SU974604A1 - Three-phase electrode heater of liquid - Google Patents

Description

The invention relates to electrical engineering, in particular to electrode heating of conductive liquids.

Known electrode fluid heater containing parallel plate electrodes, vertically mounted in the housing, ⁵ and a node for the horizontal movement of the electrodes [1].

The disadvantage of this device is a structurally limited range of applications for electrical resistivity of water, the lack of the ability to smoothly control the thickness of the water layer between the electrodes without disassembling the heater.

A fluid electrode heater is also known, containing a group of plate fixed electrodes vertically mounted in the housing and a group of plate movable electrodes located on one side of them connected to a horizontal displacement unit [2].

The disadvantages of this heater are as follows. Its use is structurally limited by the value of the electrical resistivity of the liquid; heating of the liquid is carried out only on one side of the phase electrodes, which leads to an increase in size.

The purpose of the invention is the provision of rated power in a wide range of values of the resistivity of the liquid.

To achieve this goal, the heater is equipped with a similar indicated and symmetrically located on the other side of the group of stationary electrodes an additional group of movable electrodes, also connected to the node of horizontal movement.

In FIG. 1 shows a heater, a longitudinal section; in FIG. 2 - the same, transverse section; in FIG. 3 - arrangement of electrodes; in FIG. 4-7 - connection diagrams of the terminals of the electrodes.

The heater consists of a housing 1, a cover 2, carriages 3 connected to the shaft 4 with ’’ left ’and’ ’right’ threads, mounted vertically stationary plate phase electrodes. 5, movable plate electrodes 6 mounted on. carriages 3, flexible conductors 7, electrical insulators 8, electrode stroke limiters 9, dielectric shield

10, guide rails I.

The movable electrodes are electrically insulated from each other, for example, by carriage 3 made of an insulating material, and through flexible current conductors 7 are led to electrical insulators 8 mounted on the housing. The electrodes by means of buses and a switch are connected in the ’’ star pattern (Fig. 4).

When the shaft 4 rotates clockwise, the carriages 3 move towards each other, reducing the thickness of the water layer between the stationary 5 and movable 6 electrodes, which reduces the ohmic resistance of the liquid layer and increases the power of the heater. From lateral displacement, the movable electrodes are protected by guide rails 11, along which the edges of the carriages slide. The possibility of contact of the electrodes and the occurrence of a short circuit between them is eliminated by the limiters 9. When the shaft 4 is rotated counterclockwise, the movable electrodes cannot operate on liquids with a resistivity close to 1000 Ohm-cm ^; this is retained by applying the star connection electrode circuit, but with disconnection of the moving electrodes located on the same carriage from the circuit (Fig. 7).

This heater ensures the preservation of the rated power in a wide range of specific electric resistance, 0 fluid resistance, moreover, the adjustment is made on the fly, which allows to unify the designs of electrode fluid heaters on its basis and thereby reduce their variety, used in 5 today. At the same time, operating conditions are improved, operating costs are reduced, since there is no need to disassemble the heater to adjust it according to the electrical resistivity of the liquid ₂₀ , revision and adjustment of the heater are facilitated, and performance is regulated over a wide range.

move from each other, the thickness of the water layer between them and the phase electrodes increases, power decreases. 25

The depth of movement of the movable electrodes is selected taking into account the conservation of the heater’s memorial power not less than with a three-fold change in the resistivity of the liquid, for example, from 2000 to 6000 Ohm-cm. At higher resistivities, the electrode connection circuit switches from star to “triangle” (Fig. 5).

This allows you to get the same rated power with values of the specific resistance of the liquid from 6000 to 18000 Ohm-cm. With a ³⁵ resistivity exceeding 1X000 Ohm-cm. the second circuit of connecting the electrodes with a triangle is used (Fig. 6). With this circuit, in comparison with the circuit of FIG. 5. Connecting the movable electrodes directly to the phase electrodes halves the thickness of the liquid layer between the phase electrodes. which allows you to maintain the nominal power of the heater when working on liquid with a specific electrical resistance of 12,000 to 36,000 ohm-e. If necessary

Claims (2)

