EP2957033A1 - Inductive tension addition unit - Google Patents

Abstract

The invention relates to an inductive tension addition unit (1), comprising a coaxial conductor structure comprising an internal conductor (2) and an outer conductor (3) that is divided into a plurality of outer conductor sections (4) corresponding in each case to an amplification stage, wherein the outer conductor sections (4) are coupled by the voltage sources (8) supplying voltage pulses to be added and the outer conductor sections (4) form an impedance avoiding a shortcut between two voltage sources (8) together with an impedance structure (9) when voltage pulses that are to be amplified are given, wherein the outer conductor section (4) is completely interrupted in a non-conductive manner at least at one point (11), in order to form two portions, and the portions of the outer conductor sections (4) are connected by the impedance structure (9) having a blocking effect for a frequency band comprising a frequency defined by the length and form of the voltage pulses.

Description

description

The invention relates to an inductive voltage addition device, comprising a coaxial conductor structure with an inner conductor and an outer conductor divided into a plurality of outer conductor sections corresponding to one respective amplification stage, the outer conductor sections being coupled by the voltage sources supplying voltage pulses to be added. The outer conductor sections, together with an impedance structure between any two adjacent voltage sources, form a short circuit for the impedance to be amplified for avoiding voltage pulses.

Pulse generators for generating voltage / current pulses are already known in the prior art. In electrical engineering in the field of Pulsed Power Technology (English "pulsed power") high-voltage and high-power pulses of egg Nigen kilowatts to several hundred terawatts for wis ^¬ tific and industrial purposes required whose Lie in ^¬ pulse take in the nanosecond to microsecond range ,

As an example of the application areas of such pulse generators reindeer is called electroporation, a industrial applicati ^¬ dung. There, a pulse generator is required which generates voltages of typically 250 kV and currents of a few 10 kA in pulses with a pulse duration of 1 ys to 2 ys. Such a pulse generator can be realized as an inductive voltage adder (IVA) Inductive voltage addition devices offer a compact design, since they are composed during pulse generation as a series connection of n discrete voltage sources.

Inductive voltage addition devices have been known for some time in the prior art, reference being made, for example, to the book by Hansjoachim Bluhm, "Pulsed Power Systems", in which Springer-Verlag, 2006, where the principle of voltage addition and in particular voltage addition by inductive isolation is explained in detail in Section 7.2, which disclosure is hereby incorporated by reference into this description. Briefly provides an inductive voltage adder in the steady state during charging are wired in parallel memory ^¬ capacitors as power sources that are uncoupled during the pulse phase via an inductor and conditionally assembled by the topology of the inductive voltage adder with a series circuit, wherein the wave properties, due to the Reflection factors, be used during the switch-on and in the stationary state to increase the voltage amplitude.

Specifically, this means that similar to a serial arrangement of voltage sources, pulse lines can be implemented as voltage multiplier circuits by connecting the positive conductor of one line to the negative of the other. Thus no short circuits occur in alternating connection of the circuit, the Verbin ^¬-making must be isolated for the duration of the pulse. During use cable ^¬ transformers for this purpose sufficiently long Übertra ^¬ supply lines using a term decoupling in an inductive voltage adder coupling is provided with a sufficiently high coupling inductors. This means that a high impedance is generated by the coupling inductances at the frequencies of the voltage pulses, which avoids the short circuit, so that the coupling inductances can also be understood as impedance structures. The use of coupling inductors results in a compact design, because the inductive insulation replaces the running time when using cable transformers. An inductive voltage ^addition device usually initially has a coaxial conductor structure with an inner conductor and an outer conductor. The outer conductor is divided into several, one adder or one stage (gain stage) corresponding Außenleiterab ^¬ sections divided, which are usually shaped so that they form at least partially enclosed by the outer conductor sections interior, so a cavity. In this case, the outer conductor sections thus annularly surround the cylindrical, in particular with respect to decreasing radii, for successive outer conductor sections stepped executed inner conductor, on which add the voltages to the output pulse. The stepped design creates a stepwise impedance matching so that the current in the structure remains constant in all stages.

