DE2014512B2 - Multivibrator - Google Patents

Description

4. Multivibrator according to claim 1, characterized in that a further Kor «, jnsator (C ₃₁ ) is connected parallel to the resistor (A _{32 ) connected to the base of the first transistor (7> 3!).}

The invention relates to a multivibrator for controlling a mechanical oscillator according to the preamble of the main claim.

A multivibrator according to the preamble of the main claim is known from NL-OS 6801245. In this multivibrator, the mechanical oscillator is operated by an electrical circuit, which, however, does not have sufficient temperature-independent properties, as a result of which the frequency of the multivibrator changes with temperature. There is a change in this multivibrator or an increase in the resistance values, an increase in the charging time of the capacitor provided and - since the resistances are also in the discharge circuit of the capacitor at the same time - also an enlarged one Discharge time. As a result, the exerted to control the oscillator causes the magnetic Force first a control, but then a damping of the oscillator.

The invention is based on the object of a multivibrator for controlling a mechanical To create oscillator with which the mechanical oscillator can be set in motion and in particular has temperature-independent properties, so that the oscillation frequency of the oscillator largely can be kept constant.

According to the invention, this object is achieved by the subject matter of the main claim. Further Refinements of the invention emerge from the subclaims.

In the case of the multivibrator according to the invention, the charging circuit for the capacitor is taken from the supply source, The coil and a resistor are formed, while the discharge takes place via two different circuits. One discharge circuit is through the emitter-base path of the second transistor and the collector-emitter path of the first transistor formed while the second discharge circuit through the emitter-collector path of the second transistor and the first resistance is determined. Thus, if the value of this resistance is increased, thereby increasing If the charging time of the capacitor increases, the switch-on time of the second transistor is only slightly changed because the discharge is essentially caused by the internal resistances of the two transistors and is not determined by the value of the first resistor. The multivibrator according to the invention enables thus the control of a mechanical oscillator from the rest position with a largely constant vibration frequency. In addition, temperature increases are compensated and it only a small amount of power is consumed during stationary operation of the transducer.

Preferred embodiments of the invention are explained in more detail below. It shows

1 shows a circuit of the multivibrator according to the invention,

2 shows a view of the mechanical oscillator,

Fig. 3 A shows the course of the voltage across the capacitor,

3 B shows the profile of the base-emitter voltage of the first transistor,

3C shows the current flowing through the coil,

4 shows a further embodiment of a multivibrator,

5 shows a further modified circuit of the multivibrator, and

6 shows a circuit diagram of a further embodiment of the multivibrator according to the invention.

Fig. 1 shows a multivibrator with a mechanical oscillator. The oscillator 1 together with a coil L forms a transducer, the coil being electromagnetically coupled to the oscillator 1 and having the function of tapping and driving. The oscillator 1 shown in Fig. 2 has a central shaft 2, a rotatably supported by the shaft disc 3, a magnet 4 attached to the top of the disc 3 and a weight 5 as a counterweight. The annular coil L is fixed in such a way that when the disk 3 rotates, the magnet 4 passes underneath. The coil L converts the electrical energy of a supplied signal into a mechanical movement of the oscillator 1 and at the same time picks up the mechanical movement of the oscillator 1 and converts it into an electrical signal. Therefore it serves as both a drive and a pick-up coil. The collector of an npn transistor Tr ₁ and the base of a pnp transistor Tr ₂ are connected in series. A resistor R ₂ lies between the transistor Tr ₁ and the positive pole of a voltage source E in order to forward-bias the transistor Tr _1. The emitter of the transistor Tr ₁ is connected to a resistor R ₁ . Between the emitters of the two transistors Tr _x and Tr ₁ , a capacitor C is provided, which the two

Capacitive coupling of the emitter. The coil L is connected to the emitter of the transistor Tr ₂ . The positive pole of the voltage source E, the coil L, the capacitor C, the resistor R ₁ , the switch S and the negative pole of the voltage source E are connected to one another in a series circuit. The collector of the transistor Tr ₁ is connected to the switch. Thus there are a total of four circuits, a discharge circuit with the voltage source E, the coil L, the capacitor C, the resistor A ₁ and the switch S; a discharge circuit with the capacitor C, the emitter and the base of the transistor Tr ₂ and with the collector and the emitter of the transistor Tr ₁ ; a discharge circuit with the capacitor C, the emitter and the collector of the transistor Tr ₂ and the resistor R ₁ ; Furthermore, a resonant circuit with the voltage source E, the coil L _1, the emitter and the collector of the transistor Tr ₁ and with the switch S.

