DE1289132B - HF oscillator which is switched on and off by a metallic body introduced into the magnetic field of the feedback transmitter - Google Patents

Description

It is known to use RF oscillators by means of metallic flags, tooth lock washers and the like, which are introduced into the coupling path between the resonant circuit and feedback coil be controlled from the vibrating to the non-vibrating state and thereby Gain measurement or counting signals. Beyond the simplest arrangements, the practical consist only of the resonant circuit, the feedback coil and an amplifier element, oscillator arrangements have become known with which z. B. a particularly large one Ratio between the oscillator currents in oscillating and non-oscillating State can be achieved, or those in which achieved by special negative feedback is that the vibrations in a very precisely defined position of the control flag on and off.

The control of the oscillators from the non-oscillating to the oscillating state and vice versa takes place in all cases by changing the coupling. The oscillators do not oscillate below a certain coupling; above this coupling they oscillate, as can be seen from the well-known formula for self-excitation k - V> 1.

In the known oscillators, a specific gain factor is set by the dimensioning of the components. A coupling of the size is then necessary for self-excitation The mechanical system influencing the degree of coupling is often oscillatable, in the general case a spring-mass damping system. This also includes systems in which the spring is a compressible medium, e.g. B. air, and the mass is a liquid. If the mechanical system influencing the degree of coupling oscillates, the coupling factor k changes unintentionally and uncontrollably by the amount j-A k, and the oscillator oscillations start and stop several times when the mechanical oscillations are at the critical point occur, so that counting errors or incorrect switching are possible.

The invention is based on the object of creating an oscillator, with the oscillations of the system to be scanned on the behavior of the oscillator do not have any effect, so that incorrect switching or incorrect counting can be avoided.

One solution to this problem according to the invention is to increase the gain factor of the amplifier element at the same time as the oscillator starts to oscillate. Since the onset of the oscillations takes place at a value k - V that is slightly greater than 1, i.e. k also only slightly greater than must be means an increase of. V, e.g. B. by a factor of 2, at the point in time at which the coupling factor k is present, a product k - V> 2. Only when k is reduced by at least a factor of 2 do the oscillator oscillations stop again. Changes in k by dk caused by mechanical vibrations in the system to be scanned thus no longer affect the vibration behavior of the oscillator. Devices according to the invention are particularly useful for scanning jerky or pendulous moving parts, e.g. B. transmission parts of liquid meters, due to vibrations or fluctuations in measured values oscillating pointers of measuring devices, etc., suitable. A device for implementing the concept of the invention is described below and illustrated by the figure. (The considerations are made for a pnp transistorized Meissner oscillator. Of course, they also apply to all other circuits that can be used to generate oscillations, e.g. three-point circuit, Huth-Kühn circuit, etc.) FIG. 1 shows a normal Meissner oscillator. A resonant circuit L, C, is located in the collector circuit of a transistor Tr, and is fed back to the base of Tr, via the coil L2 (or a resonant circuit L, C2). A suitable base voltage is set via the divider resistors R and R2. The oscillator can e.g. B. by a pivotable in the coupling path between the coils L, L2 cover A, z. B. pointer flag of a measuring instrument, perforated or toothed disk (slotted disk) for measuring revolutions or speeds of rotating shafts, gear parts od. Ä. Are caused. In position 1 of the cover plate A is z. B. the coupling is so small that k - V is much smaller than 1. In position 2 the coupling is just so great that k - V = 1 . Slight fluctuations around dx lead to changes in k around dk and thus permanent fluctuations (k : L dk) V = 1 ± dk - V, which cause incorrect counting or incorrect switching.

The oscillator carries a current that depends on its vibrational state is dependent. This stream can e.g. B. measured with an ammeter J.

F i g. 1 a shows a device according to the invention for implementation of the general idea of the invention. With the capacitor C3 the oscillation voltage decoupled from the resonant circuit L, Cl and rectified in the diode Dl. the The negative voltage now occurring at the negative pole of the diode is passed through the resistor R3 the base of the transistor Tr, supplied. This process is below summarized under the term DC feedback. The one with the DC feedback associated increase in the base voltage of Tr causes an increase in the gain. It goes without saying that the divider R 1, R2 for the base voltage can be selected appropriately of the operating point of Tr, must be set so that the gain that is without DC feedback is smaller than the gain with DC feedback.

