SU953260A2 - Electric pump - Google Patents

Description

The invention relates to a pump engineering industry, relates to electric pumps.

According to the main auth. No. 900049 is known for an electric pump comprising a housing with, at least one, installed in it, one pair of electrodes isolated from each other, made in the form of two installed concentrically and with a gap of perforated cylinders, the electrodes provided with openings for supplying liquid and connected by coaxial magnesium ; with the conductor of the high-frequency electromagnetic oscillator. In this case, the ratio of the diameter of the perforations to the length of the electromagnetic wave in the liquid is not pre-. is 0.1 ij.

A disadvantage of the known pump is that the polar components contained in large quantities in highly viscous liquids are deposited on the perforations of the cylinders of the electrodes, thereby reducing their working section.

In this case, to obtain the required intensity of pumping liquids, additional electromagnetic energy must be supplied to the electrodes, which is lost to heat the fluid in the interelectrode gap. All this reduces the efficiency of the pump.

The aim of the invention is to improve the efficiency of the pump.

This goal is achieved by the fact that the pump is additionally equipped with an annular acoustic emitter installed coaxially to the electrodes and an ultrasonic generator to which the emitter is connected. .

In this case, the emitter can be made in the form of a piezoelectric transducer.

The drawing shows the proposed pump.

Claims (2)

A pair of insulators 2 and 3 of electrodes 4 and 5, insulated 2 and 3, arranged in the form of two perforated cylinders arranged concentrically with a gap, is installed in the pump casing 1. The electrodes 4 and 5 have perforations b for the passage of liquid and are connected by a coaxial magnetic circuit 7 to a generator of 8 high-frequency electromagnetic oscillations. The housing 1 has a nozzle 9 for the supply and a nozzle 10 30 for removal of the pumped medium. In case 1, an annular acoustic emitter 11 connected to a sound generator 12 is installed coaxially to electrodes 4 and 5. To prevent contact with the pumped medium, emitter 11 is covered from the inside with a layer of insulator 13, for example, with epoxy resin. The emitter 11 can be. You are filled in the form of a piezoceramic transducer, on the inner and outer surfaces of which are applied. respectively metallized. the covers 14 and 15, to the first of which the generator 12 is connected directly, and to the second through the ground. The diameter of the perforations 6 is chosen because its relation to the length of the electromagnetic wave in the liquid does not exceed 0.1. The pump is filled with the pumped liquid . Thereafter, electromagnetic energy is supplied to electrodes 4 and 5 from generator 8 of high-frequency electromagnetic oscillations along a coaxial magnetic conductor 7. Between the electrodes 4 and 5 a non-uniform high-frequency electromagnetic field is created, due to which non-uniform heating of the fluid in the interelectrode gap is carried out. At the same time, near the central electrode 4, where the electromagnetic energy density is higher due to a decrease in the electrode area, the heating is more intense. As a result of this heating of the fluid, its viscosity decreases, mobility increases, as well as hydrodynamic resistances on the electrodes decrease and an inhomogeneous change in the dielectric properties of the fluid between the electrodes 4 and 5. This results in the interaction of the fluid with the electromagnetic field of the capacitor forces and, as a result , to the occurrence of a pressure differential between the electrodes 4 and 5. Under the action of this pressure differential, the liquid from the inlet 9 of the inlet flows through the holes b of the electrode 5 into the interelectro projectile loader gap, and then through the holes used in the electrode 4 is eliminated to the nozzle 10 retraction and further to the consumer in the process of pumping fluid in the gap between the electrodes occurs demulsification pumped liquid, and also decrease the temperature of onset of crystallization of paraffins contained in the pumped liquid, for example oil. The indicated ratio of the diameter of the holes b and the length of the electromagnetic wave in the liquid ensures the smallest losses due to the emission of electromagnetic energy through the branches of the electrodes 4 and 5. When pumping viscous liquids along the edges of the holes 6, large quantities of these fluids can be deposited pnye components, and the flow area of the holes b will be reduced, which will increase the hydrodynamic resistance, and will increase the additional thermal and thermal effects of undesirable phenomena. Therefore, in the proposed pump, the acoustic field created by the emitter 11 when the ultrasonic generator 12 is turned on is superimposed on the pumped liquid. Ultrasonic acoustic oscillations in the liquid cause a breakdown of the polar components adsorbed on the perforations, creating an additional pressure gradient in the interelectrode gap, contributing to pumping liquid, and also leads to additional demulsification of the pumped liquid and additional decrease in temperature Atura onset of crystallization of paraffins contained in the pumped liquid. Thus, the proposed technical means achieves an increase in the intensity of fluid pumping, an increase in pump capacity, a reduction in the cost of preparing oil-water emulsions and the possibility of pumping paraffinic liquids. All this increases the efficiency of the pump. Claims of the invention 1. Electric pump according to author. No. 900049, characterized in that, in order to increase efficiency in operation, it is additionally provided with an annular acoustic emitter mounted in the housing coaxially to the electrodes and an ultrasonic generator to which the emitter is connected. 2. An electric pump as claimed in claim 1, wherein the radiator is made in the form of a piezo-ceramic converter. Sources of information taken into account in the examination 1. USSR Author's Certificate No. 900049, cl. 04 R 17/04, 1979.