MD909Z - Convective heat exchanger - Google Patents

Abstract

The invention relates to convective heat exchangers intended for cooling elements and assemblies of electronic equipment.The convective heat exchanger comprises a housing (1), made in the form of a closed channel, with an ascending part (4) with a heat supply zone (11) in its lower part, and two descending parts (2) with heat removal zones (3) in their upper part. In the ascending part (4) of the housing (1), in the heat supply zone (11), is installed a heat source (5), in the upper part of which are placed in pairs, transversely to the ascending part (4) of the housing (1), emitter electrodes (6) and grounded electrodes (7). In the descending parts (2) of the housing (1), below the heat removal zones (3), is placed one porous partition (9) of dielectric material, in the upper part of which is installed one charge collector (10), each connected to the emitter electrodes (6). The portions of the housing (1) at the level of the porous partition (9) are made of dielectric material (8). The housing (1) is filled with dielectric fluid.

Description

The invention relates to convective heat exchangers intended for cooling elements and nodes of radioelectronic equipment.

The convective heat exchanger used to cool the Roentgen emitter is known, which consists of two main parts - the anode and the cathode, which are under different voltages. The most thermally stressed element, which requires cooling, is the anode. Autonomously, without applying potentials to the anode and cathode, such a heat exchanger cannot function. Both the heat exchanger and the Roentgen emitter connected to it synchronously require an external high voltage source [1].

The disadvantages of this heat exchanger consist in the use of only one pair of electrodes, which allows for very weak convection, and in the use of electrodes with sharp protrusions, which leads to rapid degradation of the dielectric liquid.

The convective heat exchanger is known, which contains a body with heat inlet and outlet areas, wire-shaped electrodes placed in pairs, covered with dielectric material and connected to the negative poles of the voltage source, and uncovered electrodes, connected to the positive poles of the source [2].

The disadvantage of this heat exchanger is the location of the heat inlet and outlet zones. The heat inlet zone is located at the top, and the outlet zone at the bottom. Such a location of the heat inlet and outlet zones completely excludes natural convection. When operating a convective heat exchanger, which operates in a gravitational field, it is necessary to fulfill all the conditions under which natural and electroconvective convection do not compete with each other, but on the contrary, contribute to the intensification of heat exchange. It should also be noted that in this solution, there is practically no swirling of the dielectric liquid immediately above the heat inlet and outlet surfaces. The intensification of the heat transfer process is achieved only at the expense of the flow, developed by two pairs of electrodes, which form a two-stage electrohydrodynamic pump. This exchanger requires an external voltage source, does not generate high electrical voltage and, therefore, can only be useful for cooling high voltage equipment.

The closest solution is the convective electrohydrodynamic exchanger, which contains downward channels with a heat intake area and upward channels with a heat exhaust area, a voltage source and electrode-emitters, connected to the external high voltage source [3].

The disadvantages of this heat exchanger are the need for an external high voltage source, the need for connecting wires and low and high voltage converters. As a result, such heat exchangers are not suitable for use in remote regions.

The problem solved by the present invention consists in creating a convective heat exchanger that does not require an external voltage source.

The convective heat exchanger includes a body, made in the form of a closed channel, with an ascending part with a heat input zone at its bottom, and two descending parts with heat output zones at their top. In the ascending part of the body, in the heat input zone, a heat source is installed, in the upper part of which are placed in pairs, transversely to the ascending part of the body, some emitter electrodes and some electrodes, connected to the ground. In the descending parts of the body, below the heat output zones, a porous partition wall made of dielectric material is placed, in the upper part of which a charge collector is installed, each of which is connected to the emitter electrodes. The portions of the body at the level of the porous partition wall are made of dielectric material. The body is filled with a dielectric liquid.

Other features include the fact that a container with radioactive substances can be used as a heat source, or a portion of the ascending part can be made of transparent material, and a heat accumulator heated by a solar concentrator is used as a heat source. Also, a battery of LEDs can be used as a heat source.

The result of the invention consists in generating high voltage due to the convective movement of the dielectric liquid inside the body and using this voltage to enhance heat transfer.

The invention is explained by the drawing in the figure, which represents the diagram of the convective heat exchanger.

The convective heat exchanger includes a body 1, made in the form of a closed channel, with an ascending part 4 with a heat input area 11 at its bottom, and two descending parts 2 with heat output areas 3 at their top. In the ascending part 4 of the body 1, in the heat input area 11, a heat source 5 is installed, in the upper part of which are placed in pairs, transversely to the ascending part 4 of the body 1, some emitter electrodes 6 and some electrodes 7, connected to the ground. In the descending parts 2 of the body 1, below the heat dissipation areas 3, a porous partition wall 9 made of dielectric material is placed, on top of which a charge collector 10 is installed, each being connected to the emitter electrodes 6. The portions of the body 1 at the level of the porous partition wall 9 are made of dielectric material 8. The body 1 is filled with a dielectric liquid.

