DE1767840B2 - Arrangement for the independent optimal setting of the electrode distance and for the automatic elimination of short circuits between the cells in chlor-alkali electrolysis cells - Google Patents

Description

The present invention is directed to an in-order for automatic optimal setting of the electrode distance and for automatic elimination of short circuits between the electrodes in chlor-alkali electrolysis cells, for which the voltage states of the individual electrolysis cells are used.

When producing chlorine in electrolysis cells, which mostly work according to the amalgam process, one goes increasingly using the distance between the graphite or metal anodes and the mercury cathode remotely controllable actuators to be set to a favorable value in each case. Because of economical reasons if one summarizes the anodes in groups or cells so that an actuator is one Anode group or all anodes of an electrolytic cell is assigned.

The actuators are preferably from a central point, e.g. B. from an existing control room manually or automatically controlled in such a way that if a short circuit occurs between the anode and Cathode, the electrode spacing is increased, thereby eliminating the short circuit. With graphite anodes the distance to the cathode increases in the course of the operating time due to burn-up. This increases the voltage drop and the yield, based on the use of electrical energy, decrease. By regular Pressing the adjusting device can compensate for this effect of the anode burn-off and the Distance can be brought to the most favorable value again and again.

In order to be able to observe the success of an actuating movement, the voltage between the anodes and of the cathode of the electrolytic cell in question and for display or automatic evaluation the central point at which the control commands are issued.

The automatic evaluation of the voltage curve of an electrolytic cell has so far been used primarily to detect short circuits, to report them and to eliminate them by means of appropriate control commands. A switching arrangement already in use for this purpose consists of an electronic switching stage, which is supplied with the cell voltage via a DC transformer for potential separation. If, as a result of a short circuit, the cell voltage falls more and faster than the response threshold of the switching stage, a short-circuit message is triggered via a switching relay, and with the help of a switching stage, the anodes of the cell in question are switched off by a specified amount by actuating the setting device the cathode lifted off.

Similarly, attempts have already been made through Use more time relays to cause the upward movement of the anodes after a certain time is fully or partially reversed. By automatically actuating the setting device in The anode shortening can have the effect of shortening the anode at regular time intervals by the same predetermined amount can be largely compensated for by burning. It is even possible to go beyond that in larger ones Time intervals in turn to automatically bring about an intentional short circuit, all the more experimentally to determine a reference value for the most favorable setting of the anodes.

For all of these automatically running processes, msn had previously to every single cell or even anode group assign a corresponding switching device. For larger systems that consist of many, e.g. B. several Hundreds of electrolytic cells exist, this method is not very useful because of the effort required grows proportionally to the number of actuating devices. Any changes to the functionality that become necessary requires an effort that is also multiplied by the large number of devices involved will.

The object of the invention is to create an arrangement which has the disadvantages of the previously known arrangements avoids and ensures a perfect, energy-saving operation of the electrolysis cells.

This is achieved according to the invention by an arrangement for automatic optimal setting of the Electrode spacing and for the automatic elimination of short circuits between the electrodes in chlor-alkali electrolysis cells, for which the voltage states of the individual electrolysis cells are used, characterized by an electronic scanning device for cyclically scanning the voltage states of the individual electrolysis cells in quick succession and through a downstream central control unit to control the electrode adjustment drives located on the cells via an interposed Command distributor due to characteristic span

changes.

The scanning device is considerably simplified in this arrangement if it is known in the art Way by DC transformers from the cell potential. You usually come with single-pole, electronic switches with low voltage stresses.

According to a particular embodiment of the arrangement, the central control unit consists of a digital one working data processing unit, which is an analog-to-digital converter is upstream. Here! The file processing machine is of course in terms of size, Storage capacity and working speed of the task and the number of electrolysis cells customized.

The central control unit determines from the incoming voltage values and from characteristic changes in these values whether a short circuit has occurred, and initiates the necessary measures such as outputting a message and confirming the assigned control. Further adjustment processes with the aim of permanently maintaining the optimal setting of the anodes can also be carried out, whereby all changes that prove to be desirable in the course of the operating time can only be implemented for all cells together by appropriate adaptation of the control program.

Another particular embodiment of the arrangement according to the invention is characterized by Motor selection contactors and motor setting direction contactors that can be controlled independently from the command distributor of the electrode adjustment drive, whereby the contacts of the motor selection contactors and motor control direction contactors are connected in series in the motor circuit. This ensures that the command distributor each servomotor via a selection contactor and a direction contactor must drive. This prevents contacts from getting stuck the motor contactor or damage to the electrolysis cells due to similar malfunctions.

Furthermore, the arrangement according to the invention is preferably provided with a second electronic scanning device to query the switching status of the motor contactors and to transmit these switching statuses to the central control unit. This ensures that the motor contactors agree with the commanded one Checked condition. The output of signals to defective scientific organs is automatically blocked.

Finally, the invention preferably provides an interposed timer stage for actuating the Electrode adjustment drive in the sense of increasing the distance between the anodes and the cathode in the event of failure the central control unit. That way will the electrode gap automatically increases to a safe level in order to protect the system from damage, as soon as the central control unit no longer sends out any impulses to identify its functionality.

The invention is now based on an exemplary embodiment on the basis of two circuit diagrams shown in a drawing explained in detail:

In the circuit diagram according to FIG. 1 we.den of the central Control unit 1 the voltages of the individual electrolysis cells 2 via an electronic scanning device 3 fed in quick succession one after the other. In a known way, this system is implemented by direct current transformers 4 separated from the potential of the cells connected in series and can be grounded independently will. Between the programmable, digitally operating data processing unit used as the central control unit 1 and an analog / digital converter 5 is connected to the scanning device 3. A command distributor 6 is controlled by the central unit and is used for the output in chronological order Control command z. B. via motor contactors for clockwise or counterclockwise rotation of a motor drive to the correct one Conducting electrode adjustment drive 7.

