SU974089A2 - Heat pipe - Google Patents

Description

The invention relates to heat engineering and can be used to cool high-voltage electronic equipment.

According to the main author. St. 587310 a heat pipe is known, containing the main and auxiliary evaporation and condensation zones and the transport zone, the lower part of the transport zone being connected by means of a pipeline to an auxiliary evaporation zone remote from the auxiliary condensation zone of the capillary-porous membrane fl.

The disadvantage of such a heat pipe is the low ultimate heat load.

The purpose of the invention is to increase the ultimate heat load.

This goal is achieved due to the fact that the transport zone is equipped with annular electrodes and capacitive sensors located in the zone of action, connected to a high-voltage current source through a control unit, and the capacitive sensors are shifted in the direction of the auxiliary condensation zone.

FIG. 1 schematically shows a heat pipe; FIG. 2 - part of the transport zone of the pipe.

The heat pipe contains the main zones of evaporation 1 and condensation 2, transport zone 3 and auxiliary zones 4 and 5, respectively, evaporation and condensation. The main 1 and auxiliary 4 evaporation zones are separated from the auxiliary condensation zone 5 by capillary-porous membranes b and 7, respectively. The lower part of the transport zone 3 is connected

15 by means of a pipeline 8 with an auxiliary evaporation zone 4, and at the connection point the pipeline 8 is provided with a nozzle 9. The main 1 and the auxiliary 4 evaporation zones have

20 capillary-porous coating 10. In addition, the pipe contains a high-voltage current source 11 with a control unit 12, and the transport zone 3 is provided with ring electrodes 13

25 and capacitive sensors 14 located in the zone of the latter, connected to the high-voltage current source 11 through the control unit 12.

Heat pipe works as follows

30 way.

When energy is supplied to zones 1 n 4, evaporation of the coolant from the capillary-top coating 10 occurs. The resulting steam moves the main evaporation zone 1 to the main condensation zone 2, where it condenses and the condensate enters transport zone 3, and steam from the auxiliary zones 4 through pipe 8 through nozzle 9, and in the transport zone 3 O, a vapor-liquid mixture is formed.

The bubbling bubble, the passage through the sensor sensor 14 and the electrode 13, causes a high voltage at the latter, and since an electrostatic head acts on the bubble, the bubble moves much faster. After the steam bubble passes, the electrode 13 is automatically switched off.

Thus, the frequency of separation of the bubble from the nozzle 9 automatically sets the speed of the traveling wave potential. The displacement of the capacitive sensor 14 allows the electrode 13 to be turned on only 25 when the vapor bubble passes a large part of the zone of action of this electrode 13, which leads to a directional movement of the vapor-liquid mixture towards the auxiliary condensation zone 5.

Thus, the invention makes it possible to pump the vapor-liquid mixture during operation of the heat pipe against gravity to a great height and, by accelerating the movement of this mixture, to increase the limiting heat load.

Claims (2)

1. Heat pipe according to ed. St. W 587310, characterized in that, in order to increase the ultimate thermal load, the pipe further comprises a high-voltage current source with a control unit, and the transport zone is equipped with annular electrodes and the last capacitive sensors located in the zone of action, connected to the high-voltage current source through the control unit . 2. A pipe according to claim 1, characterized in that the capacitive sensors are displaced in the direction of the auxiliary condensation zone. Sources of information taken into account in the examination 1. USSR author's certificate 587310, cl. , F 28 D 15/00, 1976. } P fj