DE267298C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 267298 CLASS 21g. GROUP

Patented in the German Empire on December 3, 1911 .

In the case of rectifiers for higher powers, the risk of a direct equalization between the anodes increases considerably with the number of anodes. On the other hand, it was again found to be low, overall performance on as many as possible in the same _vessel: distributing anodes located, namely from pure thrift reasons ,. There is therefore the task of counteracting the risk described

ίο suitable protective measures for direct compensation hold true.

Until now it is known between two anodes of different polarity to switch obstacles in the form of protective walls, and that has hoods, bells and the like are preferably used. Such known designs occupy such a large space that the vessel with a larger number of anodes becomes inappropriately large, d. H. it will not be favorable in terms of its functions exploited. One of the most important of these tasks is the creation of a regulated steam flow, d. H. the vapors must reach the cooling vessel walls in the most expedient way possible be guided and ordered as far as possible .. run.

Furthermore, the known protective caps have the disadvantage that if they have sufficient security are to offer against the risk mentioned, they must be carried out in such a length that the heat development within these caps increases extraordinarily.

According to the invention, the anodes and the associated steam are stretched by special radial cell walls separated from each other.

The advantages of such an arrangement are evident when the cell walls for the ascending Vapors offer almost no obstacle, on the other hand, however, as a result of the arbitrary large selectable expansion ensure the greatest possible protection.

It is also advantageous to have the cell walls inside and outside by special cylindrical To limit pipes, whereby the protective device is composed of several manholes Cell system forms. However, nothing stands in the way, the walls of each cell compartment to multiply.

The cell-shaped arrangement of shafts proves to be equally advantageous for any Shape of the vessel, regardless of whether the vessel is made of insulation material or has metal walls.

Fig. Ι shows another useful form of the new arrangement by transfer the outer cylindrical boundary walls into a guide wall in the form of a collecting funnel, into which all the individual steam lines flow.

Mean in this figure: a the anodes, the cathode k, q, the novel cell walls, the outer 0, in the form of a baffle-run protection wall and j> the internal chimney-like completion of the cell compartments; g is the vessel wall, and h means the protective cap against falling mercury, which can now be kept very small and does not impede the flow of steam.

It is also possible to combine two or more anodes in one cell, if the maximum occurring voltage difference harmless

is low or even zero as a result of parallel connection. A corresponding arrangement is shown in FIG. ... ^:

The inner delimiting cylinder p can also be omitted, especially when the anode is introduced from the side, the radial cell walls extending as far as the vessel axis (cf. FIG. 4). In the case of vessels with anodes introduced from above, the latter arrangement is, however, disadvantageous compared to that shown in FIGS. 1 to 3, since the good guidance of the rising metal vapors to be achieved by p is only imperfect.
Under certain circumstances, it may be useful to extend individual radial walls below the tube p to the vessel axis, especially if the risk of a current transfer is particularly high between certain anodes due to the high operating voltage.

The first material used for the cell walls is insulating material, ζ. B. porcelain, into consideration, but with sufficiently careful insulation, metal such. B. iron sheet, can be used. In Fig. 5 it is shown in which way the insulation of the metallic cell walls is to be carried out. The inner boundary wall consists of the parts. O ₁ O ₂ , the outer one from the parts P ₁ p ₂ . Only the outermost shell p ₂ consists of a single sheet metal cylinder , while O ₁ O ₂ Pi ^and 1 are connected to one another by insulating spacers ζ. This subdivision ensures that the metallic partitions do not promote any compensation between the anodes. FIGS. 4, 6 and 7 illustrate the application of the inventive concept when the anodes are introduced from the side while maintaining the reference numerals given in FIGS. .

Claims (5)

Patent Claims: ι. Metal vapor rectifier with several anodes located outside the vessel axis, characterized in that the individual Anodes or groups of anodes inside more open at the top and bottom, through vertical ones Walls of bounded cells are arranged. 2. Metal vapor rectifier according to claim i, characterized in that the individual cells have common partitions (q) . 3. metal vapor rectifier according to claim: ι and 2, characterized in that that the cell system consists essentially of two concentric and radial cylinders flat walls is formed (Fig. 1 to 3). 4., metal vapor rectifier according to claim ι to 3, characterized in that the boundary walls formed from double sheet metal layers by insulating spacers are interrupted in such a way that compensation on the cell walls is made much more difficult (FIG. 5). 5. Metal vapor rectifier according to claim ι to 4 with anodes, which of special Protective caps are surrounded, characterized in that the spherical caps are individually or open in groups into one cell each. 1 sheet of drawings.