DE865007C - Circuit arrangement using magnetically overdriven iron chokes - Google Patents

Description

Circuit arrangement using magnetically overdriven Iron chokes are known to generate multiples of a basic frequency Magnetically overdriven iron chokes are advantageously used. If you send through the Iron inductor a sinusoidal alternating current of sufficient strength such that strong magnetic oversaturation of the choke occurs in the cycle of the alternating current, in this way, a electromotive force in the form of a voltage spike with alternating signs is positive and negative. The harmonic analysis of the alternating voltage shows that in the voltage curve obtained in this way, only odd multiples in addition to the fundamental frequency the fundamental frequency are present. It is also known that when a other frequency above the fundamental frequency current except for the odd multiples the base frequency nor the side frequencies of the even multiples of the base frequency appear. The magnetically overdriven iron choke acts as a so-called harmonic modulator, if, in addition to the magnetizing current of the fundamental frequency, there is also a current of a modulating one Frequency of the iron choke is fed.

If a harmonic modulator is loaded by the external resistance in the frequency ranges of the sidebands, sideband currents arise which have recently modulated in the choke, ie they in turn cause new side frequencies of the even harmonics of the fundamental frequency. So arise z. B., if you have a harmonic modulator with the. Fundamental frequency fg supplies a modulation frequency n, including electromotive forces of the sidebands' 2 @ fg + _n. If now the modulator z. B. for the frequency (2 f gn) ._ is loaded with an impedance _N, a current of the frequency (2 fg-n) is created, which is now additionally magnetized and thus as side bands of z fg electromotive forces of the Frequency 2 f g- (2 f g-41) = n and 2 fg -i- (2 f g-42) = q, fg-n generated. Thus, among other things, there is an additional EMF of the modulation frequency n, which acts as a feedback. The additional EMF is in phase with the current of the modulation frequency when the current of the sideband frequency (2 fg-n) is in phase with the EMF, i.e. when the load (Ni -I- Ra) of the generator - at the frequency ( 2 fg-n) is real (N = is the operational inductive internal resistance of the modulation choke n), and a real feedback is obtained, i.e. an additional current of the modulation frequency generated by the additional EMI, which is in phase with the original current, even if the load is real for the modulation frequency. However, the feedback is also real if, in the case of complex loads, the phase shift between the additional current and the additional EMF is made equal to the opposite of the phase shift between the sideband current and the sideband EMF needs to make to bring the circuit arrangement to self-excitation. According to the invention, therefore, the iron choke or the iron chokes is loaded with an impedance; which at - an even multiple of the magnetizing basic frequency or at two or more frequencies, the sum or difference of which is an even multiple - of the basic frequency, zeros or infinity points, real minima or real maxima or a dimensioning that shows a real feedback measure of a size that leads to self-excitement.

Further details of the invention are given with reference to FIGS. I to q. explained. In FIG. 1, the frequency scheme of the processes is shown in an arrangement according to FIG. The alternating current source S drives a sinusoidal current via the resonant circuit LC through the iron choke Dr, the magnetization curve of which is thereby controlled into the saturation areas. This creates a voltage with a strongly distorted curve shape at the choke, which, in addition to the fundamental frequency fg, also has the odd-numbered frequency. Contains multiples of 3 fg, S fg, etc. If, in addition, a second alternating current of frequency f is sent through the choke Dr from the current source S 'via a series resistor R ", as indicated by dashed lines; the side frequencies of the even multiples z 1g, 4f, etc. . -sei For example, a time so there arise the side frequencies b, -.. c and d; e. üsw If the frequency f = b were to be selected, the frequency would be reversed arise a.

At. With an unloaded choke, the EMF of the modulation product in question is linearly related, as has been confirmed by measurements, to the current of the modulating frequency for a certain amplitude range. So it is true E'b = Jd'27ab, E'd = Jb'7% ba (i) E #: Ea = Jc # r% cd l If you now load the throttle via two resonant circuits L1, Cl and L2, C2 with the resistors R1 and R2 and agree z. B .. the circuit i on the frequency a and the circuit 2 on the frequency b , then as a result of the EMF Eb a current of the frequency b arises, which conversely again causes an EMF E, which causes a current. through the choke and the circuit i that supports the current supplied by S '. So you have a feedback, and self-excitation occurs even if S 'and R "are not present It is assumed that 'the throttle Dr; the inductances L1, L2 and the capacitances Cl, C2 are free of loss resistances. If there are losses, the total loss resistances of circuits i and 2 must be inserted in R1 and R2 so that the above instability condition applies.

In the example it has been assumed that only the frequencies a and b are fed back. However, the other modulation products c, d, e etc. also arise in the choke and can be removed if necessary. However, self-excitation can also occur if other modulation products are used for the feedback instead of a and b. So z. B. the circles i and 2 are also tuned to the two side frequencies b and c or d and e. If, for example, the circle i @ is tuned to the frequency b, the frequency c is the side frequency of the even multiple -4 f and the fundamental frequency is the frequency c. The two circles are also tuned to a modulation frequency and to one of the resulting side frequencies. It has been shown - that. it is particularly advantageous --- to tune to one of the lower side frequencies that arise. A special case arises for a = 2 fg. Then: namely the frequencies a and d coincide, namely to the relevant multiple 2 fg. So if you tune to 2 fg or another even multiple of the basic frequency (you only need one resonance circuit); so can self-excitement occur. The even-numbered multiples of the basic frequency then arise. For a = fg or 3 fg etc., self-excitation results in odd multiples of the round frequency in the same way.

The practical application of a frequency doubler working according to this principle or multiplier etc. is shown in Fig.3i. With this one The embodiment is the feedback resonant circuit at the same time as an input circuit a band filter F has been used, for example to better sieve out a even multiples of the fundamental frequency, e.g. B, the frequency 2 f "is used.

