SU787868A1 - Heat transfer apparatus - Google Patents

Description

one

The invention relates to heat engineering, in particular to heat transfer devices with pulsating heat pipes, and can be used in various technical fields in transmitting a tail for a considerable distance.

A heat transfer device is known, which contains two identical pulsating heat pipes with evaporation and condensation zones at opposite ends connected by means of two pipelines connected at one end to the condensation end of the corresponding pipe 1.

In the known device, each of the pipes is designed as a system of parallel channels, the ends of which are connected in the evaporation and condensation zones, respectively, to the steam and liquid collectors, both liquid collectors are connected to the closed circulation loop by symmetrically relative to the axis of the latter and under ocTptJM angle to it, a part of the contour, preconnected by pressure tubes, is divided into two parallel branches with a casing in each of them, in which there is a condensation zone and a liquid call the vector of the corresponding pipe, and the circuit is additionally equipped with a heat exchanger-cooler.

Such a design requires high precision manufacturing of the heat pipe connecting unit to the circulation circuit to ensure reliable operation of the device.

The purpose of the present invention is to simplify the design while simultaneously. increase reliability.

This goal is achieved. A vapor-liquid ejector with a working nozzle and a diffuser facing the evaporation and condensation zones, respectively, and a receiving chamber, to which the second end of the corresponding pipeline is connected, is installed in each pipe between the evaporation and condensation zones.

FIG. 1 schematically shows a device; in fig. 2 - the same and-working position.

25 The heat transfer device contains two identical heat pipes 1 and 2 with evaporation zones 3 and 4 and condensation zones 5 and 6, respectively. Pipes 1 and 2 are interconnected with

30 using piping 7 and 8, connected at one end to the ends of the condensation zones 5 and 6, respectively. In pipes 1 and 2, vapor-liquid ejectors 9 and 10 are installed, respectively, each of which has working nozzles 11 and 12 facing the evaporation zones 3 and 4, diffusers 13 and 14 to the condensation zones 5 and 6, and second pipe ends 7 and 8 respectively.

The device works in the following way.

When heat is applied to the evaporation zones 3 and 4 and heat removal from the condensation zones 5 and b, each of the pipes 1 and 2 operates in a pulsed mode, while the pressure increase in the evaporation zone 3 of the pipe 1 corresponds to a decrease in pressure in the evaporation zone 4 of the pipe 2 and vice versa. During boiling of the coolant in zone 3 of evaporation of the pipe 1; The vapor pressure rises, as a result of which the steam flow through the ejector 9 rushes to the condensation zone 5, which condensate from the pipeline 7 is pushed into the receiving KciMepy of the ejector 10 and further to the evaporation zone 4 of the pipe 2. At that time, the condensate enters from the pipeline 8 through the condensation zone 6 of the pipe 2 into the diffuser 14 of the ejector 10 and then injected into the evaporation zone 4. In the condensation zone 5, the vapor condenses, the pressure in the pipe drops and then the cycle repeats in the opposite direction.

As a result of the described processes, the coolant is circulated in a closed loop.

Thus, the heat transfer device described above is simpler in terms of design and technology, requires much less investment for industrial implementation and lower operating costs, and is highly reliable compared to similar known devices.

Claims (1)

1. USSR author's certificate No. 635386, cl. F 28 D 15/00, 1977. 9orr, 8. figure 1 QomS. .l