RU2310801C1 - Absorption-diffusion refrigerator - Google Patents

Abstract

FIELD: refrigeration engineering.

SUBSTANCE: refrigerator comprises generator, absorber provided with the connecting pipes for supplying and discharging solution, condenser, evaporator steam-lifting pump for lifting strong solution to the separator actuated by means of coolant supplied from the generator, pipe for steam-gas mixture, and steam duct with hydraulic valve gate. The refrigerator has additional steam-lifting pump with lifting pipe, additional separator, and additional steam duct with hydraulic valve gate. The absorber is provided with the additional tank. The steam space of the separator is connected with the lifting pipe of the additional steam-lifting pump whose bottom end is connected with the tank in the bottom part of the absorber, and top end is set into the steam space of the additional separator that is connected with the lifting pipe of the downstream additional steam-lifting pump whose bottom end is connected with the additional tank in the bottom part of the absorber, and top end is set into the steam space of the downstream additional separator connected with the steam space of the condenser. The liquid spaces of the additional separator and downstream additional separator are connected with the connecting pipe for supplying solution to the absorber.

EFFECT: reduced sizes.

8 cl, 1 dwg

Description

The invention relates to household refrigeration and can be widely used in domestic refrigerators equipped with absorption-diffusion refrigeration units (ADHA).

Known ADHA (RF Patent No. 2079071, F25В 15/10, 1997), which contains a steam lift pump for lifting a strong solution into the separator, working with steam from a boiler, the level of the boiling solution in which is higher than the level of supply of a weak solution to the absorber. In addition, ADHA contains a heat exchanger-condenser and a heat exchanger-reflux condenser, the liquid cavities of which are included in the line of strong solution between the separator and the boiler.

A disadvantage of the known ADHA is its low thermodynamic efficiency, due to the insufficient intensity of the heat-mass transfer processes occurring in it.

The closest analogue of the claimed invention is ADHA (RF Patent No. 2205336, F25В 15/10, 2003), containing a generator, an absorber with fittings for input and output of the solution, a condenser, an evaporator, a lift pump for lifting a strong solution into the separator, working with the help of refrigerant vapor from generator, the level of boiling solution in which is higher than the level of supply of a weak solution to the absorber, the vapor-gas mixture pipe and the steam line with a water seal.

A disadvantage of the known ADHA is the low refrigerating capacity due to the low efficiency of the absorber.

The objective of the invention is to obtain in the process of absorption of a strong solution of maximum concentration by increasing the contact surface of the cold vapor-gas mixture (ASG) with the solution entering the absorber without increasing the overall dimensions of the absorber.

The task is achieved due to the presence of the following set of essential features.

Absorption-diffusion refrigeration unit containing a generator, an absorber with solution inlet and outlet fittings, a condenser, an evaporator, a lift pump for lifting a strong solution into a separator operating with refrigerant vapor from a generator, the level of boiling solution in which is higher than the level of supply of a weak solution to the absorber , a gas-vapor mixture pipe and a steam line with a water lock, characterized in that the unit is equipped with an additional steam lift pump with a lifting pipe, an additional separator, an additional steam line with a water trap, and the absorber is equipped with an additional capacity, while the steam cavity of the separator is connected through a water trap through a water trap to the riser pipe of the additional steam lift pump, the lower end of which is connected with the formation of a water trap to the tank in the lower part of the absorber, and the upper end is inserted into the steam cavity of the additional separator, which, through an additional steam line, is connected through a hydraulic lock to the lifting pipe of the subsequent additional parlift pump, the lower end of which It is connected with the formation of a water seal to an additional tank in the lower part of the absorber, and the upper end is inserted into the vapor cavity of the subsequent additional separator associated with the vapor cavity of the condenser, while the liquid cavities of the additional separator and the subsequent additional separator are connected through hydraulic locks to the solution inlet port to the absorber.

The unit contains an absorber made in the form of a cylindrical body with plugged ends, inside of which a vapor-gas mixture pipe is installed with a gap.

The unit contains the outlet end of the nozzle for introducing the solution into the absorber, connected through a water lock to the liquid cavity of the additional separator, which is located above the surface of the baffle cylinder with an open upper end and a bypass hole for the vapor-gas mixture in the lower part, which is installed with a gap between the vapor-gas mixture pipe and the absorber body and hermetically connected to the lower end of the absorber.

The unit contains the outlet end of the nozzle for introducing the solution into the absorber, connected through a water trap to the liquid cavity of the subsequent additional separator, which is located above the pipe surface of the gas-vapor mixture.

The unit contains a container in the lower part of the absorber, which is formed by the absorber body, the lower end of the absorber and an additional partition wall with an open upper end sealed to the lower end of the absorber installed with a gap between the partition wall and the absorber case.

The unit contains an additional container in the lower part of the absorber, which is formed by an additional cylinder-partition, the lower end of the absorber and the cylinder-partition.

The unit contains a nozzle for withdrawing a strong solution from the absorber to the steam lift pump, which is connected to the inner tank in the lower part of the absorber, formed by a partition cylinder and the lower end of the absorber.

