DE1291388B - Semiconductor oscillator - Google Patents

Description

The invention relates to a semiconductor oscillator with at least two semiconductor switches, each of which two with their switching paths and a DC voltage source are connected in series, during the Connection point of the two switching paths is connected to a consumer, so that the Consumers lying DC voltage in the cycle of a control voltage supplied to the semiconductor switches polarity is reversed.

In a known semiconductor oscillator of this type, transistors are used as semiconductor switches. The oscillator diffent for the generation of low frequencies Square waves.

In contrast, the object of the invention is to create an oscillator for generating powerful, preferably sinusoidal, electrical waves in the range of ultrasonic frequencies, ie approximately below 50 kHz. It is known to generate electrical oscillations by alternately charging and discharging a capacitor via a mechanical or gas-filled switch. However, this type of vibration is generally limited to low frequencies. Thus, a known circuit arrangement of this type consists of several discharge circuits which are charged one after the other and which are discharged alternately with the aid of ratchet wheels. The discharge circuits each consist of a series connection of a capacitor and an inductive resistor, but are not matched to the natural frequency of the consumer (antenna). Charging overall _'30 schieht aperiodic.

The introduction of the controlled silicon rectifiers (thyristors) has to the mentioned frequency restrictions Hardly anything changed, because the controlled silicon rectifier at higher frequencies and powers fails because of difficult heat dissipation and required recovery time. Even with the above-mentioned known circuit arrangements, thyristors cannot easily be used because once they are open they will not be locked at any time ' can, but .only, by falling below a certain minimum flow rate. The aperiodic opening and blocking of mechanical or semiconductor switches is not feasible with thyristors.

The aim of the invention is now to provide a semiconductor oscillator based on the circuit arrangement mentioned at the beginning to create, with which penetrated into the long-wave range using thyristors can be.

According to the invention, this is achieved in that several series positions of controlled semiconductor rectifiers (Thyristors) are connected in parallel that the. Switch .55 connection points stretch jointly connected consumers consists of a parallel resonant circuit, which is connected to the Natural frequency of the resonant circuit tuned series resonant circuit is connected upstream, and that the of the series circuits, each thyristor is only in a fraction of the periods of the natural oscillation of the parallel resonant circuit is used to supply energy. This can reduce the recovery time considerably extend or increase the operating frequency of the arrangement accordingly. Are also in in a manner known per se in each branch several, z. B. two, in-phase controlled thyristors in Series used, the voltage load and thus the transmitted power z. B. double.

The semiconductor oscillator constructed in this way is because of its high current carrying capacity for the operation of a Power amplifier, especially the antenna amplifier of a long wave transmitter, is excellently suited.

The invention is explained below with reference to the drawing. In here is

Fi g. 1 is a schematic circuit diagram relating to the essential features known arrangement from which the invention is based, and

F i g. 2 is a schematic circuit diagram of an embodiment the invention.

F i g. 1 shows two sieved silicon rectifiers 12 and 14 which are connected to a pulse shaper 13, the output of which leads to a resonant circuit 20. In detail, the rectifier 12 with anode 61, cathode 63 and control electrode 65 is connected in series with a rectifier 14 with anode 71, cathode 73 and control electrode 75. The anode 61 of the rectifier 12 is connected via an inductance 10 to a terminal 28 to which a positive DC voltage B + is supplied. The cathode 63 is connected to the anode 71 of the rectifier 14. The cathode 73 is connected to a reference point (earth). The control electrodes 65 and 75 of the two rectifiers are each connected to a secondary winding 42 and 52 of two transformers 40 and 50. The primary windings 41 and 51 of these transformers are connected to a pulse generator 30 which sends triggering pulses to the control electrodes 65 and 75 in order to open the rectifiers 12 and 14 at certain times.

The connection point 34 between cathode 63 and anode 71 is with the input of pulse shaper 13 tied together. The resonance circuit 20 connected to the output thereof consists of an inductance 22, a capacitance 24 and a load resistor 26.

In the embodiment shown, the pulse shaper is at the center tap of the inductance 22 connected, but it could also be connected to the upper end of the parallel circuit.

The arrangement is controlled by the pulse generator 30. First, the rectifier 12 is by means of an opening signal at the electrode 65 is opened while the rectifier 14 remains blocked. The pulse shaper 13 is charged in an oscillatory manner to a voltage that is twice the operating voltage is by a current from the terminal 28 via the charging choke 10, the rectifier 12, the pulse

individual series circuits one after the other in the cycle 60 former 13 and the inductance 22 flows to earth. the the natural frequency of the resonant circuit for charge reversal inductance of the choke 10 is large compared to

of the same are used.

The series resonance circuit connected to the output forces sinusoidal oscillations, which trigger the parallel oscillating circuit to produce powerful oscillations with its natural frequency. By connecting several inductors 22 and the equivalent inductance of the pulse shaper 13 to alternately charge and discharge the resonance network, the pulse shaper contains at least one inductance and / or a capacitance or both. The pulse shaper 13 charges to approximately twice the operating voltage in a time which is equal to π YLC , where L is the value of the charging inductance 10 and C is the value of the pulse shaper 13

3 4

capacity shown is. If the pulse shaper is used, for example, as a series connection of an inductance 16

13 is charged, the amperage increases through the and a capacitance 18 shown. Between the rectifier 12 and finally falls to a terminal point 34 and earth there are three parallel values below the extinguishing current, whereupon the series circuits of silicon rectifier are switched. Rectifier 12 is blocked. It remains blocked until 5 tern 14 α and 17 a, 14 b and 17 b and 14 c and 17 c. it is opened again by an opening signal on the electrode The three series connections on the charging and discharging 65 is opened. In a certain later time charging side together form three stages A, B and C, point the pulse generator 30 gives an opening which actuate the pulse shaper 13 in the above-described pulse on the control electrode 75 of the rectifier manner. Every controlled rectifier is

