DE3114222A1 - Apparatus for chlorinating molten magnesium chlorine salts - Google Patents

Abstract

An apparatus for chlorinating molten magnesium chlorine salts has a housing (1) which is lined with a refractory material and whose inner cavity (2) is formed by walls (3), a base (4) and a cover (5). Means (6) for supplying chlorine are installed in the lower section of the walls (3) of the housing (1), while means (7 and 8) for feeding in the initial melt and for discharging the chlorinated melt are fitted in the upper section of said walls (3). The object is to increase the efficiency of the apparatus and to prevent the deposition of sludge by tapering the inner cavity (2) of the housing (1) downwards so that its passage cross-section in the plane of the means (6) for supplying chlorine is not more than 0.3 times the passage cross-section in the plane of the means (7 and 8) for feeding in and discharging the melt. <IMAGE>

Description

DESCRIPTION

The invention relates to the electrolytic production of magnesium and chlorine and more particularly relates to an apparatus for chlorinating molten magnesium chlorine salts.

The purpose of the invention is its preferred use in furnaces for chlorination the products of magnesium chloride hydrolysis in a melt of the chloride salts, whose composition comes close to the Karnallitz composition.

It is known that the structural elements of apparatus for Chlorination of molten salts is becoming more and more demanding. On the one hand must these elements ensure an even distribution of chlorine in the melt on its flow path and ensure full chlorine utilization; on the other hand, the construction elements easy to manufacture and reliable in operation in the presence of aggressive ones Be media. These requirements are not yet satisfactory in any known construction Fulfills.

The state of the art already includes an apparatus for chlorinating (Streletz Ch. L. "Magnesium production through electrolysis", Metailurgizdat, 1962, p. 79), der a rectangular housing with walls lined with a fireproof material, having a bottom and a cover. In the cavity of the housing are through the cover introduced electrodes and means for discharging gaseous products. Means for the chlorine supply, for the inlet, extend through the housing walls the starting melt and for the outlet of the chlorinated melt. The chlorination room consists of several chlorination areas, which are separated by partition walls and horizontal grates are separated from each other. The chlorination of the molten salts occurs through interaction a stream of the melt fed to the upper cavity portion of the apparatus will, with the gaseous chlorine, which is under pressure in the lower part of the apparatus is fed to the grates.

Such an apparatus has the disadvantage that it is very complicated in construction and is only insufficiently effective in operation. In addition, the Chlorination process in this construction only in an environment of the means for The chlorine supply is active. In the lower part of the apparatus space there are always dead or congestion areas in which the melt does not come into contact with chlorine, insoluble suspensions precipitate and one is referred to in the following as sludge forms a viscous suspension which must be removed periodically. By the presence the gas distribution grids in the form of ceramic plates, which are mounted on the circumference of the lining and have openings for the passage of chlorine over the entire surface in addition, the uninterrupted service life of the apparatus is severely limited, namely because on the one hand, the individual openings in the gas distribution grids during operation become clogged by particles of the feed, so that the chlorine contact with the melt is disturbed, and on the other hand the gas distribution grids by hydraulic shocks and vibration can be damaged.

In another known apparatus for the production of urine-free Magnesium chloride (GB-PS 1 478 864) is the function of the gas distribution grids of an attachment made of pieces of a carbonaceous material exercised over are distributed throughout the volume of the chlorination tower.

However, the attachment made of the carbonaceous material will eventually covered by mud, which requires periodic repair and replacement of the attachment makes necessary.

The apparatus consists of a tower which is designed so that the Magnesium chlorine salt melt with a pump through heated pipes in the upper part of the rectangular tower of chioration, the one with the top made of pieces a carbonaceous material is filled. Simultaneously will chlorine and hydrogen are fed to the lower tower section via heated pipes by the means for supplying chlorine in countercurrent to the melt flowing down into the Tower to be headed.

