak solution. The heat generated in this case is removed by water or air (see 29) circulating through the coil 15. The strong solution formed in the absorber 13 is drained into the receiver 14.

0 in the summer, the regenerator 18 serves as a heat exchanger of solutions, while the check valve 26 and valves 27 are closed, and the coil 22 is turned off. Weak solution from generator 1 through coil 5 and completely

5, an open ejector 23 enters the horizontal channels of the regenerator 18. where it exchanges heat with a strong solution moving in the vertical channels of the regenerator 18. Next, a cooled weak solution through the throttle valve 25

enters the absorber 13. The strong solution formed in the absorber from the receiver 14 is pumped through the coil 16 into the vertical channels of the regenerator 18. From these channels, the heated strong solution is returned via line 28 to the generator 1.

In winter, the regenerator 18 serves as an absorber-generator. A weak solution of generator 1 through a coil 5 enters the ejector 23, in which the solution pressure decreases to a pressure exceeding the pressure in the absorber 13 by the amount of losses in the pipelines; in this case, steam from the absorber 13 is sucked in through the pipe with a non-return valve 26. From the ejector, the vapor-liquid mixture enters the horizontal channels of the regenerator 18, where vapor is absorbed by the liquid. The resulting hardened solution through the fully open throttle vein-25 is sent to the absorber 13 for further hardening. The strong solution and the absorber 13 are discharged into the receiver 14 and NFSOS 17 after heating in the coil 16 is fed into the vertical channels of the regenerator TCJpa 18, Here the solution boils due to the heat generated by the absorption of steam in the horizontal channels of the regenerator, and due to the heating the coolant entering the coil 22 after exiting the generator 1. The weakened solution is returned via line 28 to the generator 1 for further distillation. The steam released in the vertical channels from the intermediate taps 19-21 through pipelines with valves 27 enters the corresponding temperature zones of the rectifier 3.

Claims (1)

The economic effect of the proposed installation is to reduce the cost of heating coolant, cooling air or water, and electricity, as well as to reduce its metal consumption. Calculations show that only the introduction of cooling of the rectified rectifier provides a saving of 5.5% in heat consumption, 9% in cooling air absorber, 8% in electricity, and 12% reduction in metal consumption. At the same time, only 5% of the absorber load is spent on cooling the reversed rectifier. According to the calculations, the boiling point in the evaporator is to - 25 ° С. The temperature of the heating coolant is 150 ° C, cooling air 32 ° C, water cooling the reversed rectifier, 20 ° C. SUMMARY OF THE INVENTION An absorption refrigeration unit comprising a generator with a rectifier and a reflux condenser, a condenser, a water and a pair of supercoolers, an evaporator, a reversed rectifier and an absorber connected to it with a refrigerant line, as well as a heat regenerator connected to it and the generator by lines of a weak and strong solution wherein the reversed rectifier through the line of the saturated solution through the pump is connected to the reflux condenser, and the condenser and absorber are connected to the cooling system with water or air, distinguishing that. In order to increase economic efficiency, the unit is equipped with a coil located in the inverted rectifier, the inlet of which is connected to a source of fresh water or air, and the outlet to a condenser and absorber cooling system.