The mode of operation of the multivibrator is explained in more detail below with reference to FIG. When the oscillator 1 is at rest, the switch 5 is closed. The base and the emitter of the transistor 7V ₁ are forward-biased, but the transistor Tr _{x is} blocked because the capacitor C is charged via the charging circuit.

In FIG. 3A, the time t is plotted on the abscissa and the voltage V _c across the capacitor C is plotted on the ordinate. The capacitor is charged to a certain level A _x via the charging circuit in accordance with the waveform a ₀ . In FIG. 3B, the time t is plotted on the abscissa and the base-emitter voltage V _{BE of} the transistor Tr _{1 is} plotted on the ordinate. While the capacitor C is being charged, the voltage rises to the level B _{x in} accordance with the waveform b _u . The transistor Tr ₁ is switched through when its base-emitter voltage reaches the value B _x . The capacitor C is therefore discharged via the discharge circuit via the circuit which contains the emitter and the base of the transistor Tr ₂ , the collector and the emitter of the transistor Tr ₁ and the capacitor C. At the same time, the transistor Tr _{2 is turned on} immediately, and the discharge current from the capacitor C is also passed through the branch v / which holds the emitter and collector of the transistor Tr ₂ , the resistor R _x and the capacitor Cent. Thereafter, the capacitor voltage drops in accordance with the waveform A _x in FIG. 3A. The base-E.nitter voltage of the transistor Tr _x is kept at a level β ₂ (FIG. 2B) by this discharge. The capacitor C is discharged according to a time constant which is determined by the capacitance of the capacitor C, the resistance of the resistor A ₁ and the resistance components of the transistors Tr _x and Tr ₂ . When the voltage of the capacitor C drops to the value A ₁ , the transistor Tr _{x is} blocked and the transistor Tr ₂ is also blocked immediately. As long as the transistor Tr _{x is} conductive, a large current flows through the multivibrator from the voltage source E via the coil L and the emitter and collector of the transistor Tr ₂ . In FIG. 3C, the time f is plotted on the abscissa and the current I, which flows through the coil L , is plotted on the ordinate, so that the illustrated current e _a results, which flows through the coil L as a drive pulse.

When the transistor Tr _{2 is} switched off, the capacitor C is charged again and the described

The same work cycle is repeated in order to carry out an astable oscillation.

The period of the astable oscillation process is set to a frequency that is greater than the natural frequency of the oscillator. The current curve e _{Q of} the drive pulse is set to a value that provides sufficient drive force to hit the oscillator.

The oscillator 1 is triggered by the pulse e ₀ and a voltage is induced in the coil /. The base-emitter voltage of the transistor Tr ₁ is supplied in accordance with the value b _x , or the signal ft ₀ in FIG. 3B is superimposed on the induced voltage. When the voltage B _{1 is} reached, the transistor 7V _{1 is switched} through. At this point in time, the capacitor C is charged to a voltage A _{3 in} accordance with the waveform a _2. The transistor Tr _x is thus switched through by the base-emitter voltage B ₁ , while the transistor Tr _{2 is switched} through in the manner described by the discharge current, which is determined by the time constant of the capacitor C, so that the Capacitor C discharges as shown by waveform O ₃ . The pulse e flows through the coil L, whereby the oscillator 1 is driven. If the process described is repeated and the oscillation amplitude of the oscillator 1 increases gradually, the induced voltage also increases and is superimposed on the base-emitter voltage, whereby the frequency by which the transistor Tr _{x is} switched is increased. As a result, the charging and discharging intervals of the capacitor C are gradually increased. The pulse width of the current flowing through the track L during the conductive state of the transistor 7V ₂ is steadily reduced. When the oscillator has reached a steady state of motion with a constant amplitude, the current pulses are also stable and stationary drive pulses e with a certain pulse width. The oscillator 1 therefore carries out stationary oscillations.

