RU2076908C1 - Device for electric shunting and method of electric shunting - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: device of jumper switching for electric shunting of at least one electrolyzer composed of individual electrolytic baths or assemblage of monopolar electrolyzers connected in series to one power supply source incorporates set of tapping connectors for connection to contact of anode of each individual bath of electrolyzer placed directly in front of shunted electrolyzer and set of tapping connectors for connecting to contact of cathode of each individual bath of electrolyzer placed directly after shunted electrolyzer. mentioned device of jumper switching includes resistor to ensure uniform reduction of electric flow in individual baths of shunted electrolyzer without change of values of electric current in adjacent baths of electrolyzer placed directly in front of and after shunted electrolyzer. EFFECT: increased operational reliability of device. 12 cl, 10 dwg

Description

 Electrolyzers, such as membrane electrolyzers of a chlor-alkali press filter of the type for salt electrolysis, are susceptible to harmful effects on the electrolytically active coating of the surface of the shunt electrolyzer cathode, which are caused by reverse electric current, harmful effects also occur when excessive current flows through individual baths of electrolyzers adjacent to a shunt electrolyzer, as a consequence of a change in the value of the electric flux in the baths, are closest them to the connection with the shunt switch.

 A short circuit device is known which allows a partial or complete bypass of an electric current around an electrolyzer. The known invention provides a method of redirecting current around a shunt electrolysis cell without creating a reverse electric flow to the shunt electrolysis cell. However, it does not offer a device for ensuring uniform electric flow from a set of bathtubs of the electrolyzer located in front of the adjacent cell to a set of bathtubs of the cell located after the adjacent cell.

 An object of the present invention is to provide a device for removing an electrolytic cell from a plurality of electrolytic cells connected in series to an electric power source, especially monopolar electrolytic electrolytic cells for liquid electrolysis, a device capable of preventing a change in the value of current flowing through individual baths of electrolytic cells adjacent to a shunt electrolytic cell, and to prevent destruction of electrolyzers by avoiding reverse electric flow.

 The next objective of the invention is to improve the method of shunting an electrolytic cell from a plurality of electrolyzers by using a jumper device of the present invention.

 These and other objectives and advantages of the present invention will become apparent from the following detailed description.

 A new electrical jumper device (means) of the jumper switching of the present invention for electric shunting of at least one electrolytic cell, consisting of individual electrolytic baths, from a plurality of monopolar electrolyzers connected in series to one power source, referred to herein as a jumper switching device, includes a set of tap connectors for connection with the anode contact of each individual bath of the electrolyzer located immediately in front of the shunted electrolyzer, and a set of tap connectors for connecting to the cathode contact of each individual bath of the electrolyzer located immediately after the shunt electrolyzer. The specified jumper switching device includes a resistor device to ensure uniform reduction of electric flow in individual bathtubs of the shunted electrolyzer without changing the value of the electric current in adjacent baths of the electrolyzer located immediately before and after the shunted electrolyzer.

 In FIG. 1 and 2 depict conventional short circuit switches of the prior art and their electric flow; in FIG. 3 5 are schematic views of an embodiment of the present invention, consisting of a jumper device located above the electrolysers, in top, front (section X X) and side views, respectively; in FIG. 6 is a pictorial illustration of an embodiment of Fig. 3 5; in FIG. 7 is a pictorial representation of a second embodiment of the present invention, wherein a jumper device is located under the electrolysers; in FIG. 8 10 are three possible variants of the internal electrical circuit of the jumper switching device of the present invention, designed in such a way as to avoid changing the current value in adjacent baths of electrolyzers immediately before and after the shunt electrolyzer.

 In FIG. 1 and 2, a conventional short-circuit switch is intended for shunting the electrolyzer 2 by connecting a short-circuit switch to metal buses 6 and 7. FIG. 2 shows the electric flow in electrolyzers 1 and 3, located immediately before and after electrolyzer 2, after the closure of the switch. The dashed streamlines (i) show an increase in the electric flux of electrolyzers 1 and 3, which are closest to the switch contacts, as a result of a shorter current path in the metal buses 5 and 7.

 In FIG. 3 5 schematically depict top, front (section X - X) and side views of a series of monopolar electrolyzers 1 3, each of which contains a plurality of closely spaced electrolytic baths 4 and 5, and a jumper device located on top, aimed at shunting the cell 2. Device jumper switching 8 is installed on the supports 9 and 10 mounted on the electrolysis 1 and 3, and connected to the contacts of the anode 11 of each monopolar bath 4 immediately preceding the electrolyzer 1, using a set of tap-offs the connectors 12. The jumper device, in addition, is connected to the contacts of the cathode 14 of each monopolar bath 5, immediately following the electrolyzer 3, using a set of tap connectors 13. In order to obtain low-resistance connections between each pair of tap connectors and the contacts of the anode or cathode , said tap connectors, which can be either rigid or flexible, can be equipped at their ends with clamps mounted on springs. The latter (clamps) under the influence of the dead weight of the jumper device 8 "pinch" the contacts of the anode or cathode, having an oblong shape. The jumper switching device 8 is also connected to a mobile crane, which makes it possible to place the jumper switching device 8 just above the electrolyzer, which must be shunted in a series of several electrolytic cells of the electrolysis shop of the electrolysis production enterprise.