Inner conductor and outer conductor of the coaxial conductor structure can be isolated by vacuum, but are also conceivable insulating gases, deionized water and the like. The outer conductor sections are coupled to each other via Ge ^¬ the voltage sources which provide the voltage pulses to be added and are usually located outside the outer conductor portions, so that the outer conductor sections are fed, for example radially. Considering the exemplified applications in the field of electroporation, for example, each of the voltage sources (and thus Verstärkungsstu ^¬ fen) a voltage pulse of typically 0.5 - 5 ys duration with a voltage amplitude of some (typically 3-10) kV and a maximum current amplitude from a few kA up to> 10 kA deliver. To generally achieve the addition of the voltage pulses and thus the voltage amplitude Vek ^¬ toraddition the electromagnetic fields in the transition region for coaxial transmission line is utilized. Thus, the voltage adding device generates an output pulse which is superimposed on the sum of the n (number of stages) individual voltage sources.

To achieve the addition of the voltage amplitudes, as already described, the positive conductor becomes a

Voltage source connected to the negative of the following. The outer conductor sections provide therefore a conductive Ver ^¬ connection between the respective terminals of the voltage sources, so that a short circuit is to be prevented by an impedance.

For this purpose, it is known in the prior art, the relative permeability for the formed by the outer conductor section

Structure to increase greatly. For this purpose, a partial volume of the interior is filled with a ferromagnetic material, for example using annular band cores, to which iron cores are usually used. In this way, a high-frequency choke is geschaf ^¬ fen on the outside of the outer conductor, the properties of which are dependent on the ferromagnetic material and the duration of the voltage pulses. The duration for which the high-frequency choke can be considered effective (volt * second product, Vs-product) is through the cross of the toroidal core and the sum of retentive and Seeds ^¬ tigungsinduktivität cut given. A suitable ferromagnetic material must have a high saturation inductance and a steep hysteresis curve. Since in the known, be ^¬ described embodiments of an inductive Spannungsaddi- tion means the outer conductor section geometry spans only a single turn, the cross-sectional area must be large from ^¬ sufficient to produce with the aid of this one turn a sufficiently large inductance The required technical ^¬ te high Impedance in the defined by the voltage pulses frequency range has. Another condition that is required is that the ferromagnetic material, which here acts as an impedance structure, does not reach saturation, since otherwise the inductance abruptly drops to low values.

Consequence of these considerations is that very large volumes are to be filled with ferromagnetic material, which brings considerable material costs, but also construction volume and design effort to master the large mass of the entire device with it.

The invention is therefore based on the object to provide an inductive ^¬ ve voltage addition means, a geringe- Res construction volume and lower production costs allowed and in particular allows longer pulse durations.

To achieve this object of the aforementioned type is for an inductive voltage addition means according to the invention provided that the outer conductor section of at least one location is pierced share completely non-conductive to the formation of two at ^¬ and the proportions of the Außenleiterab- section through the a by the Length and shape of the voltage pulses defined frequency frequency band containing a blocking effect unfolding impedance structure are connected.

The invention therefore proposes a modification of the impedance structure, that is to say the inductive isolation of the individual amplification stages, in the voltage addition device. Specifically, it is proposed to break each outer conductor section at one point completely non-conductive, thus creating an opening that forces a current flow through the impedance structure, which, as will be explained below, are not necessarily connected at the point of Durch ^¬ break got to. The knowledge that is the to ^¬ grunde is that pulse amplifier, as well as the inductive ^¬ ve voltage adder, are often created for specific purposes, are therefore operated with certain voltage pulses, which in turn define certain frequency bands in which the impedance be sufficiently high must to produce the inductive isolation. Accordingly, an impedance structure actually flowed through by the current is proposed, which blocks (only) for this frequency band.

In particular, this means that the impedance structure comprises at the plane defined by the length and shape of the voltage pulses Fre ^acid sequence one over other frequencies increased impedance value which differs in particular by at most 20% of the maximum impedance of the impedance structure. A requirement can also be formulated relative to the arrangement without an impedance structure, according to which the impedance structure then has an impedance value at the frequency defined by the length and shape of the voltage pulses, which exceeds the impedance value of the outer conductors without an impedance structure by at least a factor of 10. This means that the impedance value at the relevant frequency is at least an order of magnitude higher than that of the uninfluenced arrangement. Having enjoyed limits on the plane defined by the length and shape of the voltage pulses frequency or the frequency ^¬ band, as far as the blocking effect, no complex RF choke more needs to be realized, son ^¬ countries it is possible, reindeer other components or structures to use, which are coupled via the breakthrough and thus make it possible to realize an inductive Spannungsadditions- device both smaller and lower mass, but in particular cost-effective. Instead of the ferromagnetic material known in the prior art, other impedance structures are spatially arranged so that the current on the outside of the respective conductor portion is reduced and therefore the total current is forced to flow in the inner waveguide structure. Nevertheless, a very high blocking effect can be achieved for narrow-band voltage pulses. It is also possible to increase the inductances used and thus to reduce the losses, in particular with long pulse durations, so that even such long pulse durations, for example greater than the microsecond range, can be made possible. A saturation effect is not to be feared. Overall, a kos ^¬ tengünstigere, more compact design is given, which allows a Massenre ^¬ production.

