MD911Z - Convective electrostatic generator - Google Patents

Abstract

The invention relates to the field of electrohydrodynamics, namely to convective electrostatic generators and may be used for power supply in different technological processes that require the use of high voltage and low currents.The convective electrostatic generator comprises a housing (1), made in the form of a closed channel, with an ascending part (2) with a heat supply zone (3) in its lower part, and a descending part (4) with a heat removal zone (5) in its upper part. In the descending part (4) of the housing (1), below the heat removal zone (5), is placed a porous partition (6), made of dielectric material, in the upper and lower part of which are installed electrodes (7), connected by means of high-voltage terminals (10 ) to output terminals (9). The portion of the housing (1) at the level of the porous partition (6) is made of dielectric material (8). The housing (1) is filled with dielectric fluid (11).

Description

The invention relates to the field of electrohydrodynamics, namely to convective electrostatic generators and can be used for power supply in various technological processes, which require the use of high voltage and low currents.

Several technological processes are known that use electrostatic energy. They are described in detail in the manual "Electrostatics in Technology", F. Tenesescu, R. Kramaryuk, Moscow, Energiya, 1980, 296 p.

The realization of such processes in the autonomous version is practically impossible. A power transmission line and a device for converting electromagnetic energy into electrostatic energy are required. In autonomous mode, a conventional heat source can be used to obtain electrostatic energy with the proposed device. In the simplest version, electrostatic energy can be converted into light using LEDs to illuminate, for example, a tourist tent, or it can be used in electrostatic pumps, or in electrohydrodynamic heat exchangers, such as heat pipes, in which electrostatic energy is used to enhance heat and mass exchange.

The heat tube with an electrohydrodynamic generator is known, which includes an evaporator, a condenser and an electrohydrodynamic convector of the energy of the vapor flow of the thermal agent into electrical energy with an ionizer, an exciter and a collector, at the same time the electrohydrodynamic convector is made in the form of a nozzle of bimetallic plates covered on the vapor flow side with a dielectric, and between the collector and the ionizer a high voltage regulator transformer is included, which serves the exciter [1].

The disadvantage of this heat tube is the inefficiency of obtaining electrostatic energy, because vapor energy is transformed into electrostatic energy.

The heat tube with an electrohydrodynamic generator is known, which includes a collector equipped on the periphery with a metallic cylinder, wrapped with a layer of dielectric material, and an electret is used as a dielectric to cover the bimetallic plates [2].

The disadvantage of this heat tube is the ineffective conversion of vapor energy into electrostatic energy.

The electrostatic generator is known, which contains a pump, a piping system and a body, in which porous plates are placed [3].

The disadvantage of this generator is the need for a pump to use the thermal energy.

The closest solution is the electrostatic generator with multiple thermotubes, which contains a body filled with liquid dielectric, with heat inlet and outlet areas, and a porous partition wall made of dielectric material with electrodes [4].

The disadvantage of this generator is that the main part of the thermal energy is used to evaporate the liquid dielectric and transport it to the condensation zone.

A negligible part of the potential energy of the condensate passing through the proposed body participates in obtaining electrostatic energy. Enormous thermal consumptions, directed to the evaporation of the heat carrier, strict requirements regarding the level of sealing of the body make high-voltage generators of this type expensive to manufacture and high energy consumers. High requirements for the level of sealing of the body and the need to blow and remove air from it, increase the requirements for its operation. If the air is not removed, then in the thermal tube it blocks the condensation zone, the vapors do not reach the condensation zone and, consequently, the dielectric liquid that flows through the porous body is not formed. The porous partitions are made coaxial and along their entire length are equipped with perforations, which allows a part of the condensate to flow through the perforations without participating in the energy conversion.

High-voltage generators based on the convective principle are much simpler and have lower energy consumption, because heat is not dissipated during phase transformations (evaporation), but only during the formation of convection. The dielectric liquid does not need to be raised to a certain height, because the entire body (not just a part of the body) is continuously filled with dielectric liquid. Even an insignificant temperature difference in the ascending or descending part leads to the movement of the liquid heat carrier through the porous partition. Heat in the convective generator is consumed only during the circulation of the dielectric liquid and is not consumed during its evaporation.

The problem solved by the present invention consists in considerably reducing the consumption of thermal energy in the process of producing electrostatic energy.

The convective electrostatic generator includes a body, made in the form of a closed channel, with an ascending part with a heat inlet zone at its bottom, and a descending part with a heat outlet zone at its top. In the descending part of the body, below the heat outlet zone, a porous partition wall is located, made of dielectric material, at the top and bottom of which electrodes are installed, connected by means of high-voltage terminals to output terminals. The portion of the body at the level of the porous partition wall is made of dielectric material. The body is filled with a dielectric liquid.