(54) THREE-PHASE ELECTRODE HEATER OF LIQUID The invention relates to electrical engineering, in particular to electrode heating of conductive liquids. A known electrode fluid heater containing parallel plate electrodes, vertically mounted in the housing, and a unit for horizontal movement of the electrodes 1. The disadvantage of the device is a constructively limited range of application for the specific electrical resistance of water, the inability to smoothly adjust the thickness of the water layer between the electrodes without disassembling the heater. Also known is an electrode fluid heater containing a group of plate-like stationary electrodes vertically mounted in a housing and a group of plate-type moving electrodes located on one side of them, connected to the horizontal displacement unit 2. The disadvantages of this heater are as follows. It is structurally limited to its application by the values of the specific electric resistance of the liquid, the heating of the liquid, is performed only on one side of the phase electrodes, which leads to an increase in size. The purpose of the invention is to provide nominal power in the iinipOKOM range of values of the resistivity of the liquid. To achieve this goal, the heater is provided with a similarly indicated and symmetrically located on the other side of the group of stationary electrodes an additional group of moving electrodes, also connected to the horizontal displacement unit. FIG. 1 shows a heater, longitudinal section; in fig. 2.- the same, transverse rz: 1 cut; in fig. 3 shows the layout of the electrodes; in fig. 4–7 are diagrams of connected electrode leads. The heater consists of a housing 1, a cover 2, carriages 3 connected to the shaft 4 with left and right threads, installed vertical} {about stationary lamellar phase electrodes. 5, movable plate electrodes 6 mounted on. carriages 3, flexible conductors 7, electric insulators in, travel stops of the electrodes 9, dielectric screen 10, guide bars P. Movable elec- tures1) are electrically isolated from each other, for example, by making the carriage 3 of electrically insulating material and through flexible conductors 7 brought to electrical insulators 8 mounted on the housing. Electrodes with the help of tires and a switch are connected according to the star (Fig. 4). When the shaft 4 is rotated clockwise, the carriage 3 moves towards each other, reducing the water layer between the fixed 5 and the moving 6 electrodes, which reduces the ohmic resistance of the fluid layer and increases the power of the heater. From lateral displacement, the movable electrodes are protected by guiding strips II, along which the edges of the carriages slide. The possibility of contact between the electrodes and the occurrence of a short circuit between them is eliminated by limiters 9. When the shaft 4 is turned in a clockwise direction, the moving electrodes move from each other, the thickness of the water layer between them and phase electrodes increases, and the power diminishes. The ps depth of the movable electrodes is selected taking into account maintaining the nominal power of the heater with at least three times the change in specific resistance (1level1 (and liquids, for example, from 2000 to 6000 ohm-cm. At higher values of resistivity, the junction electrode circuit) from the star n;) a triangle (Fig. 5). This allows to obtain the same nominal monixity at a specific resistance of the fluid from 6000 to 18000 ohm-cm. With a specific match, it is 1X000 ohm-cm. A second triangle-delta connection scheme is used (Fig. 6). With this scheme, in comparison with the scheme of FIG. 5, p. 1) 1 of 1-electrode 1X electrodes directly to the phase reduces the thickness of the layer between the phase electrodes by half, which makes it possible to preserve the nominal power of the HJIH detector with a fluid of y. electrical resistance Fri 12000 to. BOOP Om-cm. At Neo-Holims work on a liquid with a resistivity close to 1000 ohm "cm, the nominal power is saved by using the star connection circuit, but disconnecting from the circuit the movable electrodes located on the same carriage (Fig. 7). In this heater, the nominal power is preserved in a wide range of electrical resistivity of the fluid, and the tuning is performed on the fly, which makes it possible to unify the design of the electrode fluid heaters on its basis and thereby reduce their diversity used at the present time. At the same time, the operating conditions are improved, the operating costs are reduced, since there is no need to disassemble the heater to adjust it to the specific electrical resistance of the liquid, it makes it easier to revise and adjust the heater, and the performance is adjusted in a wide range. Claims of the Invention Three-phase electrode fluid heater comprising a plate-shaped stationary electrodes vertically mounted in a ground housing and a group of plate-shaped moving electrodes located on one side connected to a horizontal displacement unit, characterized in that it is necessary to provide nominal power in a wide range of resistivity values fluid, the heater is equipped with a similar pointer and symmetrically located on the other side of the group of stationary electrodes d An additional group of moving electrodes, also connected to the horizontal displacement unit. Sources of information, taken into account in the examination of 1.Matko, P.M., and others. Electrothermal absorption. M., Energie, 1971, E. 105-111. 2. USSR author's certificate number 663133, Yu1. H 05 B 3/60, 1977.