SU1672192A1 - Centrifugal thermal pipe - Google Patents

Abstract

The invention relates to heat engineering, in particular to centrifugal heat pipes, which are used to remove heat from the rotor of an electric machine. Improving the operational reliability of a heat pipe, one of the condensation zones of which is an auxiliary, and in the presence of non-condensing gas in it, is achieved by placing transverse partition 5 at the boundary of the auxiliary condensation zone 4 and evaporating zone 3 for the passage of non-condensing gas. 1 hp f-ly, 2 ill.

Description

1

 N

The invention relates to heat engineering, cooling systems, and centrifugal heat pipes, which are used, for example, to remove heat from the rotor of an electric machine.

The purpose of the invention is to increase the operational reliability of the heat pipe, one of which condensation zone is a pregroupglum, and in the presence of noncondensing gas as well.

FIG. 1 schematically shows the proposed pipe; in fig. 2 shows section A-A in FIG. one.

The pipe consists of a cylindrical body 1, hermetically sealed, partially filled with coolant, with the main condensing youth 2, evaporating zone 3 and auxiliary zone 4. In the inner cavity of the teggy tube at the border, waiting for t from the pi pi eluy 3 and ancillary tn n epatsiin - This A is located on the crossbar 5, made in the form of a disk with radial fixing points 6, Between the heat supply pnufeing surface of the pipe - wall 7 and a finger (caustic slotted) windows 8.

Centrifugal heat pipe works as follows

When the pipe rotates, the coolant is distributed by centrifugal forces with a thin layer on the inner surface of its housing 1. When heat is supplied to the evaporation zone 3, the coolant evaporates, steam enters both condensation zones 2, 4 and condenses there. Condensate by centrifugal forces returns to the evaporation zone 3. Light steam containing non-condensing gas, such as hydrogen, enters both condensation zones along with steam and here tends to concentrate along the splicing axis. However, in the main condensation zone 2, the vapor flow due to diffusion blurs the accumulated non-condensing vapor gas and this gas is returned to the steam flow. In the auxiliary condensation zone 4, the partition 5 is preferred.

the interaction of a cloud of gas concentrating at the axis of rotation with the flow of steam entering this zone prevents the cloud from spreading along the axis into the evaporation zone 3. In this zone the gas does not return to the flow of steam As a result, after some time, all the gas in the pipe it turns out in the cavity of the auxiliary condensation zone A and the heat transfer in the rest of the pipe goes on a clean pair.

Thus, the proposed heat pipe works effectively in the presence of a light non-condensing gas in it, for example, hydrogen. This makes it possible to use water in the steel heat pipe as a heat carrier, which is a good heat carrier in the temperature range 100–200 ° C.

 f Fictitious heat transfer, as well as in terms of environmental technology, accessibility, and so on.

In a heat pipe, made in the form of a hollow shaft of an electric machine, the role of the subsidiary condensation zone1 4 plays the leading end of the shaft, and the function of the external heat source is the coupling half, through which the machine is connected to a rotatable mechanism

Claims (1)

Claim 1. Centrifugal heat pipe, comprising a housing partially filled with coolant, with an evaporation zone in the center and with condensation along the periphery, characterized in that, for the purpose of DIFFERENCE operational reliability of the heat pipe, one of the condensation zones of which is with an auxiliary, and the presence of non-condensing in it. “For, on the border of the auxiliary condensation zone on the side of the evaporation zone, there is additionally installed a transverse partition with radial fastening tabs forming With the inner surface of the housing profiled windows. 2 Trumpet pop.1. from l and h and u; and with the fact that the partition is made about the form of a disk. FIG. 2