Other features include the fact that the porous dielectric material partition wall is made of sintered glass particles, and the organosilicone liquid, for example, polyethyl or polymethyl organosilicone liquid, is used as the dielectric liquid.

The result of the invention consists in obtaining high voltage from low-level thermal energy in a relatively short period of time.

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

The convective electrostatic generator includes a body 1, made in the form of a closed channel, with an ascending part 2 with a heat inlet zone 3 at its bottom, and a descending part 4 with a heat outlet zone 5 at its top. In the descending part 4 of the body 1, below the heat outlet zone 5, a porous partition wall 6 is located, made of dielectric material, at the top and bottom of which electrodes 7 are installed, connected by means of high-voltage terminals 10 to output terminals 9. The portion of the body 1 at the level of the porous partition wall 6 is made of dielectric material 8. The body 1 is filled with a dielectric liquid 11.

The convective electrostatic generator operates in the following way.

When heat is supplied to the heat input area 3, the dielectric liquid 11 heats up and rises through the ascending part 2 of the body 1. Since the heat discharge area 5 is located at the top of the descending part 4 of the body 1, the dielectric liquid 11 flows into the descending part 4 of the body 1. The joint action of the heat input areas 3 and the heat discharge areas 5 creates a continuous circulation of the dielectric liquid 11 inside the body 1. At a weighted heat load in the heat input areas 3 and the heat discharge areas 5, the temperatures in the ascending parts 2 and descending parts 4 of the body 1 stabilize, maintaining a higher temperature in the ascending part of the body 1 and a lower temperature in the descending part 4 of the body 1. When the dielectric liquid 11 passes through the porous partition wall 6, made of dielectric material, charge separation. Charges of different polarity accumulate on opposite surfaces of the porous partition wall 6, which leads to the appearance of a high voltage at the electrodes 7, installed in the upper and lower parts of the porous partition wall 6. Unlike the closest solution, in the convective generator each drop of the dielectric liquid passes through the porous partition wall 6 and participates in the energy conversion. Due to the high-voltage terminals 10, the electrostatic energy is transmitted to the output terminals 9, after which it can be used for technological needs. The proposed convective generator can be used to power electrohydrodynamic heat pumps and tubes, in technological processes, where high voltage and small electric currents are required.

Example

The body 1 of the generator was made of stainless steel pipes. The diameter of the ascending 2 and descending 4 parts of the body was, respectively, 15 mm. The surface of the porous partition wall 6 (with a porosity of 100 µm) was 12.5 cm2, and the thickness - 3 mm. At the same time, the friction force, opposed by the porous structure to the liquid, was ~0.35 N. As electrodes 7, copper rings with outer and inner diameters of 40 mm and, respectively, 36 mm, and a thickness of 8 mm were used. The electrodes 7 are made of a metal grid with a diameter of 40 mm (the dimensions of the grid mesh were (1.5x1.5) mm) equal to the diameter of the porous partition wall 6. The size of the body 1 in the places of placement of the porous partition is ⌀ 40 mm. As a heat source 5, an electric burner was used, located on the outer surface of the body 1, in the heat input zone 3. In the heat output zone 5 on the outer side of the body 1, a standard radiator with plates for heat output up to 30 W was installed. The contact points of the radiator heater surface with the body 1 were lubricated with a special heat-conducting paste. The distance between the levels of the heat input zones 3 and 5 was 450 mm, while the total height of the generator was 520 mm, and the perimeter - 1350 mm. It should be noted that the high voltage potential generated by the porous structure depends on the speed of the dielectric liquid, the pore size, the surface area and the thickness of the porous partition wall 6.

1. SU 706672 1979.12.30

2. SU 883643 1981.11.23

3. SU 66073 1940.12.16

4. RU 2376698 C1 2009.12.20

Claims (3)

1. Convective electrostatic generator, which includes a body (1), made in the form of a closed channel, with an ascending part (2) with a heat intake area (3) at its bottom, and a descending part (4) with a heat exhaust area (5) at its top, also in the descending part (4) of the body (1), below the exhaust area (5), a porous partition wall (6), made of dielectric material, is placed, at the top and bottom of which electrodes (7) are installed, connected by means of high voltage terminals (10) with output terminals (9), and the portion of the body (1) at the level of the porous partition wall (6) is made of dielectric material (8), the body (1) being filled with a dielectric liquid (11). Convective electrostatic generator according to claim 1, wherein the porous dielectric partition (6) is made of sintered glass particles. 3. Convective electrostatic generator according to claim 1, wherein the organosilicon liquid, for example polyethyl or polymethyl, is used as the dielectric liquid (11).