SU989752A1 - Three-phase liquid heating device - Google Patents

Description

(54)

THREE-PHASE ELECTRODE LIQUID HEATER

Claims (2)

The invention relates to electrical engineering, and more specifically to structures for heating an electrically conductive liquid used for industrial and household needs, in heating and ventilation systems. Electrode water heaters are known, or they contain electrodes and bushing insulators inside the case for supplying electric current to C 1 J electrodes. The closest technical solution is a three-phase liquid-electrode electrode heater containing a cylindrical case and a lid with three equidistant from each other and the housing axis circular flanges rotating about its axis, in each of which an insulator is installed with an eccentricity, made in the form of a continuous cylinder fixed on its outer surface surface encased with electrode elements C2} The disadvantage of this heater is the uneven loading of the phases and the small range of power control. The aim of the invention is to even out the load of the phases and extend the range of power control. To achieve this goal, the electrode elements are made in the form of longitudinal plates, and inside the case coaxially the flanges have three fixed insulating chambers, made in the form of two coaxial cylindrical plates connected to one side by a vertical plate, and the radius of the inner plate is smaller than the size of the ecdrisity, and the radius greater than the total value of the eccentricity and the diameter of the bushing. FIG. 1 shows a heater; a cut; in fig. 2 - heater, top view; in fig. 3 - electrode-insulator; in fig. 4 is a section A-A in FIG. 3; . ; in fig. 5 is a section BB in FIG. 3; in fig. 6 shows the movement of an electroplating insulator in an annular chamber, section 39, section B-B in FIG. one; in fig. 7 is an electrical wiring and control circuit. The three-phase electrode heater of an electrically conductive fluid comprises a housing 1 with a nozzle 2 for introducing cold liquid, a nozzle 3 for exiting the heated liquid, a cover 4 with openings for accommodating electrode insulators 5 eccentrically located in circular flanges .6. Inside each lead-through insulator 5, insulated supply conductors 7 extend to the electrode elements 8, while the flange 6 is installed in the hole of the clamp 4 with the possibility of compressed rotation together with the electrode 5, which, when entering it into the insulating chamber 9, changes The resistance of the liquid column in the interelectrode space (the distance between the electrodes on the water increases), and thus control the amount of power consumed. The annular chamber 9 is fixed in the housing 1 by means of insulating struts 10. Chamber 9 shields the electrode elements 8 along their entire height of the passage on the bushing insulator 5, the remaining space at the roof and the bottom ensures the circulation of the heated fluid. The elec- trode heater of the electrically conducting fluid is turned on and off by devices 11 and 12. The number of chambers is equal to the number of electrodes, they are installed coaxially with the flanges and are made in the form of two coaxial cylindrical plates 13 and 14 connected to one side by a vertical plate 15. At when the flange rotates, the electrode will enter the chamber, which is ensured by the fact that the radius of the inner plate is smaller than the value of the eccentricity, and the radius is larger than the total value of the eccentricity and the diameter of the bushing insulator. The device for controlling the power of the electrode heater of the electric wiring fluid works as follows. After filling the housing 1 with liquid, the voltage is applied by turning on the devices 11 and 12 from the three-phase AC source (see Fig. 7) to each Electrode-bushing insulator 5 its phase: phase A - first electrode phase B - second electrode, phase C third electrode. 2 Depending on the temperature of the heated fluid or the power consumed, the required number of electrode elements 8 is turned on or off by the apparatus 12 in each phase. Due to the axial rotation of the flanges 6, the electrodes of the bushing 5 are consumed (Fig. 1 - dashed contours). In the case of current asymmetry in one of its phases. they are aligned by individual rotation of flange 6 with an electrode - bushing insulator 5 or by switching on elements 8 in underloaded or off elements in overloaded phase 8 (LAEReanism of flange rotation is not shown, since this device is well known in the art). The use of this device allows us to simplify the design of the electrode heater of an electrically conductive fluid, to rationally use electricity, to maintain a symmetrical load in phases, to increase the reliability and processability of heating. The invention has a three-phase electrode fluid heater comprising a cylindrical body and a rivet with three flanges equally distant from the body axis and from each other, rotating about their axis, in each of which a bushing insulator fitted with an eccentricity, made in the form of a flat Cylinder with attached immersed in the surface of the surface of the electrode elements, characterized in that, in order to increase the uniformity of loading of the phases and the extension of the limits of power control, electrode elements are made in the form of longitudinal plates, and inside the case three fixed, insulating chambers coaxially mounted to the flanges are made in the form of two coaxial cylindrical plates connected to one side by a vertical plate, the radius of the inner plate being less than the eccentricity eccentricity and diameter of the bushing. . Sources of information taken into account in the examination 1.Datskov I.I. and Mazanov S.S. Electrical heating devices: M., 1973, p. 8 - 12. 2. USSR author's certificate for application No. 3327935 / 24-07, cl. H 05 B 3/60, 07.81. ten FSh.1 W R L / 7 eight eight at Fig.d 6 Fig.Ch