The device according to FIG. 1 behaves up to the switching point k − V = 1. 1 a just like the known device according to FIG. 1. As the oscillator starts to oscillate, due to the direct current feedback according to the invention due to the higher gain of the transistor Tr ,, the product k - V is now much larger than 1. However, since only a value of k - V is slightly larger to maintain the oscillations than 1 is required, k may now decrease sharply, ie the vibrations of the cover disk around dx, which cause a change in k around dk , do not lead to the at F i g. 1 described disadvantages (incorrect counting, incorrect switching).

In Fig. 2 is the behavior of the oscillators according to FIG. 1 and 1 a shown. The dashed line shows the dependence of the current on the coupling in a conventional oscillator. at the oscillator does not oscillate and the quiescent current Jo flows. With increasing coupling, the current also increases from the value 1 and finally reaches its maximum value. In the event of a change in k caused by the system to be scanned by 4 k at point k = 1 , the current fluctuates between its two extreme values, as a result of which the aforementioned incorrect counts or incorrect switching occur. The solid line shows the dependence of the current on the coupling in an oscillator according to the invention. Below the quiescent current also flows Yes. With a slight increase in coupling over In addition, the current suddenly assumes its maximum value as a result of the direct current feedback described. If the coupling is reduced or increased by small amounts, the maximum value remains. Only when k is reduced to a fraction, which is smaller than the increase in V caused by the direct current feedback, do the oscillations suddenly stop.

The device according to the invention provides a further advantage achieved: As already mentioned and in Fig. 2, the current increases with the common ones Oscillators start up relatively slowly after reaching the critical coupling. The rise time depends on the speed of the mechanical that influences the degree of coupling Systems. However, such a current curve is for direct further processing not suitable. There must be pulse or edge-shaping elements such. B. Schmitt trigger or the like. In contrast, in the case of the invention with a Equipped with direct current feedback, the onset and tear-off of the oscillators Vibrations, and consequently the rise and fall of the current, independently on the speed of the mechanical system influencing the degree of coupling in such a short time that pulse-shaping elements are dispensed with can.

Another arrangement according to the invention, the one. compared to FIG. 1 a shows an improved effect is shown in FIG. 3 shown. Instead of a diode, a transistor Tr2 is used to rectify the HF voltage coupled out with the capacitor C3. It is advisable to switch the collector-emitter path of Tr and the divider resistor R1 in parallel, thereby changing the divider ratio Because the transistor has an amplifier effect compared to the diode used in FIG. 1 a, the desired influence on the gain factor is greater than in the case of the diode. As a result, the vibrations reach their maximum even faster. The preceding shows how the avalanche-like onset and breakdown of oscillator oscillations can be achieved by increasing the gain of a transistor by means of direct current feedback. F i g. 4 shows a further arrangement according to the invention, with which a similar effect is achieved by abruptly supporting the oscillation state of the oscillator with the aid of an increase in the feedback portion of the alternating voltage generated in accordance with the increase in the alternating voltage amplitude.

A resonant circuit L3 C6 or an inductance L3 or an ohmic resistor R5 is connected in series with the resonant circuit L, Cl. The high-frequency voltage is again supplied to the base of a transistor Tr through a capacitor C3. The collector of Tr is connected via a capacitor C to the connection point between the resonant circuit L, Cl and L3 C, or L3 or R, respectively. If the coupling is less than and the oscillator oscillations have not yet started, the resistance of the collector-emitter path of the transistor Tr, is high, and the capacitor C, cannot yet take effect. The high-frequency voltage is divided by the series connection L, C, and L, C, or L3 or Rs. If the coupling is a little larger than this, the oscillator vibrations set in, the basis Tr3 receives a small high frequency voltage, and the resistance of the collector-emitter path of Tr3 decreases. As a result, C, becomes partially effective, and the proportion of the high-frequency voltage at L1 C1 increases. However, since L1 Cl is fed back via L2 C2 or L2 to the basis of Tr, this means an increase in the fed back energy, which increases the absolute level of the high-frequency voltage. Tr, receives even more voltage via C3, the resistance of the collector-emitter path of Tr3 continues to decrease. C, becomes very effective, so that there is practically no more division of the high-frequency voltage, but only high-frequency voltage is present at L, Cl. The whole process takes place like an avalanche, so that in terms of current, the behavior of the circuit again roughly according to the solid line in FIG. 2 is created. The suspension of the vibrations also takes place again as tearing off. The processes described above are repeated in reverse order.