The convective heat exchanger works in the following way.

When heat is supplied to the heat supply area 11, the dielectric liquid heats up and rises through the ascending part 4 of the body 1. Since the heat discharge areas 3 are located at the top of the descending parts 2 of the body 1, the dielectric liquid flows into the descending parts 2 of the body 1. The joint action of the heat supply areas 11 and the heat discharge areas 3 creates a continuous circulation of the dielectric liquid inside the body 1. When the dielectric liquid passes through the porous partitions 9 to the charge collectors 10, a high voltage is generated. When connecting the charge collectors 10 with the emitter electrodes 6, the convective and electroconvective flows are summed up, which contributes to increasing the speed of liquid circulation, thus to cooling the heat source 5 and increasing the high voltage at the charge collectors 10. All these three elements - the heat source 5, the heat dissipation areas 3 and the system of emitter electrodes 6 with the electrodes 7 connected to the ground contribute to amplifying convection inside the body 1.

The heat source 5 with radioactive substance can release heat and maintain convection inside the body 1 for a long time, therefore, it can generate a high voltage at the charge collectors 10. Also, when operating such a heat exchanger in the desert, where the sun usually shines during the day, a heat accumulator heated by a solar concentrator can be used as a heat source. In this case, a portion of the ascending part 4 can be made of transparent material. The volume of the heat accumulator is calculated on the condition of maintaining heat at night. This allows the convective heat exchanger to operate during the night. Part of the generated energy can be used for other purposes, for example, for charging the high-voltage capacitor and the transmitter operating in the pulse mode.

Thus, an autonomous convective exchanger is proposed, which does not require an external high voltage source. Such a heat exchanger can be installed even in the desert, where even low voltage energy sources are lacking.

Example

The convective heat exchanger was made of stainless steel pipes. The diameter of the ascending and descending parts was, respectively, 20 mm and 15 mm. The area of each of the two porous partitions 9 with a porosity of 100 µm was 12.5 cm2, and their thickness was 3 mm. The friction force, opposing the movement of the liquid through the pores, was ~0.35 N. Copper rings with diameters of 40 mm and 36 mm, respectively, and a thickness of 8 mm were used as charge collectors 10. Charge collectors 10 were made of a metal grid in the form of cylinders with a diameter of 40 mm. The dimensions of the grid mesh were (1.5x1.5) mm. The diameter of the channel in the section of the porous bodies was 40 mm. The electrodes 7 were made of copper conductors ⌀ 1 mm. The electrodes - emitters 6 were covered with insulating material (enamel). As a heat source 5, an electric burner was used, placed on the surface of the body 1, in the heat input zone 11. In the heat output zones 3, standard radiators with plates for heat output up to 50 W were installed. The contact surfaces of the radiator with the body 1 were greased with a special heat-conducting paste. The distance between the heat input zones 11 and the heat output zones 3 was 450 mm, while the total height of the installation was 550 mm, and the perimeter - 1500 mm.

It should be noted that the high voltage generated by the porous partitions 9 depends on: the velocity of the liquid through the pores, their dimensions, the area and the thickness of the porous partitions.

1. Болога М.К., и др. Electroconvective cooling of high-voltage equipment. Electronic processing of materials. №2, 1985, p. 48-50

2. Zhakin A.I., and others. Study of transition processes and influence of the surface structure of electrodes on heat transfer in a wire EHD heat exchanger. Electronic processing of materials, volume 47, number 3, 2011, p. 55-59

3. MD 577 Z 2012.12.31

Claims (4)

1. Convective heat exchanger, which includes a body (1), made in the form of a closed channel, with an ascending part (4) with a heat inlet area (11) at its bottom, and two descending parts (2) with heat outlet areas (3) at their top; in the ascending part (4) of the body (1), in the heat inlet area (11), a heat source (5) is installed, in the upper part of which are placed in pairs, transversely to the ascending part (4) of the body (1), some emitter electrodes (6) and some electrodes (7), connected to the ground, and in the descending parts (2) of the body (1), below the heat outlet areas (3), a porous partition wall (9) made of dielectric material is placed, in the upper part of which a charge collector (10) is installed, each being connected to the emitter electrodes (6); the portions of the body (1) at the level of the porous partition wall (9) are made of dielectric material (8), at the same time the body (1) is filled with a dielectric liquid. Convective heat exchanger according to claim 1, wherein a container with radioactive substances is used as the heat source (5). 3. Convective heat exchanger according to claim 1, in which a portion of the ascending part is made of transparent material, while a heat accumulator heated by a solar concentrator is used as the heat source (5). 4. Convective heat exchanger according to claim 1, wherein a battery of LEDs is used as the heat source (5).