The unit contains the outlet end of the nozzle for introducing a weak solution from the generator into the absorber, which is located above the inner surface of the absorber housing.

Consider the presented schematic drawing of ADHA, which allows us to understand the design features of the proposed refrigeration unit.

ADHA contains a steam lift pump 1 for lifting a strong solution into the separator 2, which works with the help of refrigerant vapor from the generator 3, the level of the boiling solution ▽ a in which is higher than the level ▽ b of the solution supply to the absorber 4. At the same time, the steam cavity of the separator 2 through the steam line 5 through the hydraulic lock connected to the lifting pipe of the additional steam lift pump 6, the lower end of which is connected with the formation of a water seal to the tank 7 in the lower part of the absorber 4, and the upper end is brought into the vapor cavity of the additional separator 8, which by means of an additional steam pipe 9 is connected through a water trap to a lifting pipe of a subsequent additional steam lift pump 10, the lower end of which is connected with the formation of a water trap to an additional tank 11 in the lower part of the absorber 4, and the upper end is inserted into the steam cavity of the subsequent additional separator 12 connected with the vapor cavity of the condenser 13. In this case, the liquid cavities of the additional separator 8 and the subsequent additional separator 12 are connected via hydraulic locks to the fitting, respectively m 14 and a fitting 15 for introducing the solution into the absorber 4.

The unit contains an absorber 4, made in the form of a cylindrical body with plugged ends, inside of which a pipe 16 ASG is installed with a gap.

The output end of the nozzle 14 for introducing the solution into the absorber 4, connected through a hydraulic lock to the liquid cavity of the additional separator 8, is located above the surface of the baffle cylinder 17 with an open upper end and a bypass hole for the gas mixture in the lower part, which is installed with a gap between the PGS pipe 16 and the body the absorber 4 and hermetically connected to the lower end of the absorber 4.

The output end of the nozzle 15 for introducing the solution into the absorber 4, connected through a water trap to the liquid cavity of the subsequent additional separator 12, is located above the surface of the ASG pipe 16.

The tank 7 in the lower part of the absorber 4 is formed by the absorber body, the lower end of the absorber 4 and installed with a gap between the baffle cylinder 17 and the absorber casing 4 with an additional baffle cylinder 18 with an open upper end, hermetically connected to the lower end of the absorber 4.

Additional capacity 11 in the lower part of the absorber 4 is formed by an additional cylinder-partition 18, the lower end of the absorber 4 and the cylinder-partition 17.

The fitting 19 of the output of the strong solution from the absorber 4 to the steam lift pump 1 is connected to the inner tank 20 in the lower part of the absorber 4, formed by the partition wall cylinder 17 and the lower end of the absorber 4.

The output end of the nozzle 21 for entering a weak solution from the generator 3 into the absorber 4 is located above the inner surface of the housing of the absorber 4.

The work of ADHA is as follows.

ADHA is charged with circulating substances in a known manner.

As a result of heat removal from the electric heater 22, a strong solution boils. Due to the overpressure, the refrigerant vapor is squeezed out of a strong solution in the hydraulic lock at a level of ▽ in and enters the riser pipe of the steam lift pump 1. The resulting two-phase mixture enters the separator 2 through the riser pipe and accumulates at a level of ▽ g, which is not lower than the level ▽ a of the boiling solution in generator 3. In the separator 2 is the separation of a strong solution and vapor refrigerants.

The unit is equipped with a condenser 13 and a reflux condenser 23 made in one in the form of pipe-in-pipe heat exchangers 23. A strong solution from the separator 2 enters the generator 3 through the annular cavity of the condenser 13 and the reflux condenser 3. Refrigerant vapors resulting from heat exchange between the strong solution and the parts generator 3, not participating in the process of evaporation of the strong solution, are removed from the housing of the generator 3 into an additional condenser 24. Refrigerant vapor from the common annular cavity of the condenser 13 and reflux condenser 23 also are found in the additional condenser 24. The liquefied refrigerant from the auxiliary capacitor 24 flows into the evaporator 25 and is evaporated, producing refrigeration effect.

A weak solution from the generator 3 through the nozzle 21 enters the inner surface of the housing of the absorber 4 and, when draining on it, absorbs refrigerant vapor from the ASG. The partially absorbed solution accumulates in the tank 7 in the lower part of the absorber 4 at the level ▽ d and through the hydraulic lock enters the riser pipe of the additional parlift pump 6.

The refrigerant vapor from the separator 2, due to overpressure, presses the solution in the hydraulic lock at the level ▽ d through the steam line 5 and enters the riser pipe of the additional steam lift pump 6. The two-phase mixture forms through the riser pipe to the additional separator 8, where the refrigerant vapor and solution are separated, which, through a water seal with the help of a fitting 14, is introduced into the absorber and fed to the surface of the baffle cylinder 17. When draining along the surface of the baffle cylinder 17, the solution absorbs refrigerant vapor and from ASO and, becoming a solution of a higher concentration, it accumulates in an additional tank 11 in the lower part of the absorber 4 at a level of ▽ e, from which through a water trap it enters the lifting pipe of the subsequent additional parlift pump 10.