It should be noted that despite the high impedances for the voltage pulses for the common-mode component, the inductive isolation described here via the impedance structure continues to offer extremely low impedances, which is the case for the low-frequency component. quenzaufladebereich of, for example, used as voltage sources capacitors (common mode) is required.

The generally known structure, in which the outer conductor sections give the ring-like cylindrical, in particular with respect to minifying radii for successive Außenleiterab ^¬ sections stepped executed inner conductor also arises in inductive Spannungsadditions- device according to the present invention. It should be noted at this point that the stepped from ^¬ formation of the inner conductor mainly arises for reasons of impedance matching after the reflection of the voltage pulses must be avoided at the injection points of the voltage sources, so that the impedance of the coaxial Leiterstruk- tur progressively towards Load must rise. In particular, each outer conductor section with the corresponding portion of the inner conductor can then be regarded as a generator of the impedance nZ ₀ , where n is the step, so that the waves propagating through the overall arrangement always see a matched load.

In a further embodiment of the invention, it can be provided that the outer conductor section has at least one radial component extending radially outwards relative to the voltage source, which allows, in particular, a radial supply from the voltage source. For example, a type of pot structure can be realized, which, moreover, also defines an inner space enclosed by the outer conductor section, which will be discussed in more detail below. Radial shares of adjacent Außenleiterab ^¬ sections run largely parallel so that there is a "transmission line". Such parallel run ^¬ de adjacent radial element portions can be separated by a standoff.

An advantageous embodiment of the present invention provides that the breakthrough at a transition from a parallel to the inner conductor extending coaxial section to a radially extending radial portion of the Außenleiterab ^{¬ section is} provided. It has been shown that it is possible to create a yet extremely mechanically stable Gesamtan ^¬ order in this way, especially if already spaced-extension elements extending radially to the spacing Radi ^¬ alan parts of the outer conductor section are provided.

It should be noted that the location of the breakdown or gap does not necessarily have to influence the localization of impedances for the impedance structure. Currents flow on the outer surfaces of the outer conductor section, which often have a thickness of a few millimeters, for example 5 mm, due to the mechanical stability, wherein the penetration depth is extremely low, so that it is quite possible for a current to flow on the surface facing the inner conductor of the portion of the outer conductor section extending parallel to the inner conductor flows as far as the opening, but on the other surface, until it can reach the impedance structure. But even with radial shares or shares of the outer conductor section, a current flow in several directions can be rea ^¬ lisiert. This enables the impedance structure to be electrically coupled to the outer conductor section at positions which are meaningful with respect to the overall arrangement.

Accordingly, it can be generally stated, provided that the outer conductor portions are formed to define a through them we ^¬ nigstens partially enclosed interior, where ^¬ is arranged connecting with the impedance of structure in the interior, in particular two radial portions. Particularly in the case of cross-sectional pot-shaped outer conductor sections, wherein the breakthrough, as described, may be provided in a "corner", it may be expedient to arrange the impedance structure between the radial components, so that they possibly also contribute to the overall stability of the inductive voltage adding device can, in any case, however, a space-using, easily realizable design offers. For concrete implementation of the impedance structure, there are a variety of possibilities, some of which advantageous embodiments are now to be shown in more detail.

In a preferred embodiment according to the invention it can be provided that the impedance structure is formed as a separate components comprehensive trap circuit having an inductance into ^¬ particular a coil, and a capacitance connected in parallel thereto, in particular a capacitor.

