DE330244C - Process for generating high-frequency electrical vibrations - Google Patents

Description

It has already been proposed to generate weakly damped electromagnetic oscillations by connecting two oscillating circuits consisting of capacitors with inductances in parallel to a discharge spark gap of high extinction capability, the capacitors having the same capacitance, while the self-inductions are so different that the discharge of a capacitor in radio transition to i8o ° lagging in phase from the other and thus a condensate _t sator after the end of the radio transition is repolarized while the other con- · capacitor's charge has maintained, so that now both capacitors in series are switched and discharge in the form of slightly dampened oscillations.

This arrangement ensures correct functioning and clear vibration relationships To achieve a spark gap of very high extinguishing ability a mercury vapor lamp with artificial ignition and valve action for use.

However, this device by no means delivers continuous undamped wave trains Vibrations, but depending on the ignition frequency of larger or smaller electrical Breaks interrupted trains of little dampened electrical waves.

The purpose of the present invention is now to provide a method in which by Delay of the inflow of the feed current to the occupancy of a via a quenching spark gap discharged capacitor in the leads to the capacitor electrical Oscillations of twice the voltage amplitude than that of the supply current are thereby generated that as a result of the discharge of the capacitor its assignments have their sign alternate, with the current surges causing the capacitor to be recharged Induction coils provide the auxiliary voltage required to ignite the spark gap generate yourself. The order is made so that the increase in Voltage on the spark gap electrodes induced by this higher voltage Currents are delayed by throttling, so that the ignition in each case exactly at the moment begins, in which the voltage on the capacitor assignments has become a maximum is.-

The process enables direct current from any power source, for example a DC machine, accumulators etc., to use and to generate vibrations, their voltage amplitude is higher than the electromotive force of the direct current supply.

The vibrations excited in the primary circuit are generated through the use of suitable extinguishing spark gaps very strongly damped, so that most of the energy oscillating in the primary circuit wanders over into the antenna circle.

The principle of the method is evident from the drawing, which is an example Scheme of the arrangement there.

G is a direct current source such as a direct current generator. The two terminals +, - of the same are on the one hand connected to the assignments A, B of the capacitor C _{1 :}

closed and on the other hand are connected via the variable inductances d _v d _z , the self-inductances D _x , D ₂ with the spark gap F , which is bridged by the capacitor C _2. ^ t ₁₁ S ₁ are the assignments of the capacitor C ₂ . The spark gap has four electrodes, the two outer electrodes via D ₁ and D ₂ . the direct current source, the two _< inner ones to the secondary; coil one

to transformers T are connected.

By the direct current source the half A is, d _v D _1, A ₁ of the oscillation circuit C _1, D _1, C _2, D _2, the half S ₁ D _2, D _2, S ₂ pressed a positive potential, a negative potential.

A line a, b branches off from the poles of the direct current source and leads the resistors rr, the self-induction I, I to the primary coil of the transformer T via the interrupter U, which can consist, for example, in a Morse code key or the like. Before the oscillation circuit is connected to the power source, the U key is closed.

If, after the capacitor circuits C ₁ and C _{2 have been} charged, the branch current through transformer T is opened by means of interrupter XJ , the following occurs: The current interruption generates a rectified current surge in the secondary coil of transformer T , the voltage of which is considerably higher than that of the current flowing through the primary coil, since the number of turns of the secondary coil is greater than that of the primary coil.

The high-voltage current surge caused by Γ in the secondary coil generates an auxiliary voltage on the two inner electrodes of the spark gap F , which is sufficient that the space between the inner electrodes is flashed over and the electricity from the outer electrodes to the two inner electrodes is immediately balanced by one Spark sets in. _{The capacitor C 2 is} short-circuited via the spark gap as a result of the spark that passes over. An aperiodic oscillation thus occurs in the oscillation circuit C ₂ , F , but this only lasts a half-wave, ie until the + charge has moved from A ₁ to B ₁ and the - charge from S ₁ to A ₁ . This is achieved by an extinguishing spark gap of the usual type, which increases the damping decrement of the circle C ₂ , F up to aperiodicity.

If, after the spark transition, the sign of the charge has changed to A ₁ - and S ₁ -f-, then there is between./! and ^ ₁ and between B and B ₁ a voltage difference of each 2 V. This voltage difference is caused by the self-inductions which delay the afterflow of positive charge from A to A ₁ and the drain of the positive charge of S ₁ to B.

The magnitude of the self-inductions D ₁ , d _x and D ₂ , ^ ₂ and thus the delay of the equalizing current is dimensioned so that the negative potential generated by the spark transition on A ₁ and, accordingly, the _{positive potential generated on S 1} can reach their maximum value before the counter-current of the countercurrent flowing _{through D 1} and D _{2 comes into play.} For the determination and adjustment of the required for this value of the self-inductions of D ₁ and D ₂ connected in series therewith, the small variable Zusatzinduktanzen ^ ₁ and d ₂ are used.

