NO138115B - BIPOLAR CHLORINE-ALKALI CELL OF THE FILTER PRESS TYPE - Google Patents

Abstract

Bipolar chlorine-alkali cell of the filter press type.

Description

The electrolytic cell used in the production of chlorine and alkali from an aqueous alkali metal chloride solution has typically been a diaphragm cell with a graphite anode. In recent times, dimensionally stable metal anodes of a practical nature have been developed for use in the diaphragm cell. These metal anodes have also made it possible to take the filter press construction into consideration for the diaphragm cell. To develop a practical cell of the filter press type, however, xlet is required with internal electrical connections, so that compact units can be achieved.

As is known, the internal environment in these cells is very corrosive to many metals, which requires strong electrical/mechanical connections that can be easily protected.

The present invention provides a bipolar electrolysis cell of the filter press type for producing chlorine from an aqueous solution of alkali metal chloride, in which cell the anode (1) consists of a valve metal, preferably titanium, and the cathode (6) consists of a ferrous metal, preferably steel, and the anode and cathode are electrically connected to each other by that

they are bolted together, with a bolt (5) with a threaded engagement device and made of essentially the same metal as said electrode (6) being passed through one electrode (6), and the other electrode (1) having an internally threaded engagement device, characterized in that the threads in the ferrous metal part are coated with coin metal and the threads in the valve metal part are coated with a metal from the platinum group, preferably platinum,

and that the internally threaded part which receives the threaded bolt (5) is constituted by a projection (2) on the side of one electrode (1) which faces the other electrode (6). A preferred embodiment is that a projection (7) of ferrous metal is attached to the cathode (6) just opposite a projection of

titanium on the anode (1), the ferrous metal projection (7) being arranged for the introduction of the bolt (5).

The drawing shows a ferrous metal cathode and a valve metal anode in electrical and mechanical connection according to the invention, the cut being laid along the bolt.

As shown in the drawing, the invention provides a metal anode 1, which, as is known per se, can be a plate (compact or, with openings in the desired pattern) or an expanded wire cloth of valve metal. A metal cathode 6: of ferrous metal, preferably steel, constitutes the second electrode in the bipolar cell. As indicated for the anode 1, the cathode 6 can either be a plate (compact or with openings in the desired pattern) or an expanded wire cloth. For reasons of convenience, the distinction between the anode 1 and the cathode 6, and parallel to these, is not shown in the drawing as the invention does not relate to a particular cell, . and as the use of separation devices in the cell is well known and greater clarity is achieved regarding details according to the invention by omitting such separation devices.

To one of the electrodes there must be attached, -typically in welding etc, a projection with a threaded engagement device adapted to receive the bolt 5. Considering that the typical electrode is thin, it is desirable that each electrode is equipped with a projection, so that when the anode 1 and the cathode 6 are aligned correctly, the two protrusions will meet and give a suitable desired distance between the respective electrodes and the separation between anolyte and catholyte. It is of course not decisive whether the projection that carries the bolt sits on one or the other electrode.

As shown in the drawing, the anode's projection 2 is adapted to receive the bolt. The projection 2 has threads or threaded engagement devices which are coated or plated with a thin but continuous coating 3. The projection 2 on the anode 1 is made of a metal which is essentially the same as the anode metal, i.e. that the projection 2 is also made of a valve metal. The coating 3 is a platinum metal applied according to common methods of platinization. A convenient method is to apply a thermally reducible platinization solution, which can then be reduced to an adherent coating with the help of a small torch. The second leap forward. is., as, shown in the drawing, the cathode projection 7 which is made of substantially the same metal as the cathode 6, namely a ferrous metal.

The projection 7 is also attached by welding or in another suitable way. The projection 7 has an opening or a hole in the axial extension of a hole in the cathode 6 through which the bolt 5 is inserted before providing the electrical/mechanical connection according to the invention.

The bolt 5 has the usual head with pressure absorbing shoulders, shank and threads at the other end. For the purposes of the invention, the threads are coated or plated with a metal 4. The bolt is made of a similar metal to the electrode through which it is passed. As shown in the drawing, the bolt is passed through the cathode 6 and the cathode projection 7, and the bolt 5 is therefore made of a ferrous metal, and the plating 4 is of coin metal. For the purpose of the invention, the nut on the bolt 5 may have a recess for a screwdriver or the like, or it may be arranged to be moved by means of a spanner or the like. The bolt's pressure-absorbing shoulders are shown as conical, but a different design, e.g. flat surfaces, can be used, depending on the thickness of the electrode and whether each electrode is provided with protrusions.