In this case, the inductive isolation of the individual amplifier stages in the inductive voltage adding device is thus realized by a discrete blocking circuit, in this case an LC parallel resonant circuit. Such a parallel resonant circuit has a high impedance at its resonant frequency, which is actually determined by the quality of the coil. It is particularly advantageous with this arrangement that with very little circuit complexity with only a single additional, commercially available component, in particular a capacitor forming the capacitance, very high impedances can already be realized in the corresponding frequency band, for which otherwise comparatively large coils are necessary would. If in an example at lower frequencies, for example, 100 kHz, corresponding pulse widths of typically 5 ys, worked, one needs in the art in Verwen ^¬ tion of a ferromagnetic material in the interior, ie at a number of turns of 1 with a ferromagnetic core, a Coil cross section of 100 cm ² , to achieve an impedance> 150 ohms. For an air coil with a coil cross section of 10 cm ^2, this would correspond to a number of turns of 100. However, air coils with a cross section of only 10 cm ² and only 30 turns are sufficient if a capacitor of 300 nF is connected in parallel. Cores of ferromagnetic Ma ^¬ TERIAL however, would require 10 times the volume, and thus about 10 times the mass and cost. Incidentally, it is also conceivable to adjust the impedance of a simple air coil by adding to cause wetting with a capacitor connected in parallel to considerably higher impedances, so that for example in egg ^¬ ner air coil with a coil cross-section of 10 cm ² and ei ^¬ ner turns of 100, the addition of a capacitor with 33 nF to an impedance in the range of 600 ohms leads, so that a significant reduction in losses is possible.

As a component, an air coil or a coil can be provided with an egg ^¬ lowering. The use of single- or multi-winding iron core coils with a parallel capacitor leads to a significant increase in the inductance, so that long pulse durations for the voltage pulses are possible even with smaller iron cores. In an expedient embodiment, at least a part of the capacity can be realized in the coil. For this purpose, there are several possibilities, on the one hand can be provided that the coil conductors consist of a copper strip, so that a coupling capacitance between the coil turns, thus the capacity either realized by the coil ^¬ who can or at least partially, so that a used Capacitor can be sized smaller. Another possibility for providing a coil with an intrinsic capacitance is the use of ceramic elements, for example ceramic rings, in the coil.

As already stated, the invention of simple design, construction volume and mass reducing from ^¬ design the impedance structure refers tied to a specific frequency. It is expedient if, depending on the output pulses to be generated, an adaptation would be possible, so that it can advantageously be provided that the capacitance can be changed at least partially via an adjusting device as a function of the pulse length and / or pulse shape of the voltage pulses, for example can be realized that a varactor is used as a component for the capacity. So this makes it possible by characteristics of the lock ^¬ circle be customized inductive Spannungsadditions- device for different configurations and output pulses.

An alternative, second exemplary embodiment of an inductive voltage addition device provides that the impedance structure is a lambda / 4 line shortened in particular by a capacitor. Such barrier structures in the prior art as well known and can be ^¬ continues to generate impedances high impedance-in rather narrow frequency bands. It is expedient if the length of the lambda / 4-line is variable via an adjusting depending on the pulse length and / or pulse shape of Spannungspul ^¬ se and / or the capacitor is designed as a varactor. For example, a tapping point can be provided which is displaceable or the like. Analogous to the embodiment of the blocking circuit can also be done via a varactor an adjustment of the effective length and thus effect of the lambda / 4-line. Thus, an adaptation of the blocking effect for different desired output pulses is also conceivable in this case.

Finally, it is conceivable in a third embodiment of an inductive voltage adder that the impedance structure is a wave trap, especially in a plane defined by the length and shape of the voltage pulses Fre ^acid sequence of more than 100 MHz. Locking pots are already known in the art, so that, for example, a Reali ^¬ tion as a cylinder ladder is conceivable, which is filled with material suitable permeability or dielectric constant, for which, for example, iron offers. This Ausges ^¬ taltung is particularly suitable for higher frequencies, wherein when iron is used as filler and a use at lower frequencies is conceivable. Such a blocking pot is a broadband realization of an impedance structure. Further advantages and details of the present invention will become apparent from the embodiments described below and with reference to the drawing. 1 shows the basic structure of an inductive voltage addition device according to the invention,

2 shows a cross section through part of the inductive voltage adding device shown in FIG. 1, FIG.

3 shows a breakthrough sectional view,

4 shows a first concrete embodiment of an impedance structure,

Fig. 5 shows a modification of the embodiment according to

4, FIG. 6 shows an equivalent circuit diagram for the inventive in ^¬ inductive voltage addition device having an impedance structure according to FIG. 4 or FIG. 5,