Compared to the apparatus described first, the height of the The chlorination tower is significantly enlarged, which means that the chlorine comes into contact with the melt is extended. However, the contact of the chlorine and melt streams is due to the Sludge deposition on the attachment made of the carbonaceous material non-uniform.

In addition, because of the pump, the apparatus is used to generate a melt flow about the chlorination tower and because of the special devices for pumping the melt very complicated.

In addition, the operation of the apparatus is extremely labor-intensive Cleaning the chlorination tower to periodically remove the sludge, severely impaired.

Another well-known apparatus for chlorinating molten magnesium chlorine salts, on which the invention proceeds, has a lined with a fire-resistant fabric conical housing with a lid, electrodes, a gas distribution grate, means for the chlorine supply as well as nozzles for the inlet of the starting melt and to the outlet the chlorinated melt (SU-PS 532 391). The gas distribution grate consists of horizontal blocks arranged one above the other, the longitudinal axes of which are offset from one another. the Means for the chlorine supply are in the housing walls below the grate in the built into the most tapered lower part of the apparatus.

This construction allows the contact area between chlorine and to enlarge the melt due to the tapering of the apparatus downwards, so that a sufficiently high gas and melt velocity in the lower part the chlorine supply is achieved.

This apparatus is significantly simpler from a structural point of view as the previously described known apparatus, has a longer service life and above all, the grate is built more simply.

This construction can only be used in devices with a small capacity can be used because an increase in diameter increases the homogeneous distribution of chlorine in the melt volume affect the mechanical loads on the construction elements increase considerably and result in a less reliable fastening of the Rostklötzo would lead.

Attempts to run this apparatus because of the gas distribution grids to overcome difficulties that arise by changing their construction, remained unsuccessful.

The block grids are admittedly in relation to the mechanical loads The use of the grates as such is more stable and structurally easier to implement however, prevents the melt from mixing in the chlorination room. Consequently sludge settles on the bottom of the apparatus.

In summary, it can be stated that in the known apparatus There is insufficient contact of the melt for chlorinating magnesium chlorine salt melts with which chlorine is reached and a sludge forms on the bottom. can settle. It exists hence a need for much improved apparatus for chlorinating molten metals Salts, thus the increased need for chlorine and magnesium by increasing their specific performance and extension of their service life can be sufficient.

The invention is therefore based on the object to provide an apparatus for To create chlorine of molten magnesium chlorine salts, with which the chlorine and Let the melt circulation speed increase so that a sludge deposition on the Soil prevents an effective chlorine utilization achieved and an increase in specific performance is secured.

This task is performed by an apparatus for chlorinating molten magnesium chlorine salts, which contains a casing lined with a refractory material, the walls, a Base and a cover, provided in the upper parts of the housing walls middle for the inlet of the starting melt and for the outlet of the chlorinated melt and has means for supplying chlorine in the lower parts of the housing walls, solved according to the invention in that the housing cavity is tapered downward so that its passage cross-section in the plane of the means for the chlorine supply to the Place their center at the mouth in the cavity (2) no more than 0.3 times of the passage cross-section of the housing cavity in the plane of the means for the Melt inlet and outlet at the point of their center at the mouth into the cavity (2) is.

Tests have shown that precisely with this ratio of the passage cross-sections of the housing cavity ensures an even distribution of chlorine over the entire melt volume and consequently a more effective use of chlorine when chlorinating the admixtures , whereby the specific apparatus performance is significantly increased overall.

In an advantageous embodiment, the inventive Apparatus in the housing cavity at least one upwardly tapering partition which is built into the floor and the housing cavity down in itself rejuvenating chambers open from above divides, with the means for the supply of chlorine are arranged on both sides of the partition. The height of the upward tapering The partition wall is intended to provide the distance between the floor and the level of the means for exceed the chlorine supply at least twice.

Chlorine is separated from the chambers formed by the partition wall fed.

The cone-shaped one standing on the ground, tapering towards the top Partition wall increases the chlorine and melt circulation speed and accordingly the equipment performance.

