MD533Z - Multistage electrohydrodynamic pump - Google Patents

Abstract

The invention relates to electrohydrodynamic pumps for pumping dielectric liquids.The multistage electrohydrodynamic pump comprises a rectangular housing (5), in which are placed the stages (6, 7) of the pump, where each stage contains two electrodes - emitter (E) and collector (C), made in the form of arrays of parallel-stretched wires. On the wires of the emitter (E) are applied insulation coatings with perforations from the end of collector (C). The perforations of the insulation coating of the emitter (E) are made of a length equal to 0.2…0.5 of the length of wire circumference. On the upper side of the stages on the wires of the collector (C) are applied insulation coatings on 0.2…0.5 of the length of wire circumference. In the insulation coatings of the wires of collector (C) are made perforations in the form of slits, transversely to the wire, on the full length of the insulation coating and with a width of 0.02…0.5 mm. The ratio of the distance between the perforations of the collector (C) to the gap between the emitter (E) and collector (C) of one stage is equal to 0.4…1.0.

Description

The invention relates to electrohydrodynamic pumps for pumping dielectric liquids.

A multistage pump is known, which contains a channel, in which groups of electrodes with three pivots are placed consecutively. Each group consists of a central pivot electrode - emitter with insulating coating and two lateral pivot electrodes - collectors. Insulating coatings are deposited on the electrodes from the channel walls on 50% of the surface of the wires [1].

The disadvantage of this type of multistage pump is that, although it develops a fairly high pressure, productivity is limited.

A multi-stage electrohydrodynamic pump is also known, each stage of which contains two electrodes - emitter and collector, made in the form of grids of wires stretched parallel on a rectangular dielectric support with a certain pitch. On the emitter wires are applied insulating coatings with perforations from the collector side. At the same time, the total pressure of the pump is the sum of the pressures in the interstices between the electrodes of the stages [2].

The disadvantages of this solution are that for such electrode systems, partial neutralization of the charged medium in the pump is characteristic, because the Coulomb interaction with the collector and emitter of the neighboring stage occurs, which is directed against the flow, thus reducing the pressure and the intensity of the discharge.

The problem that the invention solves is increasing the pressure and productivity of the pump.

The multi-stage electrohydrodynamic pump, according to the invention, eliminates the above-mentioned disadvantages by containing a rectangular body, in which the pump stages are located, where each stage contains two electrodes - emitter and collector, made in the form of grids of parallel wires. On the emitter wires, insulating coatings with perforations are deposited from the collector side. The perforations of the insulating coating of the emitter are made with a length equal to 0.2…0.5 of the length of the wire circumference. From the upper part of the stages, insulating coatings are deposited on the collector wires on 0.2…0.5 of the length of the wire circumference. In the insulating coatings of the collector wires, perforations in the form of cuts are made, transverse to the wire, along the entire length of the insulating coating and with a width of 0.02…0.5 mm. The ratio of the distance between the collector perforations to the gap between the emitter and collector of a stage is 0.4…1.0.

An insulating covering of the collector less than 0.2 of the length of the wire circumference leads to an increase in the influence of the uncovered part of the collector, to a decrease in the inhomogeneity of the electric field on its surface and to the electrification of the dielectric liquid and, consequently, to a deterioration in the final characteristics of the multistage electrohydrodynamic pump. An insulating covering of the collector more than 0.5 of the length of the wire circumference leads to a decrease in the uncovered surface on the emitter side, to a decrease in the degree of neutralization of ions with the sign of the emitter potential and the final parameters of the stage and the multistage electrohydrodynamic pump as a whole. Increasing the width of the perforations of the insulating coverings over 0.5 mm leads to a decrease in the inhomogeneity of the electric field on the surface of the electrodes and the degree of electrification of the working medium, to a decrease in the pump productivity. Analogous regularities are observed when the ratio of the distance between the collector perforations to the gap between the emitter and the collector of a stage decreases, i.e. below 0.4. When the ratio of the distance between the collector perforations to the gap between the emitter and the collector of a stage increases, i.e. above 1.0, the mutual influence of the electrohydrodynamic flows, which occur at each perforation, decreases, areas of recurrent flows are formed (directed against the main flow from the emitter to the collector) and, consequently, the pump productivity is reduced.

In order to increase the pressure and productivity of the separate stages, the perforations at the emitter are made as at the collector, but with a length equal to 0.2…0.5 of the length of the wire circumference.

At a length of the emitter perforations over 0.5 of the wire circumference length, the influence of Coulomb forces increases, which act on ions with the sign of the emitter potential in the direction of the collector of the neighboring stage, opposing resistance to the main flow of the working agent. In the case of the emitter perforations length below 0.2 of the wire circumference length, the instability of the electrohydrodynamic flow characteristic of pronounced asymmetric electrodes (needle-ring) increases, the influence of flows occurring at the perforations of neighboring wires of the emitter decreases, the intensity of recurrent flows increases and the pump productivity decreases. The application of the insulating coating with perforations ensures the operation of the pump at electric field intensities closer to the breakthrough values than in the case of pronounced asymmetric electrodes (needle-ring).

