SU1204914A1 - Gravity heat pipe - Google Patents

Description

The invention relates to heat transfer devices, namely, to tenl tubes operating in the field of gravity, two-phase thermosyphons.

The aim of the invention is to increase the heat transfer ability.

The drawing shows a gravity heat pipe, longitudinal section.

The gravitational heat pipe contains a vertically located housing 1 with zones 2 and 3 of evaporation and condensation, respectively, the first of which is located in the ground 4. The pipe cavity in zone 2 of the discharge is divided in height into sections that are radially spaced relative to the housing 1 with conical inserts 5 with central holes, and above these inserts, transverse partitions 6 are installed with central openings connected to the central openings of inserts 5 by means of nozzles 7 brought out through the partitions 6 x with the formation between the nozzles 7 and the walls of the housing 1 of the annular collections 8 of the coolant. The annular cavities 9 between the inserts 5 and the transverse partitions 6 are connected to collectors 8 by hydraulic tubes 10, the position of the upper end of which determines the level of the liquid in the collectors 8. Outside of the housing 1 in the condensation zone 3 there is a fins 11.

Evaporation zone 2 in height. Can reach tens of meters. A hood is installed in the form of a system of hollow cones 12 above the nozzle 7 of the uppermost section.

and 13, the upper of which has a smaller transverse size. Between these cones, as well as between the lower cone 12 and the end of the pipe 7, there are gaps for the passage of the coolant vapor.

The gravitational heat pipe operates as follows.

When heat is supplied from soil 4 to housing 1 in zone 2 of evaporation, the coolant evaporates, and its steam passes through nozzles 7 of all sections upwards, to condensation zone 3, where it is condensed when the taggl is removed to the outside, the liquid flows first into the upper collector 8, from which there are liquid heat carrier through overflow

the tube 10 falls on the conical insert 5 and then through the gap between it and the body 1 in the form of a thin film flows down the wall of the body 1 down (partially evaporated when heat is applied to the upper section of the evaporation zone 2) to the next

collection 8, where with the excess heat carrier the same occurs as in the upper collection, etc.

The evaporation of the heat carrier from thin 1-membranes provides high intensity of heat transfer. Collections 8 contribute to the smooth start of the pipe when the heat flux starts to go to the evaporation zone 2. A drip separator prevents condensate dripping from the upper end of the pipe into the vapor stream.

The gravitational heat pipe can be used, for example, to freeze soil to a great depth.

Claims (2)

I. A GRAVITATIONAL HEAT PIPE, comprising a housing and hollow conical inserts with central holes, which are mounted on a belt axis and have a gap relative to the walls, characterized in that, in order to increase the heat contact with its walls, transverse partitions with central holes connected to the holes are additionally installed over the inserts holes in the inserts by means of nozzles brought up through the partitions with the formation with the walls of the housing of the annular collectors of the coolant, and the cavity between the inserts and orodkami communicated to collectors through overflow pipes. 2. The pipe in π. 1, characterized in that in the case above the upper nozzle there is a droplet eliminator in the form of a truncated hollow cone facing upward and placed above it with a gap of a hollow cone with a smaller transverse th