SU1270507A1 - Heat pipe evaporaing chamber - Google Patents

Abstract

I. EVAPORATIVE HEAT PIPE CAMERA operating in the field of gravity under conditions of various orientations, comprising a housing with a condensate conductor at the end and installed in contact with the lateral surface of the housing a capillary-porn cylindrical nozzle plugged from one end and having a condensate conductor side central notch, and along the perimeter - longitudinal grooves connected to the steam collector, characterized in that, in order to increase the amount of supplied heat flux, the casing is made with screw threading internal side surface, and the nozzle with a plugged end is installed in contact with the end surface of the body, equipped with a ring system and. radial grooves communicated in the same way as screw grooves through the longitudinal grooves of the nozzle with the steam manifold, while the notch in the nozzle is made tapering in the direction of its plugged end. 2. The camera according to claim 1, characterized in that (L that the tops of the screw thread from the side of the nozzle have a cut. I rj Yu o

Description

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And iufipfTtMine related to heat engineering ti can be used to remove heat or elements of electronic equipment TVjibi.

AND; iest;) a tenl tube evaporation chamber, comprising a housing with a capillary RIo-1 mounted inside it, with a central nozzle fitted with a central recess and a cross-section of radial and radial grooves on the outer surface acting as steam discharge channels 11.

A vaporization chamber of a heat pipe is known, comprising a housing with a capillary-porous nozzle, provided with a central recess in the form of two truncated cones united by smaller bases (2.

The disadvantage of these structures is the impossibility of their use in the case when one of the end surfaces of the chamber is subjected to heat load.

Also known is an evaporation chamber of a heat pipe operating in a field of gravity under conditions of different orientations, comprising a housing with a condensate line at the end and installed in contact with the side surface of the housing of a capillary-Tyrio cylindrical nozzle plugged from one end and having a condensate line central notch, and along the perimeter - longitudinal grooves connected to the steam collector 3).

The disadvantage of this design is that when syudvod heat load not only to the side surface of the evaporation chamber, but also to its end there will be no effective heat removal from the end, because the nozzle does not have direct contact with it.

The purpose of the invention is to increase the value of the supplied heat flux.

This goal is achieved by the fact that the evaporator chamber of a heat pipe operating in a gravity field under conditions of different orientations contains a case C with a condensate line at the end and installed in contact with the side surface of the case a capillary-porous cylindrical nozzle plugged from one end and having from the side of the condensate line there is a central recess, and along the perimeter there are longitudinal grooves connected to the steam collector, the casing being screwed on the inner side surface, and the nozzle behind The flat end face is installed in contact with the face surface of the body, equipped with a system of annular and radial grooves, communicated in the same way as the screw grooves through the longitudinal grooves of the nozzle with the steam manifold, while the notch in the nozzle is narrowed in the direction of its muffled end, and the helical slicing from the nozzle have a cut

Phi | -.1 presents an example of the layout of a heat pipe with an evaporation chamber of a prototype and a sealed unit; figure 2 - the same with the proposed camera; on fig.Z - the proposed camera, a longitudinal section; figure 4 - section aa on fig.Z; figure 5 - node I in fig.Z; figure 6 is a cross section of the end of the camera with a system of grooves.

Heat pipe evaporation chamber 1

It contains a housing 3 with a condensate duct 4 at the end 5 and a capillary-porous cylindrical nozzle 6, plugged from one end 7 and having a central recess 8 on the side of the condensate duct 4, and longitudinal grooves 9 around the perimeter.

5 this housing 3 is made with a screw thread 10 on the inner side surface, and the nozzle 6 is installed in contact with both the side and the end surface 11 of the housing 3, and the end surface 11 is equipped with a system of annular and radial grooves 12 and 13, respectively, forming together with longitudinal grooves 9 of the nozzle 6 and grooves 14 of the screw thread 10 steam discharge channels communicating with the steam collector 15.

The proposed camera works as follows.

When the heat flux is supplied to the side and end surfaces of the chamber, evaporation of the heat transfer medium from the nozzle 6 coming from the recess 8, which can be performed, for example, in the form of a truncated cone, begins.

The resulting steam through the vapor channels formed by the longitudinal grooves 9 of the nozzle 6, the grooves 14 of the screw thread 10 and the system of grooves 12 and 13 on

the end face 11 of the chamber enters the steam manifold 15, from where it is removed by the steam line.

Since the nozzle is in contact with the side and end surfaces of the evaporation chamber, heat is removed from them equally efficiently. The proposed arrangement of the nozzle in the housing allows an increase in the surface of the evaporation zone and, consequently, an increase in the power of the supplied heat flux.

Making a notch in the nozzle tapering in the direction of its plugged end makes it possible to increase the thermal resistance of the nozzle in the part where the formation of a vapor bubble capable of blocking part of the absorbency is most likely. However, even if such a bubble is formed, the shape of the notch will allow it to float to the most cold end part of the chamber, where it will condense.

Placing the main part of the steam duct on the body of the chamber allows the capillary-porous material to undergo minimal mechanical processing during the manufacture of the nozzle, which reduces the requirements for its strength characteristics and, consequently, increases the porosity and permeability of the nozzle, which determine the capacity of the heat pipe.

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Claims (2)

I. EVAPORATION CAMERA OF A HEAT PIPE operating in the field of gravity in different orientations, containing a housing with a condensate pipe at the end and installed in contact with the side surface of the housing, a capillary-porous cylindrical nozzle plugged at one end and having a central recess on the side of the condensate pipe , and along the perimeter - longitudinal grooves connected to the steam manifold, characterized in that, in order to increase the amount of heat input, the body is made with screw thread on the inside its lateral surface, a tip end plugged installed in contact with the end surface of the housing and provided with a ring system. radial grooves, communicated in the same way as screw grooves through the longitudinal grooves of the nozzle with a steam collector, while the recess in the nozzle is made tapering in the direction of its muffled end. 2. Camera by π. 1, characterized in that the vertices of the screw threads from the nozzle side have a slice. Fig /