DE976546C - Circuit arrangement for improving the efficiency of a transistor pulse oscillator in the manner of a blocking oscillator - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUE 7 NOVEMBER 1963

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ¹ GROUP 36o2 INTERNAT. CLASS H 03k

N107τ2 VIIIaJ21a ¹

Leon Henry Light, Glasgow (Great Britain)

has been named as the inventor

N.V. Philips' Gloeilampenfabrieken, Eindhoven (Netherlands)

Circuit arrangement for improving the efficiency of a transistor pulse oscillator in the manner of a blocking oscillator

Patented in the territory of the Federal Republic of Germany on May 29, 1955 Patent application published September 20, 1956

Patent issued October 17, 1963

The priority of filing in Great Britain June 2, 1954 and May 3, 1955 (No. 16 329)

is used

The invention relates to a circuit arrangement for improving the efficiency a transistor pulse oscillator in the manner of a blocking oscillator, e.g. B. to implement a low DC voltage (transistor operating voltage) into a high DC voltage through rectification of the generated pulses, whereby the current-conducting state of the transistor is connected to its base in Forward bias applied is promoted and as a result of a in its collector-emitter circuit occurring saturation phenomenon is ended.

It has already been proposed to use a transistor z. B. the

309 731/2

to use p-n-p type, whose emitter is connected to the positive terminal of a DC voltage source, z. B. a battery, and its collector electrode over the primary winding of a transformer on the negative terminal of this source, while the base electrode is on the secondary winding of the transformer is connected in series with a resistor to the emitter.

During the period in which the transistor ίο is live, its base current is the oscillation energy the oscillator, d. H. the voltage, which occurs on the secondary winding and reverses its sign in a pulse shape for a short period, so that the transistor is blocked.

The invention aims to provide a transistor pulse oscillator in 'which this base current is not applied by the vibration energy generated in the transistor.

Tube iiC oscillators have already become known, in which the one consisting of the parallel connection of a capacitor and a discharge circuit i? C circuit is connected in the cathode control grid circuit of the tube, with the discharge circuit contains the series connection of a resistor and a voltage source, which the with the Control grid of the tube connected electrode of the capacitor can charge positively. The feedback loop this oscillator contains a winding across which a feedback voltage is generated and connected in parallel with the capacitor via a rectifier connected in this way is that the electrode of the capacitor connected to the control grid of the tube through the Feedback voltage can be negatively charged. While the capacitor is afterwards over discharges the resistor and is charged by the voltage source with reverse polarity, the anode current increases and a corresponding voltage appears across the feedback winding generated that blocks the rectifier. However, the capacitor voltage is opposed and greater than this feedback voltage, the rectifier becomes conductive, the anode current stops increasing, the feedback voltage disappears and changes sign, and the Capacitor suddenly recharges itself via the feedback winding and the rectifier, with the appropriate sharp and strong decrease in the anode current, to then again over the Resistance to discharge and through the voltage source with reverse polarity when blocked Rectifier to be charged. So here is the conductive state of the tube by reaching terminated a capacitor charge voltage at which the rectifier becomes conductive. the Tube circuit can and is mostly operated without grid current, while transistor circuitry cannot work without base power. The control power to be supplied to the base circuit via the feedback circuit is accordingly provided a considerable attenuation of the switched on in the collector-emitter circuit of the transistor Output circuit and a considerable decrease in the use of the transistor already in pulses transformed energy.

The invention is now characterized in that the base circuit of the transistor in combination a direct current source for supplying in the forward direction the one corresponding to the conductive period flowing base current and a feedback circuit in series with one in the reverse direction switched isolating rectifier is connected in parallel, which during the current-conducting period is blocked by the forward feedback voltage, so that the collector-emitter circuit of the transistor is not attenuated by its base circuit during the current-conducting period is, however, the reverse-biased feedback voltage generated at saturation this isolating rectifier is fed to the base and suddenly blocks the transistor.

By combining the measures according to the invention, the control energy is immediate Supplied by the source of low DC voltage by in an analogous manner to that mentioned Tube i? C oscillators the base circuit of the transistor the parallel connection of a direct current source for the supply of the current conducting The forward base current corresponding to the period and a feedback circuit in series with one connected in the reverse direction Contains isolating rectifier, which during the conductive period through the forward directional feedback voltage is blocked. The collector-emitter circuit of the transistor becomes then no longer attenuated by its base circle during the conductive period, but it is In contrast to the tube circuits mentioned, the one generated when saturated, directed in the reverse direction Feedback voltage supplied to the base of the transistor via the aforementioned isolating rectifier and suddenly blocks the transistor.

The circuit arrangement according to the invention is also not compatible with the known multi-circuit circuits to compare that for the amplitude comparison of a relatively slowly changing Voltage with a reference voltage or for converting a sinusoidal voltage into a square wave voltage be used. The input voltage can also be activated when a Diode can only reach the control grid of a tube via a coupling capacitor, i.e. only as a pulse. In addition, only approximately square-wave pulses are generated in the anode circuit of the tube no sawtooth tension.