Thanks to the attachment of the partition wall with the specified height takes place in the communicating chambers in the lower part of the housing cavity an intense Mixing of melt and chlorine takes place in the entire volume of each chamber, thereby one Sch1armmansammlungt on the floor excluded and a more active one Chlorination of the admixtures is achieved.

Conveniently, in an apparatus with a large capacity more than one partition can be provided.

In another embodiment, there are two in the housing cavity intersecting partition walls built into the floor and tapering upwards, one of which on the longitudinal axis of the apparatus and the other on the transverse axis of the apparatus is arranged. The means for the chlorine supply are on both sides arranged one of the partition walls.

The arrangement of two intersecting partitions to form four chambers tapering downwards guaranteed with simple construction and large capacity ensures optimal operation.

The distance from the floor to the level is advantageously Means for supplying chlorine less than 0.1 times the distance from the bottom 4 to to the level of the means for the inlet of the starting melt and for the outlet of the chlorinated Melt.

The arrangement of the means for the chlorine supply at this height distance from the bottom prevents sludge from building up on the bottom, making the labor-intensive There is no need to remove sludge and a long, uninterrupted service life is possible is.

The apparatus of the invention has the advantage that its performance in The average can be increased by 20 to 30% compared to the known devices can that the labor-intensive operation of the inevitable sludge removal does not apply, the operating time is reduced in the case of uninterrupted use in presence of aggressive media up to 1.5 to 2 times that of known devices its capacity can be increased significantly, i.e. 2 to 3 times can, its construction and operation are simplified and its components are simple can be produced and assembled.

The invention is explained in more detail, for example, with the aid of the drawing. It shows 1 shows an apparatus for chlorinating molten magnesium chlorine salts in vertical section; Fig. 2 shows an apparatus as in Fig. 1 with a built into the ground, upwardly tapering partition and FIG. 3 shows an apparatus with two intersecting Partition walls in plan view.

The apparatus shown in Fig. 1 for chlorinating molten magnesium chlorine salts has a housing 1 lined with a refractory material (Fig. 1). The inner one Cavity 2 of the housing 1 is made up of walls 3, a floor 4 and a cover 5 educated. In the lower part of the walls 3 of the housing 1 are Tiittel 6 for the supply of chlorine in the cavity 2 of the housing 1 arranged symmetrically, which consists of a Nozzle system exist. In the upper part of the hands 3 of the housing 1 there are means 7 for the inlet of the starting melt and means 8 for the outlet of the chlorinated Melt mounted. The means 7 for the inlet of the starting melt consists of a nozzle in the wall 3 of the housing 1 of a melting chamber, not shown connects to the cavity 2 of the apparatus. Similar is in the opposite Wall 3 of the housing 1 as a means 8 for the outlet of the chlorinated melt, a nozzle arranged, the cavity 2 of the apparatus with a settling space, not shown connects.

In one of the walls 3 of the housing 1 there is an opening 9 for removal of the gaseous products. Through the cover 5 are in the Cavity 2 of the housing 1 introduced at least two heating electrodes 10. aside from that a partition 11 is arranged in the cavity 2, which is supported on the walls and in the upper part of the cavity 2 is mounted so that it is in the plane divides the means 7 and 8 for the inlet and outlet of the melt into two parts, wherein opposite one side of the partition wall, the means 7 for the inlet of the starting melt and opposite the other the means 8 for the outlet of the chlorinated melt arranged is.

The housing 1 tapers downwards and is inside with a refractory fabric 12 lined. The inclination of the walls 3 can be over the entire length be uniform, as Fig. 1 shows. The walls 3 of the housing 1 can also only be inclined in the lower part and that from the bottom 4 up to the plane that is at least twice as high above the floor 4 as the plane in which the axes of the means open into cavity 2 for the chlorine supply.