The refrigerant vapor from the additional separator 8, due to excess pressure, presses the solution in the hydraulic lock at the level ▽ e through the additional steam line 9 and enters the riser pipe of the subsequent additional steam lift pump 10, through which the two-phase mixture enters the subsequent additional separator 12, where the solution and refrigerant vapor are separated . Refrigerant vapors from the subsequent additional separator 12 through the reflux condenser 23 enter the condenser 13, where they are liquefied. The liquid refrigerant flows to the evaporator 25, in which it boils at low pressure, producing a refrigerating effect. The resulting cold ASG through the pipe 16 enters the absorber 4 and through the bypass hole 26 in the lower part of the cylinder-septum 17 is distributed throughout the entire volume of the absorber 4.

The solution from the subsequent additional separator 12 through the water seal using the nozzle 15 is introduced into the absorber 4, where it is fed to the surface of the ASG pipe 16, during which it absorbs the vapor of the ASG refrigerant. Through the open upper end of the baffle cylinder 17, substantially pure hydrogen enters the evaporator 25.

Since the ASG pipe 16 is located inside the partition cylinder 17, the strong concentration of the maximum concentration formed during the absorption process after draining along the surface of the ASG pipe 16 is accumulated in the inner tank 20 at the level of ▽ in and through the fitting 19 it enters the parlift pump 1. After that, the working cycle ADHA is repeated.

Thus, achieved by using the proposed device, the technical result is the receipt in the process of absorption of a strong solution of maximum concentration, due to a three-time supply of the solution to the absorber. This ensures consistent movement of the solution on different surfaces of the elements of the unit and the absorber without mixing solutions of different concentrations. This increases the contact surface of the ASG with the solution without increasing the overall dimensions of the absorber.

Comparison of the claimed ADHA not only with the prototype, but also with other technical solutions in this technical field did not reveal the signs that distinguish the claimed device from the prototype.

This gives reason to recognize the claimed solution in accordance with the criteria of the invention.

The economic feasibility of using the proposed ADHA as part of household refrigerators is to reduce their daily energy consumption due to the deep utilization of heat and increase the efficiency of the absorber.

Claims (8)

1. Absorption-diffusion refrigeration unit comprising a generator, an absorber with solution inlet and outlet fittings, a condenser, an evaporator, a steam lift pump for lifting a strong solution into a separator operating with refrigerant vapor from a generator, the level of the boiling solution in which is higher than the level of supply of a weak solution into the absorber, the gas-vapor mixture pipe and the steam line with a water lock, characterized in that the unit is equipped with an additional steam lift pump with a lifting pipe, an additional separator, an additional steam line the house with a water trap, and the absorber is equipped with an additional capacity, while the steam cavity of the separator is connected through a water trap through a water trap to the riser pipe of the additional steam lift pump, the lower end of which is connected with the formation of a water trap to the tank in the lower part of the absorber, and the upper end is inserted into the steam cavity of the additional separator , which is connected through an additional steam line through a water trap to the lifting pipe of the subsequent additional steam lift pump, the lower end of which the second one is connected with the formation of a water trap to the additional tank in the lower part of the absorber, and the upper end is introduced into the vapor cavity of the subsequent additional separator associated with the vapor cavity of the condenser, while the liquid cavities of the additional separator and the subsequent additional separator are connected through hydraulic locks to the solution inlet port to the absorber. 2. The unit according to claim 1, characterized in that the absorber is made in the form of a cylindrical body with plugged ends, inside which a vapor-gas mixture pipe is installed with a gap. 3. The unit according to claim 2, characterized in that the outlet end of the nozzle for introducing the solution into the absorber, connected through a water trap to the liquid cavity of the additional separator, is located above the surface of the partition cylinder with an open upper end and a bypass hole for the vapor-gas mixture in the lower part installed with a gap between the vapor-gas mixture pipe and the absorber body and hermetically connected to the lower end of the absorber. 4. The unit according to claim 2, characterized in that the outlet end of the nozzle for introducing the solution into the absorber, connected through a water trap to the liquid cavity of the subsequent additional separator, is located above the surface of the gas-vapor mixture pipe. 5. The assembly according to claim 2, characterized in that the container in the lower part of the absorber is formed by the absorber body, the lower end of the absorber and an additional partition wall with an open upper end sealed to the lower end of the absorber installed with a gap between the partition wall and the absorber case . 6. The assembly according to claim 2, characterized in that the additional capacity in the lower part of the absorber is formed by an additional cylinder-partition, the lower end of the absorber and the cylinder-partition. 7. The assembly according to claim 2, characterized in that the fitting for withdrawing the strong solution from the absorber to the steam lift pump is connected to an internal container in the lower part of the absorber formed by the partition wall and the lower end of the absorber. 8. The unit according to claim 2, characterized in that the output end of the nozzle for entering a weak solution from the generator into the absorber is located above the inner surface of the absorber housing.