EP0457037A1 - Spark gap electrode for lithotripsy - Google Patents

Abstract

Spark gap for underwater shock wave generation, in particular for non-invasive lithotripsy, with a coaxial arrangement of an inner conductor (IL) with an inner electrode, an insulation (I) and an outer conductor (AL) with a bracket (B) and outer electrode, the outer diameter of the inner conductor (IL) is relatively small compared to the inner diameter of the outer conductor (AL), the inner conductor (IL) is considerably shorter than the outer conductor (AL) and the outer conductor (AL) protrudes beyond the inner conductor (IL) at the rear end of the spark gap, the spark gap contains within the insulation (I) a cavity (HO) which is open in the direction of the rear end of the spark gap and which is limited in the opposite direction by the inner conductor (IL) itself and its enclosure by the insulation (I). This version is easy to manufacture and much lighter than previously used spark gaps. <IMAGE>

Description

The invention relates to a spark gap for underwater shock wave generation, in particular for non-invasive lithotripsy, with a coaxial arrangement of an inner conductor (IL) with an inner electrode, an insulation (I) and an outer conductor (AL) with a bracket (B) and an outer electrode.

Such a spark gap is known from DE-PS 26 35 635 and forms the preamble of claim 1. From DE-PS 35 43 881 a spark gap with optimized field line distribution is known.

The object of the invention is to improve a spark gap for the generation of shock waves in such a way that it can be produced more cheaply.

This object is achieved according to the invention by a spark gap with the features of claim 1. Embodiments of the invention are the subject of subclaims.

• a) Mechanische Halterung der Innenleiterspitze
• b) Elektrische Isolierung zwischen Innen- und Aussenleiter.

Der Innenleiter kann nunmehr relativ klein dimensioniert sein, z.B. durch einen relativ schmalen Metallstift realisiert sein. Die mechanische Stabilität wird jetzt

• im Gegensatz zu bisherigen Funkenstrecken, deren Formgebung im wesentlichen dem Innenleiter folgte - von der Isolierung aufgebracht werden. Durch diese Metalleinsparung kann das Gesamtgewicht der Funkenstrecke reduziert werden.

The spark gap according to the invention has an inner conductor, the Outer diameter is relatively small compared to the inner diameter of the outer conductor. The inner conductor is also considerably shorter than the outer conductor, and the outer conductor projects beyond the inner conductor at the rear end of the spark gap. The spark gap has a cavity inside the insulation which is open in the direction of the rear end of the spark gap and is delimited in the opposite direction by the inner conductor itself and its enclosure by the insulation, so that a kind of "hat shape" of the insulation arises .
The internal inner conductor contact saves material, which leads to lower manufacturing costs and, due to the lower weight, also to lower transport costs. An embodiment of the spark gap according to the invention has a higher mechanical strength due to a thicker bow to the outer conductor tip, which results in a longer service life. In a further embodiment, the bow arms can be rotated about the longitudinal axis of the spark gap, so that a resilient effect is produced. The arms of the bracket then do not run parallel to the longitudinal axis of the spark gap, but enclose an angle ≠ 0 ° with it, which makes them act like a torsion spring. The hanger material can be chosen the same or similar to the lace material in all versions. The insulation is preferably made of an injection molded plastic and fulfills the functions:

• a) Mechanical holder of the inner conductor tip
• b) Electrical insulation between inner and outer conductors.

The inner conductor can now be dimensioned to be relatively small, for example realized by a relatively narrow metal pin. The mechanical stability is now

• in contrast to previous spark gaps, the shape of which essentially followed the inner conductor - are applied by the insulation. By this metal saving can reduce the total weight of the spark gap.

The ratio of the inner diameter of the outer conductor to the outer diameter of the inner conductor is preferably in the range from 3: 1 to 8: 1. The length of the inner conductor is preferably 20-60% of the length of the outer conductor.
In one embodiment, the field line inclination is optimized, which results in a more uniform ignition (less scatter) and a longer service life. This is achieved by suitable shaping of the interface between the insulator tip and water in the tip region of the inner conductor, in accordance with the features disclosed in DE-PS 35 43 881 , in particular the stronger version of the insulator tip. This results in a field line focusing (constriction) on the axis, which leads to a more uniform spark jump.

