NO139275B - PROCEDURE FOR REGULATION AND PROTECTION OF ANODE DEVICES IN ELECTROLYSIS CELLS - Google Patents

Description

The invention relates to a method for regulation and

protection of the anode device in electrolysis cells which are designed for the electrolysis of chlorides of alkali metals and alkaline earth metals and equipped with a mercury cathode and a number of anode groups mounted on anode-carrying yokes.

For a given amperage, an electrolytic cell must

operate under optimal scouting conditions, primarily regulated electrically and furthermore the average distance between the electrodes must be as small as is practically possible due to the present irregularities in the cathode layer and the anode arrangement.

This distance must be increased over time even with relatively dimensionally stable anodes. As long as precautions are not taken against this, after a certain time a short circuit will occur which can damage some of the anode elements. In order to

could prevent this, then the short circuit must be detected in time,

and then the yoke that carries the defective elements must be

works, after which a general regulation can finally be carried out to restore the optimum voltage.

If these work operations are to be performed manually, they will

be expensive and time-consuming, and there will be a risk that they will only take place after a short circuit has occurred.

From German publication no. 2,136,603, however, an automatic method of the above-mentioned type is known, during which automatic lifting and lowering of anode-carrying yokes is carried out on the basis of lifting orders and lowering orders, which are generated during predetermined regulation processes, lifting orders being prioritized over lowering orders. According to the German text, such a process involves the difference (i— T) between the current strength i for each anode group and the average current strength X for all anode groups being compared with a high, experimentally determined threshold value and a lifting order is issued to all yokes for which the considered difference exceeds the high threshold value for an arbitrary anode group carried by the yoke in question.

Against this background of the state of the art, the purpose of the invention is to specify a method for automatically and in the shortest possible time partly to obtain information about the cell's electrical condition and partly to reveal and counteract short circuits just before they become harmful, as well as finally to automatically regulate the distance between the electrolysis cell's electrodes in such a way that the cell's energy consumption is constantly optimised.

This is achieved with the help of one method of the type indicated above and whose special feature according to the invention consists in that in addition to the regulation process indicated above a) the following further regulation processes are carried out: b) the difference (i - T) is continuously compared with a low experimentally determined threshold value and a lowering order, possibly time-delayed, is issued to all yokes, for which both the observed difference falls below the low threshold value: i for all anode groups on the relevant yoke, and the electrolysis voltage exceeds a predetermined, experimentally determined threshold voltage.

c) the electrolytic agent voltage and/or the voltage on each yoke is compared with an experimentally determined safety voltage, and a lifting order is given to the relevant anode-carrying yoke if the compared voltage falls below the safety voltage, and the lifting order is maintained until this voltage again exceeds the safety voltage for the relevant yoke, as the aforementioned regulatory processes a), b), and c) are carried out.; at the same time, and said experimentally determined threshold values and voltages are adjustably set depending on the present electrolysis process, the nature of the cell and the degree of wear of the anode and/or continuously regulated as a function of the current density and/or other cell parameters that can affect the electrolysis voltage.

The experimentally determined stresses are usually determined

depending on the cell's so-called reference voltage, V re^ which is defined by the expression:

The constants k^ and k_ are here characteristic constants for the cell in question and correspond respectively to the cell's nominal electromotive force and the nominal resistance per unit anode surface, while iA is the current density on the anode surface.

The experimentally determined threshold voltage mentioned under point b) is then usually defined as the sum of the reference voltage V and an adjustable additional voltage Vo.

Similarly, the experimentally determined safety voltage mentioned under point c) is usually defined as the sum of the reference voltage V ref and an adjustable additional voltage

S .

r

A lowering order according to point b) will have a duration T , after which a blocking time of duration Tl is usually created for subsequent lift orders and a blocking time of duration T3 for subsequent lowering orders.

The invention will be explained in more detail below in connection with the attached drawing, with a single figure showing an embodiment of an automatic regulation system for electrolysis cells and which is arranged for carrying out the method of the invention.

In an electrolysis cell for the production of chlorine and with a mercury cathode, the supplied current is distributed to the cell's anodes by means of current rails 8. The leads 3 for the anodes 4 are supported by an anode-carrying yoke 7, which by means of a motor 9 can mechanically displace the anodes in relation to the cathode, which consists of a mercury layer 5. Below this, the height of the yoke's anodes can be regulated in relation to the surface of the mercury-silver layer 5. Furthermore, each individual anode 4 can be displaced maue1c

in relation to the others, if this is necessary.