 In FIG. 6 is a pictorial representation of an embodiment schematically shown in FIG. 3 5.

 In FIG. 7 shows a similar pictorial representation of a second embodiment of the present invention, where the jumper switching device 8 is located under the electrolytic cells and rests on a trolley moving along rails located just below each row of electrolytic cells.

 The remaining components are left unchanged, as well as the corresponding positions.

 The electric current is directed from the monopolar bath 4 of the immediately preceding electrolyzer 1 through the contacts 11 and the set of tap connectors 12 to the jumper switch 8. Then, the electric current flows through the resistor device in the jumper switch 8 to control the electric current to the set of tap connectors 13 and to the contacts 14 of the monopolar baths 5 of the immediately following electrolyser 3. The current is withdrawn gradually in equal portions from monopolar baths 4 and is supplied in equal portions to monopolar baths 5, In this way, the problem of changing the current value, which was discussed earlier, is completely solved.

 In FIG. 8 to 10 show three possible embodiments of the internal electrical circuits of the jumper switching device 8 of the present invention.

 In more detail, FIG. 8 shows that tap connectors 12 and 13 can be connected to metal buses 15 and 16, the cross-sectional area of which is significantly greater than the cross-sectional area of the metal buses connecting the electrolysers (positions 6 and 7 in the previous figures). A cross-sectional area of such a large magnitude prevents any, somehow significant, change in the current value in adjacent individual baths of electrolyzers located immediately before and after the shunted electrolyzer. This jumper switching device 8, in addition, is equipped with two switching units 17 and 18 and a resistor device 19; after the tap connectors 12 and 13 are connected to the contacts of the anode and cathode (11 and 14 in Fig. 3 7), the switching unit 17 is closed and part of the total electric current is discharged through the resistor device 19. The remaining smaller part of the electric current is still supplied to a shunted electrolyzer, thereby contributing to the establishment of such working conditions in the electrolyzer that prevent the appearance of reverse current in the resulting short-circuited circuit. After an appropriate period of time after the closure of the switching unit 17, the switching unit 18 is also closed, providing a complete bypass of the cell without any significant reverse current in the cell itself.

 Another embodiment of the electrical circuit is shown in FIG. 9; in this case, the metal busbars were divided into subassemblies 20, 21 and 22, 23, respectively, to which tap connectors 12 and 13 were connected. Each subassembly, being electrically isolated from the other, is equipped with switching units 24, 25 and 27, 28, respectively, and resistor devices 26, 29, which operate as described above, in the case of the jumper device of FIG. eight.

 Separation of metal buses into sub-nodes allows to exclude a change in the current value, as mentioned above, without returning to the use of massive metal buses, due to some complication of the electrical circuit.

 In FIG. 10, a diagram of FIG. 9 in the boundary case when each pair of anodic and cathodic tap connectors 12, 13 is connected to its own switching unit (30, 31) and resistor device 32 in a modular design. When using parallel connection of switching units and resistor devices shown in FIG. 9, 10, the switches must be switched simultaneously (for FIGS. 9, 24 and 27 and then FIGS. 25 and 28).

In order to properly understand this invention, it must be borne in mind that the resistivity is the direct current resistance between opposite parallel faces of a piece of material having a length and cross-sectional area. The specific resistance of the material determines the resistance of the material, and the resistance is calculated by the formula
R pL / A (1),
where R is the resistance, mOhm;
p resistivity, mOhm / cm;
L length, cm;
A cross-sectional area, cm ² .

The following are the resistivities of several metals:
Metal Ud. resistance
Aluminum 2,655
Copper 1,673
Cast Iron 75 98
Lead 20.65
Magnesium 4.46
Nickel 6.84
Steel 11 45
The voltage drop in each metal bus (shown at 6 and 7 in FIGS. 1, 2) can be calculated for the circuit of FIG. 1, where a conventional short circuit switch is used to bypass electrolyzer 2, defined as
V 0.5 RI (2),
where R is defined by equation (1) above;
I is the total current passing through the cells.

Assuming a total current of 60,000 A, a length of 200 cm and a cross-sectional area A of 100 cm ² , the voltage drop along the metal bus will be 0.1 V.

 That is why connecting the short circuit device of the prior art to one of the ends of the metal bus 6 and 7 will cause a change in the current value in the baths located closest to the contacts of the jumper switch, as shown in FIG. 2. In these cases, when the prior art used a switching device, connecting it to the metal busbars 6 and 7, as in US Pat. Nos. 4,561,949 and 4,598,966, the electrolyzers were limited to only a small number of monopolar baths to avoid excessive changes in the value of the electric flow.

