DE881211C - Device for generating steep surge voltages - Google Patents

Description

Device for generating steep surge voltages For generating from high alternating voltage impulses one can, according to T e s l: a, as is well known, one Capacitor, use which is located over the primary winding of an ironless transformer and discharges a radio link connected in series with this winding. This forms the primary winding of the Tesla transformer with the capacitor and the spark gap a dampened oscillation circuit.

In practice, however, there is seldom or never a need today To generate high voltages in the form of a damped vibration train; against it needed for many purposes (radio measuring devices, X-ray flash devices, etc.) steep, if possible rectangular, one-sided high voltage pulses, so-called surge voltages. As a first approximation, these can be represented by the half-wave of an electrical oscillation replace and consequently produce by an arrangement of the type indicated, if one changes this in such a way that its primary oscillation circuit approaches aperiodically is dampened.

In the aperiodic limit case, the damping resistance of an oscillating circuit must, as is well known, be the value own. Since the surge voltages that can be achieved are obviously greater, the higher the currents in the primary winding of the transformer are allowed to rise, i.e. the larger the capacitance C and the smaller the limiting resistance R, a surge voltage device of this type must be the cheaper work, the smaller the self, the production L becomes.

Thorough research has shown that one of these considerations starting at surprisingly steep and high impulse voltages, if by ferromagnetic guidance of the force field effective in the Tesla transformer as well as through extremely low-induction training of all other circuit elements and The lines of the approximately aperiodically damped oscillation circuit The formation of magnetic stray fields in this circuit is suppressed. This will- the self-induction of the circle practically exclusively on the few turns the one for coupling with the secondary circuit. serving primary coil of the Tesla transformer limited. Although the natural frequency of the oscillation circuit of a Tesla arrangement is always in the order of magnitude of io5 to io8Hz, this coil can surprisingly here with a raw, subdivided one, for example from normal Trunformatorenbleche built-up iron core, if you look at the routing of the supply lines selects for this primary winding so that these leads are not direct in all the smallest parts for coupling with the secondary circuit, for avoidance an insulation breakdown have a permissible distance. This is achieved on best by not placing the above-mentioned supply lines vertically in the usual way, but rather, parallel to the axis of the winding support from the transformer ausfü@hrt.-Für , the spark gap is achieved with a particularly low stray field if one it is designed as a cylindrical sliding spark gap or symmetrical plate spark gap and one conductor passes axially through this spark gap. On the capacitor the formation of a stray field is best suppressed by the fact that one of the usual way on opposite end faces from the condenser or the supply lines led out of the Köndens atomic chain one immediately; the other over, one over the oscillating: overarching circular capacity Cage connects to the associated elements of the resonant circuit: This cage shields at the same time all electrical, stray fields and can be used to suppress radio interference. if necessary, can also be pulled over the spark gap.

The invention is in the following with reference to the drawings: supplementary explained. Of these, FIG. 1 shows a schematic representation of one according to the invention designed arrangement for the generation of surge voltages with a flank, ündernr down to about io-s Sel-Fig. 2 a further _improved arrangement of these Type for impulse voltages with a flank width of only about io--? Seconds, Fig. 3 . the design of the cage for two capacitors connected in series and Fig. 4 the design of the cage for two capacitors connected in parallel.

According to FIG. I, those on the end faces are: the one shown in section Winding body protruding assignments of the capacitor i with the sheet metal disks 2 and 3 soldered. The connection, sheet 2 is connected to the cage 4, either from a pot surrounding the capacitor or, for example, also three symmetrically may consist of rods or strips raised to one another on the capacitor. The connecting plate 3 is via the low-induction resistor 5 directly to the one pole core spark gap 6 connected. The cable 7 connected to the cage 4 is as tight as possible passed the spark gap 6 and leads to the primary coil 8 of the transformer, which is equipped with a laminated iron core 9 and its secondary coil io feeds the consumer i z.

The primary coil 8 consists of only two turns and lies on one Insulating tube 12. On the inside of this insulating tube 12, the cable 7 is parallel routed to the pipe axis c-b. This is also the case: return cable 13 - parallel to the Tube axis a-b in an inner surface line of this insulating tube 12, which of the cable? only has the distance d required to prevent breakdowns. The return cable 13 is connected to the other pole of the symmetrical plate spark gap 6.

The supply voltage derived from. a rectifier 14 is supplied, flows to the. Capacitor i via the traveling wave blocking resistors 15 and 16 to. the individual discharges of the spark gap are made in a known manner by an auxiliary spark gap ignited that of one pole of the spark gap 6, and the one centrally through this Pole rear-end-guided ignition electrode 18 fed from an ignition coil 17 is formed will. The time interval between the individual ignitions is of course large enough to choose to fully recharge the capacitor in the meantime i from the voltage source 14 to enable.

The peak currents; the one when discharging a capacitor i in such; approximated to the aperiodic limit. for the oscillation circuit i, 6, 8 damped arrangement is obviously the larger, the smaller the damping resistance 5 can be measured. It has been shown that the smallest. Deviations from the parallel course of the two cables 7 and 13 are sufficient, to force such a strong increase in the damping resistance 5 that a very noticeable. Output power drop results. The closer you get. on the other hand the Cables 7, 13 move closer to one another and the more carefully you do it, so do all the others -Place. the origin of magnetic, -trending outside of the iron core 9 Avoid stray fields, the smaller the damping resistance 5 can be dimensioned. You can even do it completely dispense with either the required attenuation by corresponding (d rough subdivision of the transformer core 9 completely in the iron (which benefits the coupling between the coils and io comes), or if you also use completely or partially concentric line routing the last magnetic stray fields are suppressed.