The circuit according to FIG. 1 is particularly effective. 4 then when the feedback loop in the base line. von Trl is a complete resonant circuit that is tuned to the same frequency as the collector resonant circuit L, Cl. It is then expedient, as in FIG. 4, a resonant circuit L3 C6 or an inductance L3 connected in series, which cause a strong detuning of the frequency in the entire collector circuit, which is canceled when the oscillations start in the manner described above, that C, becomes effective and then L, Cl are solely determining the frequency. This means a further increase in the fed-back energy, since now not only a larger voltage from L, Cl acts on L2 C2, but also the correct frequency.

In order to achieve an even greater hysteresis, it makes sense to to build an oscillator, which at the same time gain through a circuit according to FIG. 1 a or 3 and the fed-back energy by a circuit according to F i g. 4 can be increased. Such a circuit can be made by connecting F i g. 1 a and 4 or 3 and 4 are easy to produce. Two amplifier elements are used for this or a diode and an amplifier element are required.

A further arrangement according to the invention, which has only one additional amplifier element and in which both the gain and the feedback energy are nevertheless increased at the time of decay, is shown in FIG. 5 shown. The high-frequency voltage is again decoupled from the resonant circuit L, Cl with the capacitor C3 and fed to the base of Tr ,,. As in Fig. 3, the collector-emitter path of Tr, the divider resistor R1 is connected in parallel and changes the divider ratio in the presence of a high-frequency voltage by reducing the resistance of the collector-emitter path so that the transistor Trl is operated in the region of a higher gain. Furthermore, as in FIG. 4 upstream of the resonant circuit L, C, a resonant circuit L3 C6. Since the collector of Tr4 is at the connection point between L @ Ci and L3 C6 and the emitter of Tr4 is at the capacitor C4, which practically represents a short circuit for high frequencies, the collector-emitter path of Tr4 is only a small one when a high frequency voltage is present Has resistance, C4 as a high-frequency short circuit at the upper end of L, C, effective. This arises in the explanation of FIG. 4 shown increase in the fed-back energy. An arrangement according to FIG. 5 thus combines in the desired manner the advantages of the arrangements according to FIG. 3 and 4.

Arrangements are also conceivable in which the coupling is not through a cover or the like. Is changed, but z. B. by means of a through a Capacity formed by liquid and two metal layers. With the appropriate arrangement the height of the liquid column affects the size of this capacity, the z. B. forms a capacitive coupling path or a capacitive dissipation of the coupling energy caused. Here, too, by designing the circuit according to the invention, similar to FIG. 1 a to 5, can be prevented that, for. B. Fluctuations in the liquid column lead to incorrect switching.

Claims (4)

Claims: 1. RF oscillator, which by one in the magnetic field the metal body introduced by the feedback transmitter on and off is, characterized in that measures are provided after the oscillation of the oscillator cause such abrupt support of the oscillation state, that a backward movement of the triggering metal body up to a defined Point has no influence on the vibration state and only after it has been exceeded At this point there is an abrupt suspension of the vibrations. 2. RF oscillator according to claim 1, characterized in that the sudden support of the oscillation state by abruptly increasing the gain of the active element with the help of a DC voltage obtained by rectifying the output AC voltage takes place. 3. RF oscillator according to claim 1, characterized in that the sudden support of the vibration state by increasing the fed-back share of the generated AC voltage takes place in that the rising AC voltage has a transistor opens, the one lying in series with the primary winding of the feedback transformer HF series resistor short-circuits. 4. RF oscillator according to claim 1 to 3, characterized in that that the sudden support of the vibrational state by sudden increase the amplification of the active element and by increasing the energy fed back takes place with the help of a transistor opened by the output AC voltage, one of the series resistor used to supply the current to the base electrode and one in series with the primary winding of the feedback transformer HF series resistor bridged.