The passage cross section F1 of the cavity 2 of the housing 1 is in the plane of the means 6 for the chlorine supply at most 0.3 times the cross-section of the passage F2 in the plane of the means 7 and 8 for the melt inlet and outlet. Only this The ratio of the passage cross-sections F1 and F2 ensures activation of the chlorination process not only in the vicinity of the connection for the chlorine supply, but in the entire cavity volume of the apparatus, whereby its volume can be increased indefinitely.

This degree of tapering of the cavity 2 of the apparatus results in an optimal one Contact area between chlorine and melt and thus an increase in gas and Melt velocities close to the means for supplying chlorine.

An increase in the ratio of the passage cross-sections F1 and F2 would result in more sludge settling on bottom 4 and one less cause effective use of chlorine.

In the embodiment of the apparatus shown in Fig. 2 is in the cavity 2 a partition wall 13 which tapers towards the top and which is inserted into the floor 4 is installed so that it divides the lower part of the cavity 2 of the housing 1 in two upwardly tapering upwardly open chambers 14 divided.

In this embodiment, the chambers 14 constitute two areas of one intensive mixing of chlorine and melt. Within these ranges is settling of solid sludge particles and consequently an accumulation of sludge is excluded, because the passage cross section of the two chambers 14 in the plane of the means 6 for the chlorine supply is the same Value as in the first described Embodiment of the apparatus has and at most 0.3 times the passage cross section of the cavity 2 in the plane of the means 7 and 8 for the melt inlet and outlet and because the height of the upwardly tapering wedge-shaped partition 13 the distance from the bottom 4 to the level of the means 6 for the chlorine supply at least exceeds twice.

The erection of the partition wall 13 with just this height makes it possible to intensify the process of melt chlorination in the volume of each chamber 14, because each of the indicated chambers 14 with the separate means 6 for the chlorine supply is provided.

To determine the height of the partition wall 13 is a criterion for the chlorine rate for the chlorine supply selected from the specified means 6, which is sufficient for the melt to circulate in the lower part of the cavity 2.

Due to this criterion, the height of the partition wall is reduced 13 in relation to the minimum specified height leads to a reduction in the contact area between chlorine and melt and thus to the formation of stagnation and dead areas in the lower part of the cavity 2 of the housing 1.

Since the cavity 2 communicating through the partition into smaller Chambers 14 is divided, each of which is separate with a means 6 for the chlorine supply is provided, large-volume apparatus can be used.

The number of wedge-shaped partitions tapering towards the top 13 is enlarged depending on the radiated capacity of the device. Thus, the embodiment shown in Fig. 3 has two intersecting upwardly tapering Partitions 13, one of which on the longitudinal axis and the other on the transverse axis is arranged. The means 6 for the chlorine supply are in the walls 3 of the Housing 1 arranged on both sides of one of the partition walls 13.

In this embodiment, in the lower part of the cavity 2 four chambers 14 tapering towards the bottom and communicating at the top are formed, each of which is provided with a separate means 6 for supplying chlorine.

The passage cross-section of the four chambers in the plane of the means 6 for the chlorine supply is the same as in the previously described embodiments not more than 0.3 times the passage cross-section of the cavity 2 of the housing 1 in the plane of the axial mouth of the means 7 and 8 for the melt inlet and -Spout.

The height of the partitions 13 again exceeds the distance between the bottom 4 and the level of the means 6 for supplying chlorine at least twice.

The volume of the embodiment shown in Fig. 3 can be opposite that of the embodiments of FIGS. 1 and 2 can be increased, with a simple Construction and reliable operation are guaranteed.

In all of the described embodiments of the apparatus, the Distance (h) from the floor 4 to the level of the means 6 for the chlorine supply at the point their center at the junction in the cavity (2) less than 0.1 times the distance (H) from the bottom 4 to the level of the means 7 and 8 for the melt inlet and outlet at the point of their center at the mouth in the cavity (2).

The attachment of the means 6 for the chlorine supply makes it possible at this height es, the chlorine consumption at a higher assimilation factor and at a lower one reduce specific consumption. Because the Ttittel 6 for the chlorine supply are arranged at a distance from the floor 4, which is not the above sludge accumulation on the bottom is prevented.

