SU853350A1 - Heat pipe - Google Patents

Description

The invention relates to heat exchangers, in particular to thermogravity heat pipes. Heat pipes are known that contain a housing with a horizontally evaporator partially filled with coolant and an insert in the form of a shell and a condenser located above the evaporator 1. Placed in these devices is the impossibility of increasing the specific heat flux compared to boiling in a large volume at low temperatures. , and at high temperatures, the deterioration of hydrodynamic processes. Other heat pipes are also known that contain a vertical body partially filled with a coolant with evaporation and condensation zones and a spring-loaded rod along its axis with a movable element at one end placed in the condensation zone 2. Such heat pipes have the same disadvantages. The purpose of the invention is to intensify heat transfer. This is achieved by the fact that the rod is on the opposite end face. in the evaporation zone, provided with a telescopic spring, and the movable element is designed as a membrane. FIG. 1 shows a heat pipe in its initial state; in fig. 2 the same, with the highest density of the input heat flux. The Teylova tube contains a cylindrical body 1 with a heat-receiving end 2 and a cover 3.. Along the axis of the housing 1 there is a rod 4, provided at one end with a telescopic spring 5, and at the other - with a membrane 6 connected by means of a spring 7 to the lid 3 of the heat pipe. In the area of the membrane 6 installed spacer ring 8. Heat pipe works as follows. When heat is applied to the heat-emission side of end 2, the coolant begins to boil. Vapor bubbles along the interturn space of the telescopic spring 5 are released into the vapor space, while deforming and acquiring an elongated shape instead of spherical, inherent to the bubbles during boiling in a large volume, the condensate returns under the action of gravity and of the channel formed by the Witx spring 5, along the heating end 2. When the heat input increases, the pressure inside the pipe increases, the membrane 6 moves the rod 4 releases the telescopic spring 5, which starts zhimats. Between the end of the heat pipe 2 and the turns of the spring 5 is a clearance. With increasing power all bolschoy number of turns moves away from the end i, freeing space for the heat transfer fluid.

When the heat flow decreases, the pressure inside the pipe decreases, the membrane 6 under the action of the spring 7 moves in the opposite direction and, through the rod 4, presses the turns of the telescopic spring 5 to the heat-receiving end 2.

Artificial deformation of the bubble makes it possible to obtain new active centers of vaporization and to intensify heat exchange.

Claims (2)

1. USSR author's certificate No. 532746, cl. F 28 D 15/00, 1975. 2. USSR author's certificate number 690273, cl. F 28 D 15/00, 1976 (prototype). eight 6 FIG. one