 As you can see, the electrical resistance can be minimized by: (1) reducing the length of the current path or (2) increasing the thickness of the metal busbars.

 In both cases, the prior art is limited by practical considerations. Thus, the prior art will in any case cause some change in the current value.

 Using the jumper switching device of the present invention, current can be uniformly transmitted from electrolyzers including any number of individual bathtubs without causing a change in the value of the electric current.

 In fact, the electric current is directly transmitted from the individual baths of the electrolyzers through the bypass connectors to the jumper switching device of the present invention without passing through the metal buses that electrically connect the electrolysers during their normal functioning. In addition, the internal electrical circuit of the jumper switching device of the present invention is designed in such a way that allows portions of the electric current passing through the bypass connections to be equal. Such a result is achieved by using the embodiments shown in FIG. 8 10 with enlarged internal metal buses, the size of which is selected in order to ensure a voltage drop of less than 50 mV, or internal metal buses divided into subnodes, each of which is equipped with switching and resistor devices, an individual switching and resistor device for each tap connection, this last device allows, as another advantage, to provide better control over the heat generated by electric current.

 In the case of a conventional jumper switch, the shunt electrolyzer should be removed by lifting it above the jumper switch, along and to the side, which leads to unsafe working conditions for workers. The electrolyzer is heavy and its location above the workers creates the likelihood that the electrolyte, which can be 32% caustic and chlorine-containing saline, during chlor-alkali electrolysis can spill down onto the workers. The jumper switch also blocks access to and exit from the shunt cell. By positioning the jumper switching device of the present invention above or below the shunt electrolyzer, these problems are solved and the electrolyzer can be located at ground level and removed, for example, using a conventional forklift. Thus, there is no risk that the cell may fall on the workers and access to the cell is open.

 Using the jumper device of the present invention can save up to 40% copper, as the metal bus connected to the electrolytic cells can be designed with the condition that it is simple to transfer electric current from one electrolyzer to another, and not to minimize changes in the value of electric current in individual bath electrolyzers, which occurred when using the jumper switch of the prior art. In addition, taking into account the fact that the total current is divided into small portions in each outlet connector, the voltage drop in these connectors is negligible, and the connection between each outlet connector and the corresponding anode or cathode contacts can be frictional type (the spring clips mentioned above ), and not the type of bolt connection required when using the prior art jumper switch, where a large, large current flows through them. It takes a considerable time to establish a bolted type connection and, accordingly, it takes workers to stay between working electrolyzers for a longer time, which is dangerous.

 Another advantage of the jumper switching device of the present invention is that there is no limitation on the number of shunt electrolysis bathtubs.

 Various modifications of the devices and method of the present invention are possible without departing from the spirit and scope of the present invention, and it should be borne in mind that this invention is limited only by what is defined by the claims.

Claims (11)

 1. Device for electric shunting of at least one electrolyzer in a series of monopolar electrolyzers connected in series to one power source, located below or above the shunt electrolyzer, including a jumper device with metal anode and cathode buses and a resistor device, characterized in that the anode bus equipped with a set of conductive jumpers, each of which is connected to one of the anodes of the electrolyzer, located directly in front of the shunted electric a roller, and the cathode bus is equipped with a set of conductive jumpers, each of which is connected to one of the cathodes of the electrolyzer located immediately after the shunt electrolyzer.  2. The device according to p. 1, characterized in that it is equipped with additional resistor device and a switching device connected in parallel with the resistor device.  3. The device according to claim 1, characterized in that at least one of the metal tires is made of several parts.  4. The device according to p. 3, characterized in that the parts of the metal busbar are connected to an additional resistor device and a switching device connected in parallel with the resistor device.  5. The device according to p. 2, characterized in that each pair of tap connectors is equipped with a switching device and a resistor device.  6. The device according to claim 1, characterized in that the connection between the bypass connectors and the anodes or cathodes is made of friction type.  7. The device according to p. 1, characterized in that the tap connectors are made rigid.  8. The device according to p. 1, characterized in that the tap connectors are flexible.  9. The device according to claim 1, characterized in that the cross-section and length of the metal tires are determined from the condition of ensuring a voltage drop in the tire of less than 50 mV.  10. A method of electric shunting of at least one electrolyzer in a series of monopolar electrolyzers connected in series to one power source, comprising connecting a device for electric shunt located above or below the shunt electrolyzer to a shunt electrolyzer containing a jumper switching device with metal anode and cathode buses and a resistor device, characterized in that the anode bus is connected through a set of conductive jumpers with anodes, moreover each jumper is connected to one of the anodes of the electrolyzer located immediately in front of the shunt electrolysis cell, the cathode bus is connected through a set of conductive jumpers with cathodes, each jumper connected to one of the cathodes of the electrolyzer located immediately after the shunt electrolyzer.  11. The method according to p. 10, characterized in that the device for electric shunting includes connecting the resistor device and the additional switching device in parallel to each other, closing the switching device to provide a short circuit of the additional switching device.

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