In an advantageous embodiment, a bracket with an even number of arms, in particular with only two arms, is used to hold the outer electrode. This results in less shading of the shock wave than in models with more arms, higher efficiency and a longer service life if the arms are dimensioned accordingly. In one version, they can consist of 2 mm thick material, e.g. from steel.

In a further embodiment, the spark gap is surrounded by a second insulation which has projections which engage in incisions in the outer conductor and extend as far as the inner insulation. This gives the spark gap high mechanical stability.

The invention is explained in more detail with reference to two figures.

Both figures each show an embodiment of a spark gap according to the invention. The inner conductor IL is separated from the outer conductor AL by the insulation I. The coaxial design of the two conductors IL and AL can be clearly seen. The outer conductor AL is surrounded by a second insulation I2. The two arms of the bracket B, which carry the outer conductor electrode, are fastened to the outer conductor AL on the left-hand side. The inner conductor IL tapers on the left side to the inner electrode, which lies opposite the outer electrode. The inner conductor IL has a strong embossing (corrugation) with which it is anchored in the injection molded part of the insulation I. It can be clearly seen that the outer diameter of the inner conductor IL is relatively small compared to the inner diameter of the outer conductor. The outer conductor AL is considerably longer than the inner conductor IL and protrudes far beyond the inner conductor at the rear end of the spark gap. The spark gap has a cavity HO within the insulation I, which is open in the direction of the rear end of the spark gap and which is delimited in the opposite direction by the inner conductor IL itself and its enclosure by the insulation I. The cavity HO in this embodiment has a length, measured along the main axis of the spark gap, of several cm.

The insulation I carries this inner conductor IL and protects it from shifts. The cavity HO in the insulation I runs like a cylinder or - as drawn here slightly conical and can thus be used for easy placement on the current-carrying connector. At the rear end, the outer conductor insulation 12 is reinforced in a ring, so that the spark gap on this ring can be easily pulled out of the device.

1 shows a section through a spark gap according to the invention along the line A-A. The coaxial structure with the inner conductor IL, the surrounding insulation I, the outer conductor AL and the second insulation I2 can be clearly seen again. The cut A-A is made at the point at which the outer conductor AL has openings through which the outer insulation I2 can penetrate through to the inner insulation I, which provides a kind of snap lock for the secure connection and the simple production of the entire spark gap.

Fig. 2 shows an embodiment of a spark gap according to the invention with twisted bracket arms B, which thereby show a stronger spring action. The entire length of the arms extending from the insulator does not run parallel to the main axis of the spark gap, but twisted against it (axis of rotation is equal to the main axis of the spark gap). Also possible - but not shown - is a version in which the bracket arms come out of the insulator parallel to the main axis of the spark gap, run somewhat obliquely after a kink, and again run forward parallel after another kink.

Claims (5)

Spark gap for underwater shock wave generation, in particular for non-invasive lithotripsy, with a coaxial arrangement of an inner conductor (IL) with an inner electrode, an insulation (I) and an outer conductor (AL) with a bracket (B) and outer electrode, the outer diameter of the inner conductor (IL) is relatively small compared to the inner diameter of the outer conductor (AL), characterized in that the inner conductor (IL) is significantly shorter than the outer conductor (AL) and the outer conductor (AL) protrudes beyond the inner conductor (IL) at the rear end of the spark gap, - The spark gap within the insulation (I) contains a cavity (HO) which is open in the direction of the rear end of the spark gap and which is limited in the opposite direction by the inner conductor (IL) itself and its enclosure by the insulation (I) . Spark gap according to one of the preceding claims, characterized in that the bracket (B) has an even number of arms, in particular two arms. Spark gap according to one of the preceding claims, characterized in that the outer conductor (AL) is surrounded by a second insulation (I2). Spark gap according to Claim 3, characterized in that the outer conductor insulation (I2) is enlarged in the form of a ring at the rear. Spark gap according to one of the preceding claims, characterized by a twisted design of the arms of the bracket (B), so that they extend in whole or in part at an angle ≠ 0 ° to the longitudinal axis of the spark gap.

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