The apparatus for chlorinating molten magnesium chlorine salts according to Fig. 1 works as follows: The electrodes 10 are connected to a power source.

The cavity is via the means 7 for the inlet of the starting melt 2 of the housing 1 filled with molten chloride salt. That at the same time as the melt Filled carbonaceous material, e.g. coconut, is placed in cavity 2 of the apparatus actively mixed and included in the chlorination process.

At the same time the means 6 for the chlorine supply is the lower Part of the cavity 2 is supplied with chlorine under a pressure which is greater than the pressure the melting column.

The chlorine fed to the lower part of the apparatus contributes to the intensive Mixing and chlorination of the solid particles. In the lower tapered Part of the cavity 2 of the housing 1 is a chlorine and melt circulation a. The mixed flow is through the chlorine in a direction from the bottom to the top carried away. The melt flow takes place along the walls 3 of the housing 1 from above downward.

Because of the ratio of the through Oantns cross-sections according to the invention of the cavity 2 of the housing 1, an intensive exchange of substances takes place in the apparatus and chlorination in the entire volume of the housing 1 without the formation of stagnation areas and without sludge settling.

The chlorine supplied to the cavity 2 prevents deposition of solid particles on the bottom 4 and thus chlorinated or via the means 8 for the outlet of the chlorinated melt into the settling area together with the melt reach. Gaseous products are sucked into the ventilation system through the opening 9.

In the embodiments of the apparatus of FIGS. 2 and 3, the chlorination process takes place in each chamber in front of you.

In the chlorination process thus carried out, the composition becomes the melt more homogeneous. For example, the magnesium oxide content is 2 to 3 O, o reduced to 0.4 to 1%.

Due to the ratio of the passage cross-sections according to the invention F2 and F1 of the cavity 2 thus become the circulation speed of chlorine and Melt not only in the vicinity of the means 6 for the chlorine supply, but also in the The entire volume of the apparatus increases, causing sludge to accumulate on the bottom 4 prevented, so that sludge removal from the apparatus is superfluous and thereby the uninterrupted service life of the apparatus is increased.

Claims (4)

Apparatus for chlorinating molten magnesium chloride salts. PATENT CLAIMS 1. Apparatus for chlorinating molten Magne siumchlorsalze with a housing whose The inner surface is lined with a fireproof fabric and that extends downwards tapers and has walls, a bottom and a cover, being in the top Wall sections Means for the inlet of the starting melt and the discharge of the chlorinated Melt and means for the supply of chlorine are provided in the lower wall sections, in that the passage cross-section of the cavity (2) of the housing (1) in the plane of the means (6) for the chlorine supply at most that 0.3 times the passage cross-section in the plane of the means (7 and 8) for the The inlet of the starting melt and the outlet of the chlorinated melt is. 2. Apparatus according to claim 1, characterized in that g e k e n n z e i c h -n e t that in the cavity (2) of the housing (1) at least one built into the bottom (4) Partition wall (13) is attached, which tapers upwards and the cavity (2) of the housing (1) in upwardly open chambers (14) divides, the means (6) for the chlorine supply are arranged on both sides of the partition (13), the height of which is at least is twice as large as the distance from the floor (4) to the level in which the means (6) are arranged. 3. Apparatus according to claim 2, characterized in that g e k e n n z e i c h -n e t, that in the cavity (2) of the housing (1) two intersecting and tapered upwards Partitions (13) are attached, one of which on the longitudinal axis of the apparatus and the other is arranged on the transverse axis of the apparatus, the means (6) for the chlorine supply are arranged on both sides of one of the partition walls (13). 4. Apparatus according to claims 1 to 3, characterized in that g e -k e n n z e i c h n e t that the distance from the bottom (4) to the level of the means (6) for the chlorine supply less than 0.1 times the distance from the floor (4) to the level of the center (7, 8) for the inlet of the starting melt and for the outlet of the chlorinated melt amounts to.