The countercurrent through D ₁ to A ₁ and through D ₂ from S ₁ has an oscillation-like character due to the inclusion of the self-inductions D ₁ and D _2. The charge would accordingly swing back and forth from A to A ₁ and back, i.e. A and A ₁ and correspondingly S ₁ and B would alternately have positive and negative potential if electricity were not continuously supplied to A from the power source with voltage V. . The result is that the potential on A cannot fall below 0, ie it cannot become negative. However, since there is a voltage difference of 2 F between A ₁ and A at the moment of the onset of the countercurrent from 4 to A ₁ (on A - \ - V, on A ₁ - V), consequently also the voltage value of the in S ₁ resp. S ₂ arising self-induction current impulse has the voltage 2 V , then the potential that is generated on A ₁ is pushed up from ο F to + 2 F. The same happens with respect to B and S ₁ , on which latter assignment of the capacitor C ₂ the potential −2 F arises. The voltage difference between A ₁ and S ₁ has increased from 2 F to a total of approximately 4 F if the voltage losses in the conductors due to energy consumption are kept as low as possible.

The two parts A, D ₁ , A ₁ and S, D ₂ , S _{1 of} the circle C _11, D ₁ , C ₂ , D _2, each forming an open oscillator, are thus triggered to oscillate.

The further excitation and maintenance of the vibrations could be brought about by repeatedly closing and opening the interrupter U. In the case of the present invention, however, the interrupter U only serves to excite an initial oscillation, which now gives rise to continuous oscillations of the electrical energy always replenished by the power source G and to a further increase in the voltage amplitudes of the oscillations.

This is achieved in the following way. The inductances D ₁ and D ₂ form the primary coils of two transformers whose secondary

coils, which have a higher number of turns than D ₁ and D ₂ , are connected in series via a capacitor C ₃ . In parallel with the capacitor C _{2 there} are two choke coils L ₁ and Z _{2 connected in series} , between which the central electrodes of the spark gap F are connected in series in the manner shown in the figure. The electrical constants of the capacitance C ₃ and the inductances L ₁ and Z ₂ are dimensioned so that the _{current flowing in the circuit C 3} , L ₁ , L ₂ is 180 ° behind the currents flowing through the coils D ₁ and D ₂ runs after. The voltages generated by these currents on the central electrodes of the spark gap F charge these auxiliary electrodes only when the countercurrent from A HaCh ^ l ₁ and from B to B ₁ has charged the former to - \ - 2 V and the latter to - 2 F or when the maximum value of the voltage that can be achieved by the countercurrents is reached. At this moment the voltage on the auxiliary electrodes of the spark gap has risen to such an extent that a flashover of the spark gap and thus a short circuit of the capacitor C ₂ occurs. For the reasons already mentioned, the spark breaks off again as soon as the positive charge ^ _{1 has} migrated to B ₁ and A _{1 has reached} the potential - 2 F, B _1, on the other hand, has reached -f 2F.

Since the voltage unchanged -j- F, B F is pressed onto by the DC power source A, exists between A and A _1, and between B and B ₁ are now depending 3 V voltage difference. A current of 3 V voltage flows from A to A ₁ and from B ₁ to B. The result is that in the manner already described, the assignment A _{1 is} now charged to - (- 3 V, B ₁ to -3 F. When the maximum value of this voltage is reached, then the discharge begins at the spark gap, since in this At the moment the auxiliary potential on the central electrodes has also reached a value which enables the transition of a discharge in the form of a spark. As a result of the discharge, A ₁ receives the potential -3 F, B ₁ the potential +3 F. It now exists between A. ₁ and " A and between B ₁ and B a voltage difference of 4 F.

This process of amplifying and increasing the voltage amplitude is repeated as long as the power source is able to supply energy. Is that through charisma and internal losses occurring energy consumption in the oscillation circuits so far so that he can deal with the amount of electricity supplied by the power source if the balance holds, then a state of equilibrium occurs. From that moment on no further increase in the voltage amplitude.

Instead of exciting the initial oscillation through the current interruption * in the circuit a, I, T, I, b branching off from the current source G, as in FIG . The process then takes place in the same way, except that the current impulse which excites the first oscillation is not caused by current interruption in circuit a, I, T, I, b and by induction on the primary circuit C ₁ , C ₂ , but by the current connection self-induction current arising in the self-inductions H ₁ , D ₁ , d ₂ , Z) _2. This induces the auxiliary voltages in the secondary coils of D ₁ , D ₂ , which must be pressed onto the auxiliary electrodes so that the spark gap S can be flashed over.