An arrangement of this type with two capacitors connected in series, Fig. 2. -The capacitors 19, 20 are connected by the pin 2i mitein.-walls r and enclosed by the cage 22, which is connected to the tube 24 through the washer 23 is. The tube 24 ends in the tungsten ring 25, in which the ceramic cylinder 2: 6 is clamped. The tungsten ring 27, which is connected to the tube 28, is seated on the head of the ceramic cylinder 26. The Wolf = -ramrings 25 and 27 form with the. ceramic cylinder 26, a sliding spark gap, which is ignited by the ring-shaped ignition electrodes 29 and 3o embedded in the cylinder 26 as soon as it passes through the capacitors; 3i, 32 from the control unit 33 a corresponding voltage surge is supplied.

The cable 3.4 is connected to the pole of the capacitor i9 facing away from the connecting pin 21 and leads through the pipe 2q.,: The ceramic cylinder 26 and the pipe 28 to the primary winding of the surge transformer 35; the return line from the primary winding to the spark gap takes place via the tube 28 which surrounds the cable 34. In arrangements of this type, the value .4 so small that the integration of a special damping resistor with sufficient power consumption of the consumer can be completely dispensed with and, as a result, peak currents of tens of thousands of amperes can be obtained even in the approximately aperiodic limit case with capacitors of a few microfarads and primary voltages of 10 to 20 kV. The entire discharge process takes place within about 2 - 10 -7 seconds, and since time spans of less than 10 -6 seconds are already in the order of magnitude of the propagation time of magnetism in iron, rn is used per se for arrangements in which the natural frequency of the oscillating circuit is above 0.16 Hz, expediently an E-shaped iron core of the type shown.

A capacitor of o, i ßF stores operating voltage at io, ooo V known to be the energy of 5 wattsec. Comes: this energy in 2- 1o-7 seconds to take effect, then 25,000,000 W are developed in this period of time, of which about half, .d. H. around 12 to 15 MW, consumed by the consumer A consumer with high voltage and low power requirements (X-ray flash tube or the like) surge voltages can already be generated with these extremely modest means from ioo to iooo kV with io to ioo A peak current, a consumer of small size Voltage and high current requirements, e.g. B. an electric welding machine, instantaneous currents of up to z; u 500,000 A at a voltage of a few volts.

The importance of the described cage arrangement for the capacitor i or for the capacitor chain i9, 20 can be seen from FIG. 3, the .eine schematic Section through a capacitor with center allocation B, the dielectric layers, D1 and Dz and the external assignments A1 and: Q2 as well as the return conductor cage bars Ei and 112 reproduces. The - during the discharge process by de, n displacement current im Closed dielectric circuits are apparently dated in the directions of the arrows Electricity flows through them and therefore generate oppositely directed magnetic Stray fields which, for example in the sense of the effect of bifilar windings, are directed outwards practically cancel each other out. Does the. Capacitor z. B. the shape of a cylindrical bobbin, it arises rather only within the area enclosed by the cage Capacitor space a closed magnetic ring field. Similar proportions tremble for the concentric ladder systems of Fig.2.

In practice there is often a need to increase the capacity of the oscillation circuit not from capacitors connected in series, but from capacitors closed in parallel build up. In this case one then needs to achieve equivalent @er who Suppression of all external magnetic interference fields guaranteeing conditions -a double cage of the type of Fig. 4. The capacitor 36 is with the. capacitor 37 through, the pin 38 connected. The inner cage 39 is connected to this pin 38, from which the supply line leads to one pole of the spark gap d.o. The two others Allocations of the capacitors 36, 37 are interconnected by the outer cage .ti connected to which the pipe 4.2 is connected. This leads to the primary coil 43 of the surge transformer. This serves as a concentric return line from the transformer in the tube 42, the cable is located, which is at the second pole of the spark gap .4o.

Claims (6)

PATENT CLAIMS: i. Device for generating steep impulse voltages by transforming the discharge current arising in the circuit of a spark gap, characterized in that magnetic stray fields are created by ferromagnetic guidance of the magnetic force field effective in the transformer and by extremely low-induction design of all other circuit elements and lines of the approximately aperiodic oscillating circuit this circle is suppressed. 2. Device according to claim i, characterized in that that the leads (7, 13) to Primary winding (ä) of the transformer parallel to the axis (a-b) of the winding carrier, (i2) led out of the transformer are. 3. Apparatus according to claim i, characterized in that the spark gap as a cylindrical sliding spark gap (25-27) or as a symmetrical plate spark gap formed and one conductor (34) passed axially through this spark gap is. 4. Apparatus according to claim i, characterized in that of. .den in usual Way on opposite end faces from the capacitor (i) or from the capacitor chain (ig, 2o) 'lead out leads. the oscillating, circular 'capacity the one (5; 34) directly, the other (7, 24) via an overreaching capacity Cage (4, 22) is connected to the associated elements .des resonant circuit. Device according to claim 4, characterized in that the oscillating circuit: s capacity overlapping cage (4i) is pulled over the spark gap (4o). 6. Device according to claim i or the following, in particular for arrangements in which the natural frequency of the resonant circuit is above o, $ MH, characterized in that the Tesla transformer inside and outside by the iron of its preferably E-shaped core is assaulted.