SU12997A1 - Method of managing the workflow in absorption chillers - Google Patents

Description

In absorption machines, the management of the working process is already known, which means that the gaseous contents of the evaporator and the absorber are brought into circulation, with the aim that the mixed gases, which are not absorbed by the absorbing liquid, did not prevent the absorption of the working coolant. In the known machines of this, the foreign gas, predominantly air, is circulated to the working substance in the evaporator and the absorber intentionally so that they also have the same pressure in the boiler as well as the condensate). In many cases, however, the air is spontaneously jugged, namely, in machines operating at less than atmospheric pressure, which is strongly reflected in their performance. In this case also, this disadvantage is eliminated by means of the above circulation: - It is often sufficient to maintain in continuous movement only the gases in the absorber, so that between the absorbing liquid and the gas to be absorbed; aza.

In known machines of a similar type, the circulation is caused by a fan. This represents the disadvantage that a mechanical drive is required and the fan shaft must be passed through the machine's steak, which may be the cause of malfunctions in operation, due to the appearance of leaks.

The proposed method of maintaining the working process in absorption chillers consists in creating directing motion without the use of mechanical drives in that a part of the gaseous working substance released at higher pressure is introduced into the system consisting of the internal heater and absorber, for the purpose of forced non-movement, gas present in this systh (1e. This is possible only in such machines where there is a higher pressure in the boiler than in the evaporator and absorber .. This pressure can be maintained for and help of pumps. However, in eliminating the elimination of the mechanic drive in this case, it is possible to use the already known action of the liquid pillars.

In the drawing of Figs, 1 and 2 schematically depict devices enabling the implementation of the proposed method of conducting the working process in absorption chillers.

Obtained from the enriched solution. In the inlet coil 1, the gas enters the gas separator 2, entraining with it a part of the solution, which rises through the pipe 5 to the absorber 4, is enriched here again with gas and lowered through the pipe to the lower end of the boiling coil. Selected, - In; the boiler coil 1 gas enters through the pipeline 6 to the condenser 7, where it condenses. The condensate rises through pipe 8 to the evaporator 9, where it evaporates again. The resulting gas, in a mixture with a larger or smaller amount of foreign gas, flows through the pipe 10 to the absorber 4, as indicated in the fng. 1 arrow. A part of the mixture that is not absorbed in the absorber flows back through the pipe 11 in the direction of the arrow into the evaporator 9. From the pipe 6 there is a branch pipe 12, which enters the pipe 10, in which the gas flows due to its higher pressure. The outflow port 13 and the pipe 10 are sized in such a way that an injection action is obtained, under the influence of which the gas is sucked out of the evaporator 9 and injected into the absorber 4.

The tiller coil 1 is heated by an electric heating device 14, the heat of condensation released in the condenser 7 is removed by the cooling coil 15, and the heat of absorption that occurs in the absorber 4-

similar to the coil 16, the substance to be cooled flows through the coil 17 passing inside the evaporator 9. It is advisable to blow the gas produced in the boiling coil 1 in the direction from the evaporator 9 to the absorber 4, as shown in FIG. 1. If, on the contrary, the blowing is carried out in such a way that the gas first enters the evaporator 9, then here it would be subjected to excessive cooling,

, with loss of cold performance.

The extraneous gas admixed in the absorber 4 and the evaporator 9 is intended, in the process described above, to reduce the pressure difference between these two tanks on the one hand, and the gas separation spaces 2 and the condenser 7 on the other hand. Accordingly, the decrease in pressure difference, the columns

The fluids in the pipes 5, b and 8 can be made shorter, resulting in a reduced construction height of the entire machine. However, even in the case when the reduction of the construction height is not meant, it often has to be considered as spontaneous occurrence of impurities of foreign gases; for example, it is often difficult to completely eliminate air infiltration into the machine when the pressure prevails in the absorber and evaporator atmospheric. In this case, the described device brings significant benefits.

If in this case it is only about such small amounts of air that they can fully fit in the absorber alone, then it often turns out that it is sufficient to maintain the gas mixture present in the absorber in continuous motion. An exemplary embodiment of such a device is shown in FIG. 2. In the machine presented here, the absorber p 54 is equipped with an enlarged gas space capable of containing a relatively large amount of air penetration. A vertical partition 25 is arranged in the gas space, leaving a free gap dL of the gas mixture passage at the top and bottom edges. On one side of this partition, the nozzle 2 & with an upwardly facing hole causing gas to circulate in the direction of the arrow shown in the drawing. The moisture supply is constantly maintained in ase,: the gas mixture directly above the liquid level cannot be enriched with air to the extent that absorption would be difficult. In this case, one connecting pipe 21, through which the gas flows from the evaporator to the absorber, can be between the evaporator and the absorber. as indicated by the arrow.

The subject of the patent.

1. The process control method in absorption machines which maintain a higher pressure in the boiler than in the absorber, characterized in that a part of the gas released in the boiler at a higher pressure is blown into the system consisting of the evaporator 9 and the absorber 4, (FIG. 1), in order to force the gas present in the system.

2. Acceptance of the method described in claim 1, characterized in that a part of the gas of higher pressures released in the boiler 8, is connected along the wire 12 to the injector nozzle mounted on the connecting pipe 10 between the evaporator 9 and the absorber 4 s the purpose

forced movement of gas present in this system.

3. Acceptance of the method described in paragraph 1, characterized in that a part of the gas separated in the boiler 2 is diverted directly to the absorber 24 (Fig. 2) through a coil 26 placed behind the partition 25, in order to support in circular motion a gas absorber

FIG.1.

FPG.Z.