DE258433C - - Google Patents

Description

IMPERIAL

PATEN

For the practical needs of wireless messaging, one has so far mainly used extinguishing spark gaps, which are composed of plate electrodes became. With these spark gaps is the distance between the opposing discharge surfaces permanently the same and cannot be changed during operation. Depending on the choice of the size of the discharge area the discharge can take place at different points in the spark space, so that the spark space is relatively lightly stressed as a result, overstressing of the material is avoided and a relatively good extinguishing effect is achieved will.

The present invention relates to a spark gap in which the spark transition cannot take place within the entire spark space, but only on one in relation to the total size of the spark space small area takes place, which is caused by a curve whose radius vector depends on the angle of rotation. Such a one The arrangement has the advantage that the distance between the shortest overlap path is achieved by rotating the electrode surfaces against one another can be changed at will during operation without affecting the absolute distance the electrode body from each other and thus the size of the overall arrangement a change learns.

As a curve corresponding to the concept of the invention, for. B. to look at a spiral, which is applied to the advantageous planar electrode surface in such a way that it protrudes beyond this surface, so that the Spark transition only between this spiral and a second one opposite it can be done.

Such an embodiment is shown in the drawing in Fig. 1 in section and in Fig. 2 in a view from above. In these figures: α denotes a two-part or multi-part housing made of insulation material, which comprises the two electrode bodies c and d and is fastened to insulators b. This housing is expediently held together by a centering ring η in such a way that it serves simultaneously with the bolt e as a guide for the upper, movably arranged electrode body c. The bolt e, which presses the two electrode bodies c and d together with the aid of a nut, is electrically separated from them by insulating bushes f. On the two electrode bodies c and d , the actual electrodes g and h are arranged as mutually symmetrical spirals in such a way that they face each other in a (drawn) central position, so that this position provides the shortest rollover path between the spiral electrodes g and h . If this shortest rollover path is z. B., as indicated in Fig. 2, 0.1 mm, the electrode spacing is increased by rotating the electrode body c in one of the two directions in that the mutual position of the two spirals is changed, as can be easily explained. The change

Claims (5)

tion of the electrode spacing can be read off directly on the calibrated scale k in millimeters and each new rollover path within the limit of 0.1 to 0.5 mm provided for this embodiment can be set using the handle i. In order to avoid unnecessary turning beyond the 0.5 mm limit, suitable stops m are provided, which cause the two outermost positions of the spark gap by striking the pointer I. It goes without saying that the form in which the electrode bodies c and d are designed is irrelevant to the concept of the invention. In addition to the plate shape shown in the figure, these can of course also have a spherical shape, a conical shape or some other design. It is essential that the discharge process can take place exclusively on a curve described above. In order to be able to use the spark gap with the greatest operational reliability, it is particularly advantageous to let this curve protrude from the surface of the electrode body so that the spark transition cannot take place directly between the electrical bodies even in the outermost position. Of course, the arrangement shown in the drawing as a single spark gap can also be easily expanded as a series spark gap. The actual electrode material g, h can also consist of other, advantageously good heat-conducting material, such as the electrode bodies. Ρλ τ ε>; τ - A ν s r R ü c 11E: 1. Spark gap for shock excitation, characterized in that the spark discharges take place within the facing sides of the electrode holder between curve electrodes, their Radius vector depends on the angle of rotation. 2. Spark gap according to claim 1, characterized in that the spark discharge takes place on spirals which protrude from the flat side of the electrode holder. 3. Spark gap according to claim 1 and 2, characterized in that one, both or all electrodes are arranged rotatably with respect to one another, for the purpose of adjusting the position of the electrodes which are advantageously symmetrical to one another To change curves and thus the rollover path during operation. 4. spark gap according to claim 3, characterized in that the rollover away, d. H. the shortest distance between the curve electrodes, on a scale can be read directly. 5. spark gap according to claim 3 and 4, characterized in that the or the rotatable electrode holders are provided with stops, which allow an adjustment via the maximum limit and thus the possibility of direct spark transfer exclude between the electrode holders themselves. For this purpose ι sheet of drawings