DE1173068B - Fuse to prevent short circuit damage in electrolysis cells - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Kl .: BOIk

Number:
File number:
Registration date:
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German class: 12h-1

F 32439 IV a / 12 h
October 29, 1960
July 2nd, 1964

In the field of chlor-alkali electrolysis there is now a general tendency to build larger ones Electrolysis units, as the latter has a number of advantages, such as e.g. B. lower manufacturing costs, Better clarity of the entire system, fewer individual parts, etc., compared to smaller ones Bring units with them.

In this regard, the mercury cells, especially those of the horizontal type, are particularly superior to the diaphragm cells. The largest diaphragm cells used in industry will be today mostly operated with an amperage of about 30,000 amperes, while today with the known new electrolysis systems that work with mercury cells, current loads on the cells 100,000 to 200,000 amperes are no longer uncommon.

Due to the high current loads of modern mercury cells when operated with minimal Tension, d. H. smallest electrode spacing, ao gain by using large anodes hence the short-circuits that occur between the electrodes, particularly when there are large changes in the current load or circulatory disorders in the cell - e.g. B. as a result of an electrode break - as can occur, more and more important and represent in modern operation with well-developed ones Subscriber devices for the anodes - whereby for energetic reasons with the smallest possible, Practically constant electrode spacing is used over the entire life of the cell - today a more important problem than before, especially since those operated with very high current loads Electrolysis cells occurring short circuits can damage the electrolysis cells sensitive.

It would be possible to use the harmful Joule heat that occurs as a result of a short circuit between an anode and the cathode, for example by means of a thermocouple (bimetal), via a temperature measurement to isolate the power supply to the anode electrically or mechanically by means of a switching element, however the devices working according to this principle would have a very complicated structure and would therefore be uneconomical and unsuitable for technical use in large-scale industry. The utilization of the considerable increase in current that occurs in the event of short circuits via an ammeter to suitable switching elements would also prove to be too costly and complicated to lead to a satisfactory solution. There were already safety cartridges for fuse to prevent
Short circuit damage in electrolysis cells

Applicant:

Farbwerke Hoechst Aktiengesellschaft

formerly Master Lucius & Brüning, Frankfurt / M.

Named as inventor:
Dipl.-Ing. Johannes Dörfel, '
Frankfurt / M.- Höchst,
Dr. Franz Holzinger,
Dr. Heinz Schmidt,
Dr. Werner Schmidt,
Frankfurt / M.- Unterliederbach,
Dipl.-Ing. Waldemar Ziemer,
Frankfurt / M.-Höchst

Prevention of short-circuit damage known, in which between fixed contact lugs There is a direct connection through a relatively weakly dimensioned conductor, which two strong conductors connected in parallel and isolated on one side from the weak one designed current conductors are led out to the outside. The conductive parallel connection on the bushing side takes place in these known fuse cartridges via spring clips that are attached to the bushings open into slot points and together with these form further conductor lines. These known fuses are only designed for low currents (about 200 to 350 amps) and no longer usable after a short circuit. However, as with the electrolysis cells, in particular in the case of the horizontal mercury cells used for chlor-alkali electrolysis, the safety devices must be set up for currents in the order of magnitude of 1000 to 2000 amperes and to be able to be used repeatedly and addressed individually to prevent short-circuit damage should respond without the other fuses due to the sudden load transfer bring the fuse cartridges described above for the prevention of short-circuit damage not possible in large electrolysis cells.

409 628/257

The present invention now relates to a fuse for preventing short-circuit damage in electrolysis cells, especially the horizontal ones used for chlor-alkali electrolysis Mercury cells that do not have the above-mentioned disadvantages of the known devices and safe operation of the electrolysis cells, which are operated in particular with very high currents made possible in a simple and economical way.

Tall parts of the anode lead are preferably made of copper.

Furthermore, in particular a power supply 2 has proven to be expedient, which consists of a package of superimposed copper strips.

For better heat accumulation of the Joule heat that occurs in the event of a short circuit in the immediate vicinity of the soldering point 16, it has also proven to be useful if the

It is characterized according to the invention that io metal part 7 in the vicinity of the soldering point cross-sectional

leading to the copper rod power supply to reductions 11, such. B. constrictions

at its other end with a pin containing
tend metal part is connected by means of a

due to the damage caused by a short circuit between

placed both in the main and in the shunt in the power supply line leading to the anode will.

The timely melting of the solder joint connecting the two metal parts 4 and 7 is particularly important this ensures that as a result of the reduction in cross section caused by the pin 3 also a higher current density at the soldering point

The operation of the shown in Figs Fuse according to the invention is conceivable see anode and cathode occurring Joule 15 simple. The heat that occurs in the event of a major short circuit and even before the occurrence of tend and damage to the electrolytic cell fusible alloy with a Joule heat that brings the invoking heat over the soldering power supply rails the electrolysis cell instead of 16 brought the two metal parts 4 and 7 connecting, a recess for the pin - metal alloy for melting and the between the other metal part is soldered, and that the 20 of the power supply 2 and the anode holder 10 Power supply by means of a spring 9 which is fastened and electrically insulated by the insulation body tears the The current-insulated spring is connected to the anode holder, pin 3 of the attached to the power supply is bound. Metal part 4 from the recess 6 of the metal part 7

So one uses out in the invention and thus immediately automatically interrupts the Fusible current fuse for short-circuit 25 power supply to the anode.