It will of course be understood that when the bolt 5 is mounted in engagement with the internally threaded projection, the contact flanges of the bolt head will rest against the electrode and/or the projection, so that the electrode (cathode 6 in the drawing) is held firmly.

As the bolt 5 is mounted in engagement with the internally threaded projection 2, the coating 4 on the threaded part of the bolt and the coating 3 on the internally threaded part will yield just enough for the bolt 5 to be screwed in and form a tight, firm electrical and mechanical connection under mechanical tension. The loss of electrical energy due to resistance in the connection is thus reduced to a negligible value. Mechanically, the connection is permanently tight and firm.

It follows from the foregoing that the anode projection 2 must fit together with the cathode 6 (or possibly the cathode projection 7), so that the head of the bolt 5 exerts pressure on and holds the cathode in place.

The person skilled in the art will easily see from the foregoing description that the advantages of the invention will be obtained regardless of whether the bolt passes through and is connected to the anode 1 and its projection 2 or the cathode 6 and its projection 7. In any case, the bolt is made of a similar metal to the electrode it passes through . In each case, the ferrous metal threads or the engagement device are coated or plated with a coin metal. In each case, the valve metal threads or the engagement device are coated or plated with a platinum metal.

When describing the invention, the term valve metal is used to describe a group of metals that are well known in the electrochemical field. Here it is sufficient to say that valve metals mean the metals titanium, zirconium, tungsten, tantalum and niobium. Titanium or tantalum is preferably used, normally of a commercially available pure quality, such as electrolytic metal. Alloys of titanium can be used provided that the alloy satisfies the passivity criterion, metal alloys that are passivated when polarized anodically can remain passive well past the anodic potential required to convert chloride ion to chlorine. The passivity phenomenon referred to here is dealt with in an article by Greene in Corrosion of April 1962, pages 136-t to 142-t, where fig. 1 shows a typical active-passive transition for a metal facing a corrosive medium. Alloys of titanium and aluminium, vanadium, palladium, chromium or tin can be used where the latter metals are present in amounts of less than 10% of the alloy.

The metal that is coated on the ferrous metal is a coin metal, i.e. copper, silver or gold. Because of solution conditions that must be met in the direct plating of ferrous metal with these metals, it is sometimes desirable to first plate with another metal such as nickel, which has a more desirable electroplating solution, after which the desired coin metal is applied by plating . For example, when nickel and copper are used, the use of a cyanide bath is avoided. If a two-stage plating with nickel and copper is described, this means that the copper is applied over a thin layer of nickel. Other intermediate layers are described in a similar way. With the help of such a two-stage application of soft metal, the advantages that the invention provides are achieved at the same time that more desirable plating solutions can be used. Such two-stage systems are understood to be within the scope of the invention.

"Platinum group metals" or "platinum metals" shall mean platinum, ruthenium, osmium, rhodium, iridium and palladium and alloys of two or more of these metals. It was found convenient to designate this group as platinum as this metal is the preferred metal in the group.

Claims (2)

1. Bipolar electrolytic cell of the filter press type for producing chlorine from an aqueous solution of alkali metal chloride, in which cell the anode (1) consists of a valve metal, preferably titanium, and the cathode (6) consists of a ferrous metal, preferably steel, and the anode and the cathode are in electrical connection with each other in that they are bolted together, a bolt (5) with a threaded engagement device is passed through one electrode (6) and is made of essentially the same metal as said electrode (6), and the second electrode (1) has an internally threaded engagement device, characterized in that the threads in the ferrous metal part are coated with coin metal and the threads in the valve metal part are coated with a metal from the platinum group, preferably platinum, and that the internally threaded part that receives the threaded bolt (5) consists of a projection (2) on the side of one electrode (1) that faces the other electrode (6). 2. Cell according to claim 1, characterized in that a projection (7) of ferrous metal is attached to the cathode (6) just opposite a projection of titanium on the anode (1), the ferrous metal projection (7) being arranged for the introduction of the bolt ( 5).