7 shows a second concrete embodiment of an impedance structure and

8 shows a third concrete embodiment of an impedance structure. With the aid of Figures 1 to 3 will now first of all the elementary ^¬ additional structure of an inductive voltage addition device 1 according to the invention, ie a "inductive voltage adders", are explained in detail, with present three Ver ^¬ amplification stages to be used. The core of the inductive voltage adder 1 is a coaxial Conductor structure with an inner conductor 2 shown only in the sectional views of Fig. 2 and Fig. 3 and an outer conductor 3, which in different, one amplifier stage corresponding outer conductor sections 4 is divided. Here, the outer conductor sections 4 are pot-shaped here, that is, they have, see. In particular Fig. 2 and Fig. 3, a parallel to the inner conductor 2 extending Koaxialan- part 5 and two radially extending radial portions 6 on. As shown particularly well in Fig. 2 it can be seen separated by a spacer 7 radial play form 6 Benach ^¬ barter outer conductor portions 4 a "transmission line". Stringing are coupled to the outer conductor portions 4, as known in principle, by in Fig. 1 indicated voltage sources ^¬ are 8, the thus fed radially into the outer conductor portions. in this case, the positive conductor of the voltage ^¬ sources If an output pulse every 8 connected through the outer conductor section 4 with the negative head of the following voltage source 8, so that in principle there is a conducting compound. now generated A sum of the pulses supplied by the voltage sources 8, a short circuit must be avoided, which is why an impedance structure 9 is used, which provides an inductance, which ensures a high impedance at a voltage pulse, which is the basic ^¬ principle of inductive Voltage adding is while it is from Sta According to the prior art, it is complicated to realize a non-current-carrying impedance structure by filling the inner space 10 formed by the outer conductor sections 4 with a ferromagnetic material, the invention proposes a different solution in which the outer conductor section 4 is not completely at one point is conductive broken, present as interpreting ^¬ Lich visible in Fig. 2 and Fig. 3, by a provided at the transition from the parallel portion to the radial portion 5 6 opening 11 (slit). If there is now a voltage pulse, a current flow takes place on the side of the parallel component 5 facing the inner conductor 2 up to the aperture 11, where the current flows back on the side facing the inner space 10, the impedance traverses structure 9 and in the gebil ^¬ dete on the other side "transmission line" passes.

The finding underlying the present invention is that such impedance structures 9 can be easily implemented as discrete components, which can be realized cost-consuming and consuming little space, taking into account that the high impedance, so the blocking effect ^¬ only is required for the frequencies defined by the length and shape of the voltage pulses. Thus, the impedance of structure 9 is chosen so that it blocks in a Fre ^¬ quenzband that contains the used, defined by the voltage ^¬ pulse frequency. For unused Fre ^¬ frequencies this blocking effect must not be present.

However, this means that in the common mode, ie at ^¬ play during charging of the realized for example by Kondensa ^¬ factors voltage sources 8, the impedance of structure 9 represents no significant resistance. However, if the voltage pulses are output, the inductive effect of the impedance structure 9 occurs. There is an extremely high impedance and the amplitudes of the voltage pulses can aufad ^¬ dieren, where as usual by the stepped structure of the inner conductor 2, which is shown in the figures, an impedance adaptation to avoid reflections is achieved.

The payload for the voltage pulses is then connected to the side 12 (FIG. 1) of the inductive voltage addition device 1 between the outer conductor 3 and the inner conductor 2 of the conductor structure.

Preferably, the impedance of structure 9 is thereby so designed that with the DEFINE ^¬ th by the length and shape of the voltage pulses of a frequency impedance maximum is given. For the specific embodiment of the impedance structure 9, there are several possibilities, wherein a preferred embodiment of Figures 4 and 5 can be seen. There, the impedance structure 9 is realized as a blocking circuit 13 whose resonance frequency at the frequency defined by the length and shape of the voltage pulses. In the blocking circuit 13 an inductance L realized by a coil 14 and a capacitor C realized according to FIG. 4 by a capacitor 15 are connected in parallel, as the arrows 16 indicating the current input and the current output show. The coil 14 has in this case before ^¬ lying to increase their inductance an iron core 17, and the capacitance C is realized in accordance with Fig. 4 by a separate, discrete component, namely, a capacitor 15,. Less preferably, air coils may also be used.

It should be noted at this point that a part of the capacitance C or even the entire capacitance C can also be realized in the coil 14 itself, in that the coil conductors consist of a copper strip, so that a coupling capacitance is created between the coil turns, and / or in which the coil 14 includes at least a ceramic member for generating ei ^¬ ner intrinsic capacitance. In an expedient, modified embodiment, according to FIG. 5, the capacitor 15 is replaced by a varactor 18, which is part of an adjusting device 19. Depending on the voltage pulses to be given concretely, this can be used to adjust the resonance frequency of the blocking circuit and thus of the frequency band in such a way that the magnetic insulation is achieved by the blocking circuit 13 during the voltage pulse.