The invention is explained by the drawings in Fig. 1-3, which represent:

- Fig. 1, electrodes (a - in axonometric view; b - in section);

- Fig. 2, general view of the multistage electrohydrodynamic pump;

- Fig. 3, the dependence of the pressure on the voltage applied to the electrodes and the distance between the steps.

The multistage electrohydrodynamic pump contains a rectangular body 5 made of organic glass, in which the pump stages 6, 7 are located, where each stage contains two electrodes (Fig. 1) - emitter E (E1 - emitter of the first stage 6, E2 - emitter of the second stage 7) and collector C (C1 - collector of the first stage 6, C2 - collector of the second stage 7) (Fig. 2), made in the form of grids of wires stretched parallel on a support. On the wires of the emitter E are deposited insulating coatings 1 (Fig. 1) with perforations 4 from the collector C side. The perforations 4 of the insulating coating 1 of the emitter E are made with a length L2 equal to 0.2…0.5 of the length of the wire circumference (πd2, where d2 is the wire diameter). From the upper part of the floors, insulating coatings 2 are applied to the wires of the collector C over 0.2…0.5 of the length of the wire circumference. In the insulating coatings 2 of the wires of the collector C, perforations 3 are made in the form of cuts, transverse to the wire, over the entire length of the insulating coating 2 and with a width L1 of 0.02…0.5 mm. The ratio of the distance between the perforations d1 of the collector C to the gap d (Fig. 2) between the emitter E and the collector C of a floor 6, 7 is 0.4…1.0.

The multistage electrohydrodynamic pump operates in the following mode.

When applying an electric field between the electrodes, in each stage 6, 7, electrification of the working medium occurs, the degree of which depends on the inhomogeneity of the electric field at the surface of the electrodes. Therefore, electrification of the dielectric liquid is more intense at the perforations 4 of the insulating coating 1 of the emitter E than at the uncovered surface of the collector C. At the same time, these processes largely depend on the parameters of the perforations 3, 4, the optimal proportion of which is indicated above. As a result, charges (ions) with the sign of the emitter potential E are formed in the working medium, which under the action of Coulomb forces move towards the collector C, entraining the neutral molecules of the medium and ensuring the pressure and flow rate of the pump. Some of the ions are neutralized at the collector C, but a large part, together with the flow, are moved outside the gap d between the emitter E and the collector C. Coulomb forces are created from the collector C1 of the 6th stage and the emitter E2 of the neighboring 7th stage, directed countercurrently, which worsens the final characteristics of the multistage electrohydrodynamic pump. The deposition of the insulating coating 2 with perforations 3 on the collector C1 of the stage 6 from the side of the emitter E2 of the neighboring stage 7 contributes to the intensive formation outside the gap d of charges with the sign of the collector potential C, which partially recombine with the ions removed from the gap d, and the remaining ones move under the action of Coulomb forces in the direction of the emitter E2, creating additional pressure and discharge of the working agent, which allows to reduce the distance L between the stages 6, 7 to the size of the gap d in the stage, leading to an increase in pressure and flow rate, to a reduction in the geometric parameters of the pump.

In Fig. 3 the dependence of the static pressure of the two-stage pump with electrodes, on the wires of which insulating coatings with perforations are deposited, on the voltage applied to the electrodes at different distances between the stages is shown. Curve 1 (Fig. 3) corresponds to the distance between the stages L=47.7 mm, at which, according to the results obtained previously from the closest solution, the mutual influence of the stages is practically absent. As the distance between the stages decreases to L=2.7 mm (compared to the gap d=2 mm), the pressure increases by 70…80% (curve 2, Fig. 3) and, accordingly, the pump productivity, in contrast to the data obtained in the closest solution. This demonstrates the effectiveness of using insulating coatings with perforations with the mentioned parameters in order to improve the final characteristics of the multistage electrohydrodynamic pump.

The multistage electrohydrodynamic pump can be used in the electronics and electrical engineering industry, for pumping and creating pressure of working agents in convective heat exchangers, in heat pipes, in high voltage transformers, in electrohydrodynamic separators, etc.

1. SU 1195876 A 1984.05.14

2. Болога М. K., Kozhevnikov I. В. The influence of the electric field and the arrangement of stages on the characteristics of the multistage pump. Electronic processing of materials, 2009, p. 64-67

Claims (1)

Multi-stage electrohydrodynamic pump, which contains a rectangular body, in which the pump stages are located, where each stage contains two electrodes - emitter and collector, made in the form of grids of parallel wires, on the emitter wires being deposited insulating coatings with perforations from the collector side, characterized in that the perforations of the emitter insulating coating are made with a length equal to 0.2…0.5 of the wire circumference length, at the same time from the upper part of the stages on the collector wires are deposited insulating coatings on 0.2…0.5 of the wire circumference length; in the insulating coatings of the collector wires, perforations are made in the form of cuts, transverse to the wire, along the entire length of the insulating coating and with a width of 0.02…0.5 mm; the ratio of the distance between the collector perforations to the gap between the emitter and collector of a stage is 0.4…1.0.