DE19924C - Innovations in electric batteries - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 21: Electrical apparatus.

JULIUS M. STEBBINS in NEW YORK (V. S.A.). Innovations in electric batteries.

Patented in the German Empire on October 4th, 1881.

These innovations relate to such batteries, whose elements consist of cells with porous Walls are formed to separate the liquids filling the cells, and have the purpose of producing a battery with a large volume and a powerful effect a long durability connects, and at which the strength of the electricity generated can be regulated at will.

To achieve this end the inner cell of the element is at its upper part, where it is surrounded by porous walls, narrower than the lower part, that of the liquid container serves and is formed from non-porous walls. The positive and negative poles are obtained from this container Plates always have an inflow of fresh liquid, which is why this battery is constant and more powerful Effect remains until the entire contents of the container are used up.

The effect can be reduced or completely canceled by non-porous screens, which are adjustably mounted close to the porous walls of the inner cell.

In Figures 1 and 2, the containers c ¹ for the inner cells are formed from the non-porous walls of the boxes C , e are the porous walls of the inner, constricted cell which are supported by the inner, non-porous box d .

This box d stands in the upper part of the box C and its bottom forms the upper wall of the container c ¹ with the opening for the inner, narrowed, porous cell.

This construction is denoted in Fig. 1 with the number ι.

The element denoted by 2 in FIG. 1 carries the non-porous screen walls ff close to the porous walls ee , which can be adjusted depending on the desired strength of the electrical current to be generated.

The element designated by 3 of Fig. 1 is with the plates forming the poles and the shown filled with both liquids.

The zinc plate Z hangs in the inner cell, while the two carbon plates c c are in the outer cell. The inner cell with the container c ^x is filled with dilute sulfuric acid, the outer cell d, on the other hand, with double chromate of potash.

It can be seen that between the porous walls ee and the zinc on the one hand, and the carbon plates on the other hand, there are only thin layers of liquid, and consequently the electric current has little resistance in them.

In the element designated by 4 in FIG. 1, the porous walls e are exposed, so that the liquids are exposed to the full effect of the electric current, while the inner cell of the element designated by 3 in FIG the effect of the electric current is interrupted.

The electric current by passing from the positive pole or the carbon plates goes to the negative or zinc poles, finds, as mentioned, only a low line resistance and is therefore again with great strength from the negative pole to the positive through the Return line.

By the strong action of the current would at the short distance between the zinc and carbon plates, and be decomposed rapidly, the latter at the small thickness of the liquid located between the same, if not in the Mafse their decomposition again new liquid from the container c ^l by the porous walls and the zinc plate would rise. This happens when the specific gravity of the fluid in the inner cell is smaller than that of the outer cell, through the following process:

As soon as part of the fluid filling the outer cell is drawn into the inner cell by the endosmotic action of the porous walls, the specific gravity of the fluid in the inner cell, which is in direct contact with the zinc plate, will be increased and it will gradually sink into the lower container c ¹ where it mixes with the liquid there and the heavier components are deposited on the ground. In contrast, the lighter, undecomposed liquid of the container c ^{1 will} rise to the inner cell and supply the apparatus with fresh, current-conducting liquid.

Otherwise, if the fluid in the outer cell d is specifically lighter than that in the inner cell, the latter, when exposed to the action of the galvanic current, will gradually sink due to its decomposition and displace ^{just as much of the undecomposed fresh fluid from the container i 1} and drive them up to maintain the activity of the electric current. In both cases, therefore, the new, peculiar shape of the inner cell, which is narrowed at the top and wider at the bottom, produces a powerful and constant, constantly renewing current.

The four elements of the apparatus shown in FIG. 1 stand on a plate rotating around the pin aa , which is shaken back and forth by the arm b , by means of a mechanism attached to the frame AB. The zinc and carbon plates are suspended from the upper cross bar connecting the uprights BB.

3 shows a modified shape of the inner cell d ¹ , which rests on the bottom of the outer cell C ² and carries the inner cell consisting of porous plates e ¹ e ^1. Both parts of the inner cell, the upper porous part as well as the lower reservoir d ¹ , are surrounded by the liquid of the outer cell. The non-porous screen walls for regulating the electrical activity of this element are the same as in Fig. 1, and the effect of this element is the same.

Claims (3)

Patent Claims: 1. In the element of an electric battery, the shape of the inner cell, the upper cell Part, formed from porous walls, communicates with the lower further part, formed from non-porous walls. 2. On the element of an electric battery, the outer cell, which the inner cell Porous walls are formed and down into a container with non-porous Wall-widening cell encloses, in connection with the positive and negative Pole-forming plates, which are suspended so that they are close to the porous wall. 3. On the element of an electric battery, the porous walls of the inner cell in connection with non-porous, adjustable and close to the porous walls are located screen walls for the purpose of regulating the strength of the generated electric current. ¹ For this purpose I sheet drawings.