Fig. 6 shows an equivalent circuit diagram of a circuit with a barrier 13 as impedance structure 9 realized inductive voltage adder 1. Clearly visible are connected by the voltage source 8 with the internal resistance R outer conductor sections 4 that face the opening 11 on ^¬. The connection between the shares is made by the blocking circuit 13. Supply the voltage source 8 per ^¬ weils a voltage Uo, is formed in this three-step embodiment, a voltage pulse of a voltage of 3 * Uo between the inner conductor 2 and the outer conductor. 3 Fig. 7 shows a further possibility for the realization of the impedance structure 9, there as a blocking pot 20, which in a

Section is shown. This is formed by a Zy ^¬ linderleiter 21, which is filled here with iron 22.

A further possibility, shown in more detail in FIG. 8, for realizing the impedance structure 9 is the use of a lambda / 4-line 23 which is shortened by a capacitor 24 in relation to a length which is necessary without the capacitor and which is indicated by the dashed line 25 can. If the capacitor 24 is designed as a varactor, here too an adjustment to different frequencies and thus different pulses to be generated is possible.

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited ^¬ by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

1. Inductive voltage addition means (1), comprising a coaxial conductor structure having an inner conductor (2) and a entspre ^¬ sponding into several, each with a gain stage outer conductor portions (4) divided outer conductor

(3), wherein the outer conductor portions (4) through said to addie ^¬ leaders voltage pulses supplied voltage sources gekop ^¬ are pelt (8) and the outer conductor portions (4) along with egg ner impedance structure (9) has a short-circuit between two voltage sources (8) form at a given, to be amplified voltage pulses avoiding impedance, characterized in that the outer conductor section (4) at least one point (11) completely non-conductive to break the formation of two shares broken and the proportions of the outer conductor section (4) by the for the frequency defined by the length and shape of the voltage pulses containing frequency band ^¬ a blocking effect unfolding impedance structure (9) are connected.

2. Inductive voltage addition device according to claim 1, characterized in that the impedance structure (9) in the plane defined by the length and shape of the voltage pulses Fre ^acid sequence comprises an over other frequencies increased impedance value, which in particular at most 20% of the maximum impedance of the Impedance structure differs.

3. Inductive voltage addition device according to claim 1 or 2, characterized in that the outer conductor section (4) has at least one radially outwardly to the voltage source (9) extending radially portion (6).

4. Inductive voltage addition device according to one of the preceding claims, characterized in that the aperture (11) at a transition from a parallel to the

Inner conductor (2) extending coaxial portion (5) to a radially extending radial portion (6) of the outer conductor portion

(4) is provided.

5. Inductive voltage addition device according to one of the preceding claims, characterized in that the outer conductor sections (4) are formed to define an inner space (10) at least partially enclosed by them, the impedance structure (9) being formed in the inner space (10). , in particular two radial portions (6) connecting, is arranged.

6. Inductive voltage addition device according to one of the preceding claims, characterized in that the im ^¬ pedanzstruktur (9) as a separate components comprehensive blocking circuit (13) with an inductance, in particular a coil (14), and a capacitor connected in parallel, in particular one Capacitor (15) is formed.

7. Inductive voltage addition device according to claim 6, characterized in that an air coil or a coil (14) with an iron core (17) is provided as the component.

8. Inductive voltage addition device according to claim 6 or 7, characterized in that at least part of the capacitance in the coil (14) is realized.

9. Inductive voltage addition device according to claim 8, characterized in that the coil conductors are made of a Kup ^¬ ferband, so that a coupling capacitance between the coil windings and / or the coil (14) comprises at least a ceramic member for generating an intrinsic capacity ty.

10. Inductive voltage addition device according to claim 6, characterized in that the capacitance is at least partially variable via an adjusting device (19) as a function of the pulse length and / or pulse shape of the voltage pulses, in particular as a component for the capacitance a varactor (18 ) is used.

11. Inductive voltage addition device according to one of claims 1 to 5, characterized in that the impedance structure (9) is in particular by a capacitor (24) shortened lambda / 4-line (23).

12. Inductive voltage addition device according to claim 11, characterized in that the length of the lambda / 4 line via an adjusting device (19) depending on the pulse length and / or pulse shape of the voltage pulses is changed derbar.

13. Inductive voltage addition device according to one of the claims 1 to 5, characterized in that the impedance ^¬ structure (9) is a locking pot (20), in particular at a defined by the length and shape of the voltage pulses Fre ^¬ frequency of more than 100 MHz.