DE1096967B - Electronic vibration generator with a bridge-connected resonant circuit - Google Patents

Description

Electronic oscillation generator with a bridge-connected oscillating circuit The invention relates to electronic vibrators and switching circuits with such vibrators.

Tube vibrators are known that have a bridge-connected Have an oscillating circuit, which consists of two capacitive and one inductive element, which are connected in a closed loop in grater, with the common Connection point of the capacitive elements and a tap on the inductive Element form the output terminal of the bridge and a tube is provided whose Input circuit is between the output terminals of the bridge and its output circuit connected to an element of the bridge so that when the bridge is forward equilibrium point is out of tune in one direction, the energy supplied to this element Causes vibrations and when the bridge is on the other side of the equilibrium point out to the other side is out of tune, no vibrations, appear.

Such a vibration generator reaches the vibration threshold, d. H. the state in which the vibrations just set in, if the positive one Feedback to the input circuit of the tube on the one parallel path the bridge between the terminals of the bridge provides the negative feedback the input circuit of the tube on the other parallel paths through the bridge between the terminals by a sufficient margin.

An object of the invention is to provide a new electronic vibrator to create at which the oscillation swell point is precisely defined.

Vibration generators of this known type are used for the purpose indicate when an independently variable element of the bridge has a predetermined one Reached size value, the vibrator is arranged so that he Schwing.ungsschwellpunkt reached when the independently variable element the obtained predetermined size value. For this purpose it is customary to set it up so that a current which is dependent on the amplitude of the oscillation, such as the anode current of the tube, fed to the excitation winding of a relay, wherein the excitation winding is thus excited by a direct current that depends on the amplitude depends on the vibration. Such an arrangement is considered to be the state of the art associated circuit known.

Due to the fact that the relay with a not small current must be fed in order to make it respond, the value of the independent gives way variable element of the bridge at which this response occurs, not irrelevant from the point at which the vibration generator sets the vibration threshold point achieved. For certain purposes this difference is unduly great, and it is therefore Another object of the invention is to make novel provisions, this difference to diminish.

According to the invention, an electronic vibrator with brought a bridge-connected resonant circuit in proposal, which consists of two capacitive and an inductive element connected in series in a closed loop are connected, the common connection point of the capacitive elements and a tap on the inductive element, the output terminals of the bridge form and an amplifier is provided, the input circuit between the Output terminals of the bridge and its output circuit with the input terminals the bridge is connected so that when the bridge is from the equilibrium point after the one direction is out of tune, vibrations are caused, and% - enn the bridge to the other side is out of tune from the equilibrium point, none Vibrations appear, with the feature of the invention, that a rectifier coupled to the resonant circuit in its output frame circuit a rectified current dependent on the oscillation amplitude results in that a branch of the bridge contains a controllable element which is dependent on the potential imposed on it can be controlled, and that the output circuit of the Rectifier is connected to the controllable element in circuit connection, whereby this controllable element such a potential is imposed that the original balance of the Bridge is enlarged when the vibrator is transitioning from a state reaches the oscillation threshold value from rest to a state of sinewy sight.

Preferably the gain of the loop which has a feedback connection which includes the aforementioned compounds and is arranged in such a way that energy is fed back to the controllable element, `., a gain, that is greater than one.

The gain of the above loop goes from zero to Increases towards one, the value of the independently variable element of the bridge, at which the amplitude of the oscillation has a predetermined substantial size : and at which the vibrator reaches the vibration threshold point, continued smaller. -If the gain of the loop: is greater than one, the whole changes Initiation not steadily progressing from the vibration threshold to a state at which .the. Vibration amplitude is of considerable size. Is the change sufficiently large on the controllable element, the oscillation amplitude a predetermined substantial value immediately after the independently variable Element of the bridge attains the value at which the vibration generator reaches the vibration threshold achieved. If this change to the controllable element is not sufficient, di.eses-'Rgebn: is to deliver so will. still a certain difference between the value of the independent variable element of the bridge, in which the oscillation amplitude is a predetermined obtained substantial amplitude size, and the value exist at which the vibrator reaches the oscillation threshold. Therefore, it is also preferable above work with a gain in the loop of: more as one the controlled element - one that has the maximum change in this is sufficient to ensure that the oscillation amplitude is a predetermined attained substantial amplitude size, while .the other elements of the bridge at Values corresponding to the vibration threshold remain.

The following is an embodiment of the invention by means of a Example explained with reference to the drawing.

The arrangement indicated in the drawing shows an oscillator which consists of a pnp transistor 1 and a bridge-connected resonant circuit which has a tapped coil and two capacitors 3 and 4. The mean potential of the base electrode 5 of the transistor 1 is kept at a suitable value in a known manner by connecting this electrode to the common connection between two Wi resistances 6 and 7, which together result in a voltage divider between the negative pole 8 of a Power source and .dem Abgriffpunkt9 is arranged on the coil. One end of the coil is connected to the positive pole 10 of the power source. The collector electrode 11 of the transistor is connected to the negative pole 8 of the current source and the emitter electrode 12 is connected to the tapping point 9 by means of a resistor 13 which is shunted by a capacitor 14. The capacitor 14 means that the emitter electrode 12 is connected directly to the tapping point 9 with regard to the oscillating current. The resistor 13 cooperates with the resistor 6 and 7 in order to stabilize the direct current operating point of the transistor in a known manner.

The coil 2 is inductively coupled to a coil 18, and the the coil 18 induced voltage is through the rectifier 22 forming a Direct current in the base-emitter circuit of the transistor 19 is rectified. A Resistor 23 serves as a shunt along the base-emitter connection and is effective, to reduce the collector current to an acceptable minimum when the rectifier 22 does not deliver electricity. The collector electrode is connected to the negative Po18 via the Winding of a relay 21 connected.