14 and makes it conductive, whereupon the Im- io assigned a transformer winding to it The charge stored in the pulse shaper can open very quickly over certain times, the equations Resonant circuit 20 in the form of a relatively rectifier connected in series at the same time as the opening and strong impulses of electrical energy. For example, the same discharges. The use of the controlled rectifier 12 a and 15 a are connected in series and are judge 12 in the charging branch of the pulse shaper 13 is actuated at the same time, so that the terminal 28 is supported the operation of the discharge circuit, since the impulse-led DC voltage can be increased without former can be practically completely discharged, the nominal reverse voltage of the controlled rectifier while exceeding one in place of the controlled rectifier. Of course, we can do even more

The usual charging diode used in 12 would be connected in series as two rectifiers, as soon as the voltage at the pulse shaper falls below 20. The same applies to the series connection, the value of the operating voltage B + would fall. controlled rectifiers 14a and 17a.

This would increase the pulse frequency or pulse width of the In operation, stages A, B and C are

on the resonance circuit 20 given energy pulse other open, so that the mean current strength in

limited. The resonance circuit 20 is reduced as a parallel circuit of each group and a relatively

formed with a high quality factor Q and a weakly high total current supplied to the pulse shaper

attenuated so that it can be controlled when the energy occurs, without the rated current of a

impulses to be exceeded during the discharge of the pulse generator rectifier. First will be

13 with its natural frequency / ₀ in oscillations, so the controlled rectifiers 12 a and 15 a advises. By subsequently alternately opening the simultaneously opened to charge the pulse shaper 13 via controlled rectifiers 12 and 14 in periodic 30 terminal 28 and charging choke 10. As with intervals, for example in each period of the own embodiment according to FIG. 1 increases the charging frequency / ₀ , the resonance circuit 20 can for upright voltage at the input of the pulse shaper 13 to approximately maintain oscillations at its resonance - twice the value of the direct voltage B + . When excited at frequency, so that it emits a pure sinusoidal charge of the capacitor 18 again, the oscillation drops. 35 Amperage through the rectifier 12 a and 15 a

The resonance circuit 20 is only shown, for example, gradually, until the holding current is reached, whereupon

represents. He can z. B. the transmitting antenna of a long-term these rectifiers are blocked. In this

wave transmitter mean. Instead, it can remain the controlled rectifier as the first interval

Ultrasonic transducers be designed. 14 a and 17 a and all other rectifiers in the

The charging throttle 10 can be locked in the pulse shaper 40 levels B and C. In a second time interval, so that the pulse shaper 13 from a vall, the controlled rectifier 14 a and simple choke in series with a capacitor 17 a are opened at the same time, so that the pulse exists, the choke both to the resonance shaper 13 discharged quickly can and an energy charge as well as for storing the discharge pulse impulses on the resonance circuit 20, whereby the serves. 45 to the oscillation with its natural frequency / ₀ .

It is well known that silicon controlled rectifiers have come across.

a certain recovery time before the locks can be opened again after the combination of levels, B and C. This operation, that after loading and unloading the recovery time, stems from the storage of minor pulse shaper 13 via stage A to stage B for the carriers of the outer barrier layers during charging and discharging of the pulse shaper in the same conduction state. These carriers need rather wise being used. After that, stage C occurs for a certain period of time until they are cleared out. The in action, etc. So the individual stages can recover the length of the storage time is essentially one radio sufficient before they come back into action of the maximum forward current and the change. Each stage leads only a third of the impulse speed of the forward flow. From the 55 pulse shaper 13 supplied total current. For the following reason, the memory effect must be taken into account. The embodiment according to FIG. 2 to be drawn when rapid actuation requires triple current as the embodiment according to, since the storage exceeds the upper frequency limit F i g. 1 without exceeding the rated current of the silicon rectifier influenced by the control. While

One embodiment of the invention is shown in FIG. 1, the energy of the resonant circuit in each

F i g. 2 can be seen. To get higher output power at period just by a pair of silicon rectifiers

To achieve the resonance circuit 20, several have been supplied, is shown in FIG. 2 each row scarf

controlled silicon rectifier connected in parallel. For the processing of controlled silicon rectifiers only in

Load three parallel series connections are used every third period. Self-evident

two controlled silicon rectifiers 12 a and 65 borrowed any number of stages to

15a, 12b and 15b, 12c and 15c, which are used between the implementation of the invention,

the one end of the charging throttle 10 and the connection.

line 34 are located. The pulse shaper 13 is driven here that the pulse shaper 13 over

several stages are charged and discharged. This allows a higher energy in the resonance circuit 20 achieve.

Claims (2)

Patent claims: 1. Semiconductor oscillator with at least two semiconductor switches, two of which are connected in series with their switching paths and a DC voltage source, while the connection point of the two switching paths is connected to a load, so that the DC voltage applied to the load is synchronized with a control voltage supplied to the semiconductor switches polarity is reversed, characterized in that several series circuits (A, B, C) of controlled semiconductor rectifiers (thyristors) are connected in parallel, that the consumer connected to the connection points of the switching paths consists of a parallel resonant circuit (20), which is based on the natural frequency of the Resonant circuit tuned series resonant circuit (13) is connected upstream, and that the individual series circuits are used one after the other in the cycle of the natural frequency of the resonant circuit for reloading the same. 2. Semiconductor oscillator according to claim 1, characterized characterized in that in the charging and discharging branch of each series circuit several in-phase controlled semiconductor rectifiers (12 a, 15 a; 14 a, 17 a) are connected in series. 1 sheet of drawings