SU439952A1 - Evaporative Cooling Device - Google Patents

Description

one

The invention relates to the field of radio engineering.

Devices are known for evaporative cooling consisting of evaporative chambers with a capillary nozzle, an injector connected by a pressure cavity to the liquid cavities of the evaporating chambers, and a heat exchanger.

However, the known devices require a certain orientation relative to the direction of the force of gravity and cannot operate in weightlessness.

To increase the efficiency of the device, each of the evaporation chambers is divided into liquid and steam volumes by a capillary septum, the steam volumes of the glowing chambers are connected to the injector nozzle, and the pressure chamber of the injector is connected to its suction cavity through a heat exchanger and additional liquid heat exchangers.

In the drawing given the proposed device.

The device consists of evaporation chambers with a capillary nozzle 1, separated by a partition 2, respectively, into liquid and vapor volumes 3 and 4.

The vapor volumes of 4 all evaporation chambers communicate with each other through the steam pipe 5 with the injector nozzle 6 of the injector 7. The injector has respectively a suction and a pressure cavity 8 and 9 connected by a narrow channel. The volume of the suction cavity 8 is designed so that excess fluid flows into it, displaced by steam from the vapor volumes 4 and the capillary nozzle 1 when the device is started up, the operation mode changes, and from thermal expansion of the liquid. The nipple cavity 9 of the injector is connected to the pipeline 10, which has an I branch, which serves to connect the pressure cavity 9 to the liquid volumes of 3 all evaporation chambers. The heat exchanger 12 heat is connected to the pressure cavity 9 of the injector pipe 10 and

a suction cavity 8 by a pipe 13. On pipelines 10 and 13 connecting the heat exchanger 12 for heat release to the cavities 8 and 9 of the injector, liquid heat exchangers 14 with cooled elements are installed.

The evaporation chamber is placed in appliances having a maximum allowable working temperature, and liquid heat exchangers are designed to cool elements having a temperature below the temperature

boiling fluid.

Nozzle 1 is heated from the heat generated by the elements. The liquid filling the pores of the nozzle evaporates and the steam flows into the vapor volume 4. Due to the capillary potential, the vapor pressure in the vapor volume 4

more fluid pressure in the ion volume 3, but less absolute capillary pressure, and the fluid from the vapor volume 3 flows into the capillaries and replenishes the fluid converted into steam. From the steam volumes 4, the steam flows through the steam line 5 to the nozzle 6 of the injector 7. From the nozzle 6, the steam flows into the neck of the injector between the suction, it and the pressure cavity 8 and 9, respectively, condenses and flows some liquid.

The vapor pressure is converted into pressure, as a result of which the pressure of the fluid in the pressure cavity 9 is greater than the pressure in cavity 8. Part of the liquid from the pressure cavity 9 flows into the pipeline 10, and part through the branch 11 into the liquid volumes of 3 evaporation chambers.

Circulation in the first circuit is due to the capillary potential of the nozzle 1 and due to the conversion of thermal energy of steam in the injector 7. The energy of these sources is spent on overcoming hydraulic resistances.

Capillary potential depends on the type of fluid, the material and structure of the packing, and the temperature. The fluid must have the greatest surface tension, and the pores must have a small diameter. Pressure drop.

generated by the injector 7, depends on the temperature difference between the vapor and the liquid in the throat of the injector and the efficiency of the injector. Circulation in the circuit: the injector 7-heat exchanger 12 occurs due to the pressure difference in the pressure and suction cavities 9 and 8 created by the injector. The liquid passes through the pressure cavity, pressure pipe, heat exchanger, 0 pipe, suction cavity and injector nozzle.

Subject invention

15 A device for evaporative cooling, consisting of evaporation chambers with a capillary nozzle, an injector connected by a pressure cavity to the liquid cavities of the evaporation chambers, and a heat exchanger, characterized in that, in order to increase the efficiency of the device, each of the evaporation chambers is divided into liquid and steam volumes by a capillary partition, the steam volumes of the evaporation chambers are connected to the injector nozzle, and the pressure chamber of the injector is connected to its suction cavity through a heat exchanger and additional liquid heat exchangers.

S

a