Incorrect positioning commands can cause considerable damage lead to the electrolysis cells 2. To avoid incorrect actuation of the actuating devices with sufficient safety to avoid, according to the invention, the following switching arrangement according to FIG. 2 apply:

In each case several, z. B. ten actuators are combined to form a group in terms of control. There it is not necessary to control actuators of a group in different directions at the same time, 2 each motor output 11 of the group instead of two contactors for right and left rotation only a contactor 12 is assigned. Two directional contactors 13 and 14 put together for the whole Group the phase sequence and are controlled alternately, depending on whether clockwise or counterclockwise rotation is desired will. Since two contactors have to be controlled at the same time for each setting process, namely one Positioning direction contactor and a selection contactor, there is a high level of security in this switching arrangement Misoperation. If one of the contactors does not switch due to a defect, it is sufficient to switch off the other contactor to shut down the actuator. The central control unit 1 can with the help of a second electronic scanning device 15 continuously query the switching status of the contactor contacts and block the output of control commands to a group in which a defect of the type described has been detected became.

The command distributor 6 expediently consists of addressable bistable switching stages, e.g. B. flip-flops or electronic storage elements. Each Such a bistable switching stage is assigned to the actuating direction and selection contactor 12 or 13, 14. The central one To initiate a setting process, control unit 1 brings the relevant switching stage by means of a control pulse in working position. It resets the switching stage to the idle state as soon as the setting process has ended shall be. If a malfunction occurs in the central control unit I, this is the case with this arrangement There is a risk that the switch-off command will not be issued and the actuating movement that has started will accordingly not be timely is terminated.

The risk of such an event can be effectively reduced by at least a portion of the Storage elements, preferably those assigned to the directional contactors, as monostable Switching stages are carried out, which are automatically time-delayed from the working position to the idle state return if a new control pulse from the central control unit 1 does not arrive in time. As long as the actuating process is to be maintained, the central control unit must with this arrangement So continuously send control pulses to the relevant switching stage in sufficiently rapid succession. In the event of a malfunction, these pulses will almost certainly fail, so that the actuation process will take place after a short delay canceled. In the simplest case, the number of monostable switching stages can be reduced to one or three, the central control unit 1

to identify its functionality continuously sends out pulses to these switching stages in the working position to keep. As soon as these impulses fail, the switching steps fall back into the rest position and interrupt possibly the auxiliary power supply for the signal output of the Command distributor 6. With three independent circuit groups, each consisting of a monostable switching stage and downstream device, each group receiving separate pulses from the central control unit, you can check the functional reliability of this monitoring device by using the well-known two-out-of-three method very increase.

The optimal anode setting results from the point of view that a small distance between the anode and mercury cathode a low voltage drop in the electrolyte and thus a good yield, based on the use of electrical energy. Increases with decreasing electrode spacing however, the frequency of short circuits between the anodes and the mercury cathode increases. Such short circuits must be resolved quickly in each case in order to avoid overload damage. This is particular In the case of a larger system, this is only possible with an automatically operating control arrangement.

It can now happen that the switching arrangement described so far fails as a result of a fault after all electrolytic cells 2 are set to a small electrode spacing. In this case! is it desirable to increase the electrode spacing immediately by a certain amount, so that during short circuits must not be expected during the downtime. This control process is according to the invention simultaneously triggered automatically for all cells 2 by an independent timer stage 16. This timer stage 16 can be kept ready to respond in the manner already described, as long as the central control unit 1 to identify its functionality continuously pulses to a monostable Switching stage sends. If these Kennimpulsc fail, the timer circuit 16 conducts for all cells 2 together the adjustment process to increase the electrode distance and ends it after the selected Line. The Zcitschaltstufe 16 is then locked against a new automatic release and can z. B. be brought back to readiness by hand as soon as the disturbance of the central Control system has been corrected and this has restored the optimal electrode spacing.

The described timer stage 16 is expediently always desirable in terms of circuitry independent selection device coupled, which allows each actuator to be operated by hand Remote control by pressing a button. To the device for automatic enlargement of the electrode distance extremely To make it functionally reliable, use can also be made here of the two-out-of-three method. If one link fails, full functionality is retained.

For this purpose 2 sheets of drawings

Claims (5)

17 840 claims: 1. Arrangement for automatic optimal setting of the electrode distance and for automatic Elimination of short circuits between the electrodes in chlor-alkali electrolysis cells, including the Voltage states of the individual electrolysis cells are used, marked by an electronic scanning device (3) for cyclical scanning of the voltage states of the individual electrolysis cells in quick succession and through a downstream central control unit (1) for controlling the electrode adjustment drives (7) located on the cells (2) via an interposed one Command distributor (6) due to characteristic voltage changes. 2. Arrangement according to claim 1, characterized in that the central control unit (1) consists of a There is a digital data processing unit, which is preceded by an analog-to-digital converter (5) is. 3. Arrangement according to claim 1 and 2, characterized by independently of one another from the command distributor (6) Motor selection contactors that can be connected (12) and motor direction contactors (13, 14) of the electrode adjustment drive (7), the contacts the motor selection contactors (12) and motor control direction contactors (13. 14) in series in the motor circuit are switched. 4. Arrangement according to claim 1 to 3, characterized by a second electronic scanning device (15) to query the switching status of the motor contactors (12, 13, 14) and to transmit them Switching states to the central control unit (1). 5. Arrangement according to claim 4, characterized by a timer (16) for actuating the Electrode adjustment drives (7) in the sense of increasing the distance the anodes from the cathode if the central control unit (1) fails.