Fig. 2 shows the basic circuit for this. G is the current source, T the key switched on in the supply line, ä _x and d ₂ variable inductances, D ₁ , D ₂ the inductances induced by the antenna currents, which induce coils with a high number of windings, whose induction currents supply the additional voltages required to ignite the spark gap .

The use of the vibrating energy takes place in a well-known way. In the case of the arrangement of the drawing, for example, the antenna An is inductively coupled to the self-induction D _1. The antenna can of course also be galvanically coupled to one of the halves of the oscillating circuit C ₁₁ D ₁ , C ₂ , Z) _2. In the latter case, the other part of the circle which is not connected to the antenna must be electrically balanced against the second half of the oscillating circuit which is connected to the antenna and which is loaded by this half.

The regulation of the auxiliary voltage on the auxiliary electrodes of the spark gap during the initial ignition by means of the transformer T takes place by means of the ohmic and inductive resistances r, r and I, I. By regulating the same, the drop in the current when it is interrupted by the interrupter U can be controlled at will within certain limits Limits are accelerated or retarded. According to the rapidity of the voltage drop, the voltage of the secondary current impulse is larger or smaller.

Claims (8)

Patent Claims: I. A method for generating high-frequency electrical oscillations, characterized in that a _{capacitor (C 2} ) charged by a direct current source (G) via self-inductions {d _lt D ₁ , d ₂ , D _s ) via a parallel-connected extinguishing spark gap ( F) is discharged in that the auxiliary electrodes an additional voltage that enables a spark transition is applied for a very short period of time, and due to the strong attenuation of the spark gap dk charge of the capacities of the capacitor :; (C ₂ ) changes sign so that due to the delay of the inflow stream; from the power source through the self-induction between the terminals of the power source or a capacitor (C ₁ ) connected in parallel to this and the corresponding assignments of the second capacitor, a potential difference of approximately double which causes a current surge. th value of the voltage impressed by the direct current source arises. 2. The method according to claim i, characterized in that during the flow of the equalizing current of the power source to 'the capacitor (C ₂ ) the capacitor (C ₁ ) is continuously supplied by the power source electrical energy, so that the potential of the positive pole The assignment (a) of the first capacitor (C ₁ ) connected to the power source does not become negative and, as a result, the voltage difference between the corresponding assignments of the two capacitors after the change in the sign of the assignments of the second capacitor (C ₂ ) between the first caused by the next spark discharge and the second capacitor produces a voltage difference of approximately three times the value of the initial voltage and that in the following discharges, the voltage difference between the corresponding assignments of the capacitors increases by the amount of the initial voltage until the power source is no longer able to supply enough energy. 3. The method according to claim 2, characterized in that the auxiliary voltage enabling the first spark discharge on the auxiliary electrodes of the extinguishing spark gap (F) is generated by the opening current surge of the secondary coil of a transformer (T), which is caused by the interruption of a j of the primary coil! Stromes is caused. j 4. The method according to claim 1 to 3, characterized in that the voltage applied to the auxiliary electrode is regulated in that the voltage drop in the primary coil when the primary current is interrupted by means of controllable ohmic and inductive resistors (r, r, 1,1) is accelerated or decelerated. 5. The method according to claim 1 and 2, characterized in that the first Auxiliary voltage enabling spark discharge on the auxiliary electrodes of the extinguishing spark gap through the high tension . Induction current surge is generated, which is generated by the self-induction current surges in the secondary coil of self-inductions (U ₁ , D ₂ ) serving as transformers when the current is closed. 6. The method according to claim 1 to 5, characterized in that the vibrations excited according to claim 3 and 4 are maintained in that the self-induction (D ₁₁ D ₂ ) flowing through current impulses induce secondary higher voltage impulses that the auxiliary electrodes of the spark gap to Press on the required auxiliary voltage to initiate the spark transition. 7. The method of claim 1 to 6, ■ characterized in that the produced to elicit the spark discharge at the moment of greatest tension difference between the respective assignments of the capacitors (C _1, C ₂₎ in the secondary coils of the self-inductions (D _1, D ₂₎ Current surges are passed through a capacitor (C ₃ ) and self-inductions (L ₁ , L ₂ ) measured in such a way that the increase in voltage on the auxiliary electrodes lags behind the inducing currents by about 180 ° in phase. 8. The method according to claim 1 to 7, characterized in that for setting to the correct time instant of the spark transition in which the voltage difference between the capacitors has reached the highest value, the self-inductions (L ₁ , L ₂ ) and serving to produce the phase difference possibly the capacitor (C ₃ ) can be regulated. 1 sheet of drawings.