Instead of the oscillating circuit LC-tuned to the fundamental frequency in FIGS. 2 and 3, a. larger series resistance can be used. The resonant circuits L1, Cl and L2, C2 are shown in Fig. 2, as longitudinal resonant circuits with coils and capacitors. Instead, oscillating crystals or other electromechanical resonators can also be used. It is particularly advantageous to have a. particularly selective resonance circuit, e.g. B. a vibrating crystal, as a circle i and a less selective circle, z. B. a damped coil-capacitor circuit, to be combined as a circuit: 2 to avoid the risk of becoming stable in the event of mutual detuning of circuit i and circuit: z and base frequency fg. to diminish. This is e.g. B. of particular importance if an exact frequency is to be generated from an imprecise basic frequency, which is taken, for example, from the power network. You will then: Form one of the two circles as a vibrating crystal and, if necessary, form the other circuit as a bandpass filter with a characteristic impedance that is flat in the pass band and runs towards infinity in the stop band, which is to be terminated with a real resistance and thus in a larger frequency range has a constant impedance. The inductive internal resistance of the iron choke Dr can, if necessary, be taken into account when tuning the feedback loops. This also increases the degree of feedback in the event of changes. the fundamental frequency constant. For example, the oscillating crystal is tuned to frequency d and the other circle is tuned to frequency a. If the basic frequency fs changes, 4 fg also changes. Since the circuit is less selective for the frequency a, the frequency a can also change without the phase measure in the feedback loops being significantly changed. As a result of the use of a very selective circle, e.g. B. a vibrating crystal, however, the frequency d remains constant. The exact frequency d is then obtained z. B. on a connected in series with the oscillating crystal. Resistance.

You can proceed in a similar way if you use iron knurls with be magnetized with a constant fundamental frequency, wants to generate changeable frequencies. In this case, for example, the resonant circuit tuned to frequency a is made selective and changeable and uses z. B. in place of a second resonant circuit for the frequency d a band filter with a leveled entrance light: resistance.

A feedback generator constructed according to the invention is particularly suitable for generating modulated vibrations, e.g. B. for call and signaling purposes. For example, a modulated ringing current 5oo / 2o Hz can be derived from the 5o Hz network. One magnetizes with this fundamental frequency. an iron choke and couples with io and z. B. 49o Hz or back with iio and goiHz. It then arise. the side frequencies of the even-numbered multiples of 50 Hz, including the frequencies 490 and 50 Hz, which can then be taken and used as a modulated ringing current.

Instead of the simple circuits shown in FIGS. 2 and 3, push-pull circuits and double push-pull circuits can also be used, which offer the advantage that undesirable modulation products, such as the odd harmonics of the fundamental frequency f, are suppressed and also the circuits i and 2 can be decoupled from each other, for example when a and b are matched and the two frequencies are to be taken from different terminals.

In Fig. Q; is the case shown that the throttle, instead of them to feed with sinusoidal current, is applied to a sinusoidal voltage, such as- it has already been proposed. A current then arises in the coil with strong distorted waveform, and man. must then instead of series resonant circuits parallel to Throttle Connect parallel resonant circuits L1, Cl and L2, C2 in series with the throttle. The oscillating circuit LC serving as an energy store is designed as a parallel circuit and instead of in series with the generator S connected in parallel. At R1 and R2 you can then the desired modulation products can be extracted. One such circuit is particularly advantageous if the fundamental wave generator S is operated in under-match will, e.g. B. in a pentode tube circuit as a fundamental wave generator.

The circuit arrangements according to the invention can also be used with advantage Can be used as a selective amplifier if the feedback level is slightly lower chooses so that self-excitement does not yet occur. If this z. B. in an arrangement carried out according to Figure 4, for example by lowering the resistors R1 and R2, a voltage of frequency a can be applied to circuit i (L1, Cl, R1) on circuit 2 (L2, C2, R2) with a different frequency, e.g. B. d, take more.

Claims (1)

PATENT CLAIMS: i. Circuit arrangement using a through a magnetic sinusoidal alternating field or by an applied sinusoidal Voltage magnetically overdriven iron choke or several iron chokes, thereby characterized in that the iron choke or the iron chokes with an impedance are loaded, which is an even multiple of the magnetizing fundamental frequency or in the case of two or more frequencies, their sum or difference is an even number The multiple of the base frequency is whichever is greater than double The basic frequency is, zeros or infinity points, real minima or real Maxima or such a dimensioning shows that there is a real feedback measure of results in a size that almost or actually leads to self-excitation. 2: Circuit arrangement according to claim z, characterized by the use of series or parallel resonant circuits in parallel or Series connection as a load acting on these frequencies or their Proximity are matched. 3. Circuit arrangement according to claim z or 2, characterized in that däß one of the minima or maxima or one of the tuning frequencies of the oscillating circuits is a lower side frequency of an even multiple of the fundamental frequency. q .. Circuit arrangement according to one of the preceding claims, characterized in that that the resonant circuit or one of the resonant circuits is also the input circuit of a Band filter is. 5. Circuit arrangement according to one of the preceding claims, characterized in that one of the two oscillating circuits is particularly selective, z. B. is formed by a vibrating crystal, and the other relatively unselective is e.g. B. is formed by a filter whose characteristic impedance is in the pass band can be leveled. 6. Circuit arrangement according to one of the preceding claims, characterized in that the amount of the real degree of feedback is chosen so is that there is no self-excitation, but only a selective amplification, 7. Circuit arrangement according to one of the preceding claims, characterized by using them to generate modulated signal voltages, e.g. B. for calling purposes in telephone systems.