The fact that the necessary for the control of a transistor, not to be neglected Control power according to the invention is supplied directly by the source of low DC voltage one can get a larger pulse power with better with a given transistor Generate efficiency. The achievable efficiency is of course much better than the one that can be achieved with a tube circuit, because the

The voltage drop that occurs is much smaller than the voltage drop between the cathode and anode a conductive tube.

The invention is explained in more detail with reference to the drawing, for example.

The embodiment shown comprises a p-n-p boundary layer transistor ι with an emitter 2, a base electrode 3 and a collector electrode 4. The emitter 2 is connected to the positive one Terminal of a battery 10 of e.g. B. 3 V, while the collector electrode 4 via the primary winding 5 a transformer 6 is connected to the negative terminal of this source. The base electrode 3 is on the one hand via a resistor 9 on a tap of the battery 10 and on the other hand over a rectifier 8 in series with the secondary winding 7 of the transformer 6 at the emitter 2, the cathode of the rectifier 8 facing the base electrode 3.

When the voltage of the battery 10 through the primary winding 5 to the collector electrode 4 and is applied to the base electrode 3 via the resistor 9, such a current flows through the transistor i that almost the entire voltage of the battery 10 of z. B. 3 V, on the primary winding 5 lies. This results in an essentially linear increase in the current through the primary winding 5, so that an essentially constant DC voltage occurs across the secondary winding 7. The circuit of the transformer 6 is such that this voltage is applied to the anode of the rectifier 8 receives a negative potential with respect to its cathode and therefore blocks the rectifier. The current through the resistor 9 flows completely to the base electrode 3.

This state lasts until the collector current reaches the corresponding value of the base current Knee reached in the characteristic that the collector current as a function of the collector voltage when the emitter circuit is grounded. When this knee is reached, the The voltage between the collector electrode and the emitter increases and the collector current increases no longer in a linear relationship with time too.

This is associated with a reduction in the negative bias voltage of the anode of the rectifier 8. This bias voltage continues to decrease until the rectifier 8 is energized. From this it follows there is a decrease in the base current and consequently also in the collector current. The decrease of the Collector current causes a positive voltage at the anode of the rectifier 8, which again increases the collector current reacts, so that the process has a cumulative picture and the transistor is blocked.

As a result of the sudden interruption of the collector current by means of the primary winding 5 a high negative voltage is generated at the collector electrode 4. This voltage can be rectified are used to generate a DC voltage that is higher than the voltage of the battery 10 can be. For this purpose, the transformer can optionally be equipped with a third winding be provided.

After the energy accumulated in the primary winding 5 is consumed, it disappears positive voltage at the anode of the rectifier 8, so that at least part of the current flows through the resistor 9 again through the base circle. The resulting increase of the collector current generates a negative voltage at the anode of the rectifier 8, so that the latter is blocked and the entire current through the resistor 9 back to the base electrode of the Transistor 1 flows. The cycle repeats itself periodically so that the circuit is constantly pulsing generated.

That taken during each cycle of the battery 10 and accumulated in the primary winding 5 Energy depends, among other things, on the base current. This current can be changed by changing the Tapping the battery 10 or the resistor 9 can be changed.

If it is desired to keep the base current more constant than with the battery 10, the collector current must deliver, is possible, a separate battery can be provided that only one would have to raise a smaller current.

By using an n-p-n junction transistor with the required polarity reversals the battery and the rectifier must be carried out, the Blocking the transistor generated pulse voltages positive instead of negative.

An additional resistor 11 can be connected in series in the circuit of the emitter 2, to facilitate the blocking of transistor 1 if necessary. Furthermore, instead of or in Combination with this resistor a small negative voltage of the source 12 in series with the Winding 7 as the threshold voltage of the rectifier 8 can be applied to a rapid transition from the live state to the blocked State of the transistor to facilitate.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for improving the efficiency of a transistor pulse oscillator in the manner of a blocking oscillator, e.g. B. to implement a low DC voltage (Transistor operating voltage) into a high DC voltage by rectifying the generated pulses, whereby the current-conducting state of the transistor by an on its Base in the forward direction applied bias is promoted and as a result of an in saturation phenomenon occurring in its collector-emitter circuit is ended thereby characterized in that the base circuit of the transistor in combination is a direct current source for the supply of the one corresponding to the current-conducting period in the forward direction flowing base current and a feedback circuit in series with one in the reverse direction switched isolating rectifier is connected in parallel, which during the current-conducting Period is blocked by the forward feedback voltage, so that the collector-emitter circuit of the transistor during the current-conducting period through its base circle is not attenuated, but the reverse direction generated at saturation Feedback voltage is fed to the base via this isolating rectifier and suddenly blocks the transistor. 2. Pulse oscillator according to claim i, characterized in that a resistor (ii) im The emitter circuit of the transistor is located. 3. Pulse oscillator according to claim 1, characterized in that a threshold voltage (12) is applied in series with the rectifier (8). For this purpose ι sheet of drawings © 609 619/160 9.56 (309 731/2 10.63)