SU1112415A1 - Fluid resistor - Google Patents

Abstract

1. LIQUID RESISTOR, comprising a housing with electrolyte and electrodes with down-conductors, characterized in that. that, in order to expand the field of application, it is equipped with an expansion tank, the housing is divided by a dielectric partition into first and second cavities, moreover. The length of the electrode sections in the first cavity is 8–12 times less than the length of the electrode sections in the second cavity, the electrodes are hollow and in the first cavity are provided with pressed-in sleeves with through holes, and the expansion tank is connected by channels with the first and second cavities. 2. A resistor according to claim 1, characterized in that solutions of heavy alcohol or alcohol are used as electrolyte.

Description

The invention relates to electrical equipment, in particular, liquid resistors, and is intended to start a powerful electric motor.

Known liquid resistor, made in the form of a cylindrical tank, through which electrolyte circulates. Inside this tank is located fa. a piston-supplied electrode to change the resistance of the resistor 1,

However, the presence of flow-through electrolyte complicates the design of the resistor.

The closest in technical terms to the invention is a three-phase liquid resistor for starting asynchronous motors, comprising an electrolyte case and electrodes with current leads. In ka4t4 1 electrolyte, an aqueous solution of alkali was used 2.

The disadvantage of the known resistor is low specific power consumption, due to low (about 100 ° C) boiling point at atmospheric pressure.

The purpose of the invention is to expand the scope.

The goal is achieved by the fact that the liquid resistor, comprising a housing with electrolyte and electrodes with current leads, is equipped with an expansion tank, the housing is divided by a dielectric partition into the first and second cavities, the length of the electrode sections in the first cavity being smaller than the length of the electrode sections in the second cavity The electrodes are made hollow and in the first cavity are provided with pressed-in sleeves with through holes, and the expansion tank is connected by channels with the first and second cavities.

In this case, the solutions of heavy alcohols were used as the electrolyte.

FIG. 1 shows the proposed liquid resistor; in fig. 2 is a section A-A in FIG. one.

The liquid resistor contains a metal case 1, which is a zero electrode, which is made of a pipe and has a bottom at one end, and a flange at the other end (not shown). A removable bottom 2 is attached to the flange of the metal housing 1, on which the phase electrodes 3 made of tubes are fixed at an angle of 120 °, open at one end, and current leads 4 are welded to the other end. The fixing of phase electrodes 3 on removable 2 is carried out through packages 5 made of insulating material (for example, fluorine, roplast). The space between the electrodes is filled with an electrolyte (not shown), consisting of an aqueous solution of heavy alcohols (for example, an aqueous solution of ethyl glycol), and is separated by a dielectric crossover 6. Dielectric partition 6 is installed with a sliding or running fit and divides the space of the metal housing 1 by two - the first and second cavities.

The first cavity serves to produce the steam necessary to create an overpressure in the resistor, which ensures that the boiling point of the electrolyte is shifted to higher temperatures. The second cavity is designed to provide the basic characteristics of a resistor (smoothly reducing resistance). First cavity in

0 8-12 times in volume less than the second, but 1.5-3 times more in the specific energy of the electrolyte (due to the fact that metal bushes 7 are pressed onto the phase electrodes 3). In order to circulate and replenish the first cavity with electrolyte, both through the phase electrodes 3 and the sleeves 7 are drilled through holes. Above the metal casing 1 time mixes the expansion tank 8, which serves to compensate for the temperature expansions of the electrolyte and to place its vapor, adjusting the energy intensity, the starting time and the slope of the characteristic. The volume of the expansion tank 8 is equal to the volume of both cavities of the metal case 1 of the resistor, and its air cavity

5 5-10 times the first cavity.

The regulation of the time resistance characteristic is achieved by varying the level of electrolyte in the expansion tank B, which can be in the range of 5-50% of the total volume of the expansion tank.

 tank 8. Expansion tank 8 to metallic housing 1 is attached to tubular channels 9 through which both liquid and vapor circulate. On the expansion tank 8, a safety valve or membrane 10 is disassembled, as well as a fitting 11. A fitting 11 serves to connect a resistor to a pressure relay (not shown); The opening for G1 relief valve 10 during the refueling period serves as a filling neck.

0 The operation of the liquid resistor is as follows.

When the power is turned on, the current from the power supply system is supplied, for example, to the stator windings of the electric motor, and then to the phase electrodes 3, to close the circuit through the electrolyte. The most intense passage of current takes place in the first cavity, where the electrolyte boils after 1.5-2 seconds. The electrolyte vapors from the first cavity come in and the expansion tank 8, where it condenses, diverting its energy to the walls of the expansion tank 8 and the electrolyte located in it. Kip is the electrolyte noBbiHjaeT pressure in the case1 of the resistor from atmospheric to the calculated value, shifting the boiling point to a higher temperature. The FS result of 4ei-o in the first cavity is a smooth process of decreasing resistance. By the end of the start in a resistor, it is understood .lan.iennc to the value at which the relay is given. electric motor to a value of 1200-1400 A with a smooth transition for 5-7 seconds to an operating current of 500 A.

Using water as an electrolyte) a solution of heavy alcohols (for example, an aqueous solution of ethylene glycol causes the boiling point of the electrolyte at a pressure of 5 fcr / cm equal to 20 () v, which increases with an additional increase in pressure.

Claims (2)

1.'LIQUID RESISTOR, comprising a housing with an electrolyte and electrodes with down conductors, characterized in that. that, in order to expand the scope, it is equipped with an expansion tank, the casing is divided by a dielectric partition into the first and second cavities, and the length of the electrode sections in the first cavity is 8-12 times less than the length of the electrode sections in the second cavity, and the electrodes are hollow in the first cavity equipped with pressed-in bushings with through holes, and the expansion tank is connected by channels to the first and second cavities. 2. The resistor in π. 1, characterized in that the solutions of heavy alcohols are used as the electrolyte. Phage 7 ω s G- * Gko Сл> I I I2415