Conclusions occurring in the anode power supply. The fuse according to the invention can

Joule heat to it, an alloy which melts at certain temperatures and which is below normal Electrolysis conditions in the form of a solder joint hold two metal parts together, melt and through Spring force automatically separates the two metal parts and an automatic and instantaneous Bring about power interruption.

An example and particularly advantageous
Embodiment of the fuse 35 according to the invention prevails and thus in the event of a fuse is shown in FIGS. 1 to 4, with high short-circuit current also having a greater F i g. 1 is a schematic representation of the total Joule heat occurring at this point. The voltage drop occurring at the device as well as the voltage drop occurring with this device and the soldering point is negligible in the case of indirectly connected parts of an electrolytic cell with normal current load on the cell and FIG. 2 to 4 the essential device 40 small.

reproduce parts on a larger scale. In the It is also to be taken into account that, if the

1 to 4, 1 denotes the copper rod, 2 which is soldered into the graphite shaft 13 on copper steel This attached power supply, 4 the one zap (soldering point 12), for soldering the metal parts 4 fen 3 having metal part, which is to be used on the power supply and 7 an alloy whose Guide 2 is attached, 5 the power supply rails 45 melting point lower than that for the solder joint 12 the electrolytic cell to which the metal part 7 with the alloy used is attached. For example, it is used for Well 6 is attached, 8 insulation body, 9 the soldering of the copper rod 1 in the graphitan the power supply 2 and the anode holder anode shaft 13 used an alloy that is used in 10 attached spring, 11 a contained in the metal part 7 melts about 180 ° C, so for the soldering point 16 tene cross-sectional reduction in the form of a one-5 ° expediently an alloy with a melting point lacing, 12 the soldering point in the anode shaft 13 of z. B. 80 to at most 180 ° C, preferably from

about 120 ° C selected.

It is within the scope of the present invention, for the connection of the metal parts 4 and 7, a Le- and 16 the soldering point which the two metal parts 4 55 alloy are to be selected, whose melting point and 7 cohesion and when a short- is true is that the time until the response of the

Fuse as short as possible in the event of a short circuit, depending on local conditions will. An increase in the current density through corresponding reduction in size also contributes in particular to this of the pin 3 and the recess 6 at.

soldered copper rod, 14 the cell cover of the electrolytic cell, 15 the one directly above the mercury cathode located anode block made of graphite

The end melts as a result of heat build-up.

An example embodiment of the metal parts 7 and 4 is shown in FIGS. 3 and 4 in an enlarged view Dimensions shown.

According to the invention has proven to be particularly advantageous for connecting the two metal parts 4 and 7 to use an alloy by soldering the pin 3 in the recess 6, the one

The advantage of the present fuse according to the invention is in particular that the associated individual parts represent very simple and easy melting points between 80 and 180 ° C, preferably 65 available elements, and the soldering also has between 100 and 140 ° C. It is very easy to insert grain of the pin 3 into the recess 6, in particular alloys made of lead, tin,
Antimony, bismuth, etc. in question. All other Me

and can be accomplished within a very short time. There is also the fact that the individual parts

the fuse according to the invention is reused at any time after eliminating the causes of the short circuit can be by simply the pin 3 of the metal part 4 again with the in question Coming alloy is soldered into the recess 6, in particular the in the F i g. 3 and 4, the embodiments of the two parts 7 and 4 shown allow good soldering by the recess 6 of the metal part 7 is filled with the fusible link and the pin 3 of the part 4 then is inserted into this cavity filled with fusible link. After cooling and solidification of the Fusible link and fastening of the power supply cable 2 fastened to the spring 9 to the metal part 4 there is a new and operationally safe fuse.

Due to the rapid interchangeability of the individual parts making up the fuse according to the invention and in particular by keeping completely soldered spare parts in stock, safe Prevention of short-circuit damage in today's large, modern electrolysis systems is guaranteed.

Claims (1)

Patent claims: 1. Fuse to prevent short-circuit damage in electrolytic cells, in particular the horizontal mercury cells used for chlor-alkali electrolysis, thereby characterized in that the power supply (2) leading to the copper rod (1) has a pin (3) at its other end Metal part (4) is connected by means of a through which a damaging Short circuit between anode and cathode occurring Joule heat and still temporally before the occurrence of damage fusible alloy with one on the power supply rails (5) attached to the electrolytic cell, having a recess (6) for the pin (3) Metal part (7) is soldered, and that the power supply (2) by means of an insulating body (8) current-insulated spring (9) with the Anode aging (10) is connected. 2. Fuse according to claim 1, characterized in that the soldering together of the pin (3) and recess (6) of the parts (4 and 7) serving alloy has a melting point between about 80 and 180 ° C, preferably between 100 and 140 ° C. 3. Fuse according to claim 1 and 2, characterized in that the copper rod (1) leading power supply (2) consists of a package of superimposed copper strips. 4. Fuse according to Claim 1 to 3, characterized in that the metal part (7) has cross-section reductions (11) for better heat accumulation in the vicinity of the soldering point. Considered publications:
Catalog from Fritz Driescher SK 1950, p. 15, paragraph, p. 16, first paragraph, as well as Fig. 19. 1 sheet of drawings 409 628/257 6. 64 © Bundesdruckerei Berlin