Since the current impulse e ₀ acting on the oscillator is much larger than the current impulse e , which is present when the oscillator has reached its stationary state of motion, the oscillator can be set in motion without any external force being required. As soon as the stationary state is reached, the oscillator is driven by current pulses e with a smaller pulse width, which is why the power consumption can be reduced to a minimum. The oscillator is driven by a current pulse, the frequency of which is synchronous with its natural frequency.

With a different arrangement of the two transistors and connection of the voltage source with opposite polarity, it is possible to obtain a different circuit arrangement for the multivibrator according to the invention. However, the mode of operation corresponds to the circuit according to FIG. 1.

Fig. 4 shows a further embodiment. Instead of the oscillator 1 according to FIG. 1, a rod-shaped oscillator 16 is provided. This rod-shaped oscillator 16 is attached at one end and provided at the free end with a magnetic rod 17 on one side and with a weight 18 on the other side, this weight representing a counterweight for the magnetic rod. An annular coil L ₁₁₁ is arranged in the vicinity of the range of movement of the magnetic rod 17. In the circuit shown is

a thermistor RIh _{19 is connected} between the collector of the transistor Tr _n and the emitter of the transistor Tr _n . The voltage source, the switch, the first resistor, the capacitor and the second resistor are designated by _{E 10} , S ₁₀ , R _n , C ₁₀ , and R _n.

With the circuit of FIG. 4, the temperature characteristics of the transistors Tr _n and Tr _{n can be} further improved.

FIG. 5 shows a multivibrator with a transducer in which the oscillator 29 is the rotor 28 of a motor. The transducer 29 is a ferrite disk which is attached to a shaft 30 and which has two pairs of north poles and south poles. An annular coil E ₂₀ provides the tapping and driving functions and is attached to the rotor at a suitable distance from the poles. A capacitor C ₂₁ is connected between the base and collector of the transistor Tr ₂₁ . According to FIG. 1, a first transistor Tr ₂₁ , a coil L ₂₀ , a voltage source E ₂₀ , a switch S ₂₉ , a capacitor C ₂₀ , a second transistor 7V ₂₂ , a first and second resistor R _n and R _{22 are} provided. With this circuit, oscillation of the transistor 7V _{21 can be} prevented. 6 shows a circuit of a multivibrator in which a capacitor Cj _{1 is connected in} parallel with a resistor R _n between the base of a transistor Tr ₁₁ and the positive pole of a voltage source E ₁₁₁ . As in FIG. 1, there are also a first transistor 7V ₁₁ , a coil E ₃₀ , a switch i ', ", a capacitor C', a second transistor 7V". first and second resistors R ₃₁ and R _{n are} provided. In this embodiment it is achieved that the drive pulses have the desired shape.

For this purpose 2 sheets of drawings

Claims (3)

Claims; 1. Multivibrator for controlling a mechanical oscillator, consisting of two transistors of opposite conductivity, of which the collector of the first transistor is connected to the base of the second transistor. a capacitor coupling the two transistors, a resistor connected to the base of the first transistor on the one hand and a DC voltage source on the other hand, a coil coupled to the mechanical oscillator, with a further resistor provided between the emitter of the first transistor and the DC voltage source, characterized in that the capacitor (C; C ₁₀ ; C ₂₀ , C ₃₀ ) is connected between the emitter of the first and that of the second transistor (Tr ₁ , Tr ₁ ; Tr _n , Tr ₁₂ ; Tr ₂₁ , Tr ₂₂ ; Tr ₁₁ , Tr ₃₂ ) is, and that the coil (L) is connected to the emitter of the second transistor ( Tr ₁ ; Tr _n ; Tr ₂₂ ; Tr ₃₂ ) . 2. Multivibrator according to claim 1, characterized in that a thermistor (Rth ₁₀ ) is located between the collector of the first transistor (Tr _n ) and the emitter of the second transistor (Tr ₁₂ ). 3. Multivibrator according to claim 1, characterized in that the base and the collector of the first transistor (Tr ₂₁ ) are coupled via a further capacitor (C _21).