In parallel with the winding 21, a voltage divider is connected is formed by two resistors 24 and 25. In parallel with the capacitor 3 is a circuit is connected, which consists of a connecting diode 26 and a blocking capacitor 27: exists. The common connection of the diode 26 and the capacitor 27 is connected to the common connection of resistors 24 and 25. The capacity the diode 26 thus forms part of a group of elements that form an arm form the bridge connection of the resonant circuit. The capacitor is preferably 27 considerably larger than the capacitance of the diode 26, so that the: the latter capacitance is connected essentially directly in parallel finitely with the capacitor 3. About losses to a minimum, the relative values of resistors 24 and 25 chosen so that the .die diode 26 acting in the reverse direction open-circuit voltage the Peak values of the oscillation voltage along the capacitor 3 exceeds and thus none substantial current flows through the diode 26. The capacitance of the diode 26 increases as soon as the tension drops along it, and vice versa.

It is assumed that the resonant circuit is not is in oscillation and the capacitor 3 increases in its capacitance (or capacitor 4 decreases in capacity) depending on a variable until finally a point is reached: at which the oscillating circuit just begins to oscillate. Then the current in the output circuit of transistor 19 begins to increase, whereby the reverse high voltage applied to diode 26 drops and thereby in turn, an increase in the oscillation amplitude is caused. The current through the coil 21 will therefore increase and will continue to increase as the capacitance 3 continues to grow (or the capacitance 4 continues to decrease) until the oscillation amplitude a predetermined size: reached at which the relay is certain to be effective will. Because the reinforcement of the loop: which is arranged in such a way that it generates energy to the diode 26 and that it in its feedback chain the connection from the common point of the resistors 24, 25 to one side of the diode 26 as well as the connection from terminal 10 to the other side of diode 26, increases towards one, the difference between the value of the capacitance becomes 3 (or Capacity 4), at which the oscillation amplitude 'the predetermined Has size, and the value at which the vibrator has the vibration threshold reached, continued smaller. Preferably the gain is this loop greater than one: the oscillation amplitude then increases by leaps and bounds from zero to a substantial value immediately after the vibration amplitude reached the vibration threshold. The change in the capacitance of the diode26 is sufficient to cause the oscillation amplitude to be the predetermined value to grow, at which the relay will be effective with certainty when the vibrator reached the oscillation wave point.

Assuming that the resonant circuit is in oscillation and the capacitance of capacitor 3 decreases (or the capacitance of capacitor 4 increased), the opposite effect will occur depending on a variable. The oscillating circuit will stop oscillating and the one flowing through the coil 21 Current falls from a maximum value at high speed, almost to zero. However, it will be necessary to reduce the capacitance of the capacitor 3 (if that is the capacity that is changeable), and was at a value that is less than the value at the beginning of the oscillation. The difference between these two Values practically corresponds to the change in capacitance of the diode26. The circuit has thus a counter-tension. Since the value of the change in capacitance of the diode 26 of depends on the relative values of the resistors 24 and 25, the size of the counter voltage can be changed by changing either or both resistors 24 and 25.

The resonant circuit shown in the drawing can be doubled be replaced, each transistor by an n-p-n transistor or by a ordinary tube can be replaced. This will .the circuit in a Modified manner as would be apparent to those skilled in the art.

Claims (9)

PATENT CLAIMS: 1. Electronic vibration generator with a bridge-connected Oscillating circuit, which consists of two capacitive elements and one inductive element, which are connected in series in a closed loop, with the common Connection point of the capacitive elements and a tap on the inductive Element form the output terminals of the bridge and an amplifier is provided, whose input circuit is between the output terminals of the bridge and whose Output circuit is connected to the input terminals of the bridge so that, if the bridge is out of tune in one direction from the equilibrium point, oscillations and if the bridge from the equilibrium point after another Side is out of tune, no vibrations appear, characterized that a rectifier coupled to the resonant circuit in its output circuit a rectified current dependent on the oscillation amplitude results in that a branch of the bridge contains a controllable element which is dependent on the potential imposed on it can be controlled, and that between the output of the rectifier and said controllable element connections are provided, whereby this controllable element such a direct current potential is imposed that the imbalance the bridge is enlarged when the vibrator when passing by one State of rest in a state of oscillation reached the oscillation threshold value. 2. Electronic vibration generator according to claim 1, characterized in that the gain of the loop that has a feedback link that the previous one includes said compounds and is arranged so that energy to the controllable element is returned is greater than one. 3. Circuit with a Electronic vibration generator according to Claim 1 or 2, characterized in that that the output of the rectifier is connected to the excitation winding of a relay is. 4. Switching circuit with an electronic vibration generator according to claim 2, characterized in that the output of the rectifier with the excitation winding a relay is connected and the maximum change on that controllable element is sufficient to ensure that the relay is actuated with certainty, while the other elements of the bridge remain at values close to the vibration threshold correspond. 5. Arrangement according to one of the preceding claims 1 to 4, characterized characterized in that the controllable element is a semiconductor diode and having a the capacitive elements in the bridge is connected in parallel and that the direct current potential is given to the diode in the opposite sense. 6. Arrangement according to claim 5, characterized in that the diode is connected in series with a capacitance , this capacitance being considerably larger than the capacitance of the diode im locked state. 7. Arrangement according to claim 5 or 6, characterized in that that the terminals of the diode are connected to two points on a voltage divider, which of the excitation winding of the relay to be controlled is connected in parallel. B. Arrangement according to Claim 5, 6 or 7, characterized in that the direct current potential the maximum oscillation potential exceeds that at the ends of a capacitive Element appears in the bridge. 9. Arrangement according to claim 7 or 8, characterized in that one of the tapping points is adjustable on the voltage divider is.