During execution of the method of the invention, a

measurement of the amperage in each supply line. This measurement is carried out as shown in the figure by measuring the voltage drop between two fixed points 1 and 2 on the supply line. All current measurements for the individual supply lines are collected in a unit 10, which also collects measurements of the electrolytic voltage between points 3 and 5. All these measurement signals are amplified in an amplifier unit 11. Comparisons of the deviation of the current strength in each line from the average current strength with the high and low threshold values and comparisons between the electrolysis voltage and the experimentally determined threshold and safety voltages,

takes place in a comparison unit 12 in which the determined values are introduced in the form of voltages which are themselves adjustable depending on the present electrolysis process, the nature of the cell and the degree of wear of the anode and/or, regulated as a function of the current density and/or other cell parameters that can affect the electrolysis voltage. These functions are processed in a unit 13 on the basis of the collected and amplified measurement values in the units 10 and 11.

Order to raise or lower the anode-carrying yoke 7

is sent to a control unit 14, which carries out the mechanical lifting or lowering of the yokes using the motors 9. These orders are registered or indicated in a storage unit 15.

The current and voltage measurements as well as their processing can be

guided by means of an electronic or pneumatic device,

but preferably takes place using analogue or digital electronic equipment. The current values can be amplified in differential amplifiers and their mean value is derived either

analogue or digital.

The constants and set values are introduced by means of auxiliary voltages, which can be a function of various - parameters that affect the determined value in question, such as the current strength, the position of the cell's anode group, the degree of wear of the anode group or other variables that can affect the determined value.

An advantage of the method of the invention is that it is checked that there is an even distribution of the current strength in the electrolysis cell between the different power supplies to the anodes,

as the produced signals are processed to be able to correct or enable a correction of the electrode distances which can change over time, thus protecting the anode^ against overload and premature wear.

The permanent ongoing comparison of the electrolysis voltage

with adjustable voltages that are fixed and/or are

function of the parameters that can affect the electrolysis voltage, enables a lowering of the yoke while protecting the anodes and causes operation of the cell within optimal ranges of the electrolysis voltage.

The execution examples indicated in the following

tables, reproduce the results obtained for an electrolysis cell with an equipment as shown schematically in the figure. The cell used in the execution example has the following characteristic values:

The cell was used for the electrolysis of an aqueous solution of sodium chloride with a nominal inlet concentration of 310 g/l and a nominal outlet concentration of 275 g/l at an average

temperature of 70°C. The values of the various previously mentioned constants and parameters were as indicated in the following:

In the case of the cell used in the design examples, the parameters vre£/ v0°9 Sr are amplified 1-5 times, while the high and low threshold values are amplified 400 times. The way voltage between points 1 and 2 is also amplified 400 times.

The following specified embodiment examples 1, 2 and 3 indicate instantaneous values for the results obtained at different current consumption for the cell.

Example 4 indicates the average performance for a cell during continuous operation for 80 days.

EXAMPLE 1 Power consumption I = 253,000 amperes

<V>ref ' = 4.38 volts

Specific energy consumption: 3,338 kWh per tonne of chlorine.

EXAMPLE 2 Current consumption I = 250,000 amperes VrQf <=> h, 36 volts

Specific energy consumption: 3A12 kWh per tonne of chlorine.

EXAMPLE ^ Current consumption. I = 171,000 amperes

<v>ref ■•<=> 3.96 volts

Specific energy consumption: 3,068'kWh per tonne of chlorine.

EXAMPLE 4

Results achieved after continuous operation for 80 days:

Claims (1)

Procedure for regulation and protection of anode devices in electrolysis cells designed for the electrolysis of chlorides of alkali metals and alkaline earth metals and equipped with a mercury cathode and a number of anode groups mounted on anode-carrying yokes, during which automatic lifting and lowering of anode-carrying yokes is carried out on the basis of lifting orders and lowering orders, which are generated during predetermined regulation processes, with lifting orders being prioritized over lowering orders, of which a first process a) consists in the difference (i - i) between the current strength i for each anode group and the average current strength in all anode groups being compared with a high experimentally determined threshold value and it is issued lifting order "to all yokes, for which the considered difference exceeds the high threshold value for an arbitrary anode group carried by the yoke in question, characterized by the following further regulation processes being carried out: b) the difference (i.- T) is continuously compared with a low experimentally determined threshold value and one, eve, is emitted ntual time-delayed, lowering order to all yokes, for which both the considered difference falls below the low threshold value for all anode groups on the relevant yoke, and the electrolysis voltage exceeds a predetermined, experimentally determined threshold voltage, c) the electrolyser voltage :' and/or the voltages on each yoke are compared with an experimentally determined safety voltage, and a lift order is issued to the relevant anode-carrying yoke if the comparative voltage falls below the safety voltage, and the lift order is maintained until this voltage again exceeds the safety voltage for the relevant yoke, as the aforementioned regulation processes a), b) and c) are carried out simultaneously, and said experimentally determined threshold values and voltages are adjustably set depending on the current electrolysis process, the type of cell and the degree of wear of the anode and/or continuously regulated as a function of the current density and/or other cell parameters that may affect the electrolysis the nning.