DE1638072C - Circuit arrangement for detecting an input variable by means of an oscillator circuit - Google Patents

Description

4. Circuit arrangement according to claim 1 or an oscillation or non-oscillation of the oscillator of the following, characterized by 35 tor. This requires a relatively low cut-off frequency that in the feedback circuit (9, 10, 14) of the oscilloscope the initiator, because with a signal change must lators (3, 4, 6) an amplifier element (14) to the oscillator starting or stopping. Extraordinary is. in the vibrating state the vibrating

5. Circuit arrangement according to claim 4, there is constant energy for the control of the tilting through characterized in that the feedback 40 amplifier is withdrawn. This disadvantageously results resistance (9, 10) of the oscillator (3, 4, 6) and a relatively large one, which requires the maximum switching distance Activation resistor (19) of the input transi- tion limit, basic attenuation.

stors (21) of the same type in the same size. The object of the invention is to provide a

Large resistances formed to create circuitry for initiators that will. 45 can be steered to as great a distance as possible

and whose switching frequency is as high as possible.

According to the invention, this object is achieved in the

initially specified circuit arrangement thereby

solved that a voltage divider is provided, the 50 via a current measuring device and an isolating diode

The invention relates to a circuit with one point of the resonant circuit of the oscillator Order is connected to the detection of an input variable by means of such that the voltage of an oscillator circuit, in which the vibrations divider, a response value of the current measuring device at of the oscillator by means of a rectifier circuit in a certain oscillation amplitude of the a signal for downstream links formed 55 resonant circuit results.

will. In the circuit arrangement according to the invention

Initiators of control devices represent input, thus a signal change is not dependent on a control device. B. Path, position, speed. In the oscillator, but depending on the over-contrast e.g. B. to limit switches detect Initia- 60 stepping or falling below a certain goal the positions of moving parts contactless oscillation amplitude of the oscillating circuit. The contact and contactless. The determined position is converted into speaking amplitude by the voltage divider, a signal that determines the downstream, which practically also limits the amplitude of the function elements (AND elements, OR elements. The oscillation amplitude remains, etc.) of the control device. Generally speaking, if there is a change in the signal from the initiator, the signal is a given signal that is almost constant. This results in a pre-yes / no signal. The contactless detection sometimes takes place at a high switching frequency,
by means of an oscillator, the oscillation of the- Die in known circuit arrangements, in particular

3 4

A further advantage of the oscillator circuit I provides Greater elcmentes of the oscillator given limiting simple oscillating circuit, which consists of only one The oscillation amplitude increases in the case of the coil 4 and one having two connections proper circuit arrangement does not occur, since capacitor 6 exists. By using a the limitation by the voltage divider before a 5 transistor 14 in the feedback circuit becomes a puts. In other words: Avoided transformer feedback in the case of the invention, so that A circuit arrangement is also known, for example, the coil 4 alone in a shell Circuits existing limitation of the amplifiers arranged and easily over only two lines loaded the resonant circuit to derive a signal as a separate probe head to the oscillator circuit exploited. An additional can be connected throughout the io. This is also without Vibration course dampening withdrawal difficulties the arrangement of a galvanic Energy for a flexible link is therefore unnecessary. see separation causing transformer instead If the limitation is not effective, the coil 4 can therefore be used. The ones not with the oscillating circuit the oscillator of the circuit-connected winding of the transformer according to the invention can be assigned swing freely. As a result, compared to 15, for example, it is designed as a probe head to another dampening external influences sensitive inductance or also to a 'contact ancher than known circuits. This gives the pre-closing. The arrangement of a separate unit control over greater distances. tragers is particularly important for intrinsically safe control

Another advantage of the inventive circuitry of the oscillator circuit is expedient,
The point of the resonant circuit 4, 6 of the oscillation of the response value of the operating voltage circuit I is via an isolating diode 16 and a voltage, without the need for special means for the voltage current measuring device with one of two resistors - ■ stabilization is required. As the level 20, 24 increases, the cut-off voltage formed on the lines 11, 11. namely grows both the voltage divider closed by the Os- connected in such a way that -'iüalor for the actuation of the current measuring device 25 a response -'ur provided current by the voltage divider 20, 24 as well as the value of the current measuring device required for a certain Suommeßeinrichtung Electricity. This results in the oscillation amplitude of the oscillating circuit 4, 6 a desired compensation. are. The isolating diode 16 simultaneously provides the DC

In the following sol! the invention on the basis of the converter circuit, by means of which from the vibration

In the embodiment shown in the figure, a signal is derived in more detail from the oscillator. One

to be chewed. Terminal of the rectifier 16 is therefore with a

The circuit arrangement shown in the figure for capacitor 17 is connected, the other terminal of which consists of initiators of control devices and is connected to line 7.
Oscillator circuit I and a flip-flop II. The current measuring device is formed by the actual oscillator of the oscillator circuit I is 35 emitter path of an input transistor 21 and a transistor 3 as well as a parallel resonant circuit connected to its base and a control resistor connected to the base, consisting of 19. Accordingly, they are also formed from a coil 4 and a capacitor 6. Base of transistor 21 via a resistor 18. The connection point of the collector of 3 to the connection point of diode 16 with resonant circuit 4, 6 is denoted by 5. The 40 each capacitor 17 and the emitter of 18 are connected to the other terminal of the coil 4 and the capacitor 6 voltage divider 20, 24. The base is connected to a line 11, the reference emitter path of the transistor 21 is thus of potential *. The emitter of the transistor 3 is driven by a current set by the resistor 19 via a resistor 2 on a line 7.

45 In the exemplary embodiment, the input transistor

will lead. 21 with another transistor 29 in a toggle

Circuitry is arranged in the feedback circuit of the oscillator 3, 4, 6, with a feedback unit amplifier resistor 22 formed by a transistor 14 at a connection point of two element arranged. Connect the collector resistors 19, 23 is connected, the one with the of the transistor 3 series-connected resistors 9, 50 base of the input transistor 21 and with the line 10 connected to the base of transistor 14, while the 11 form voltage divider connected. The resistance collector of 14 and the base of 3 directly connected 19 are high ohms to the resistance are switched on. Next are the collectors from 14 to 23. For 22, one can also conveniently Via a resistor 13 to the line 7, the low resistance can be provided. - Emitter of 14 through a resistor IS to the line 55 of the transistor 29 are the emitter to the line 11 and the base of 14 via a resistor 11, the collector to the resistor 22 and stood 8 to the emitter of the transistor 3 and via a resistor 28 to the line 30 and the a resistor 12 connected to the line 11- base at the junction of two resistors. connected to 26, 27 between the

Through the emitter resistors 2 and 15 a 60 gate of the transistor 21 and the line 11 is switched current negative feedback, through the resistor 8 are one. Next, the collector of 29 is achieved with the off-voltage negative feedback. This negative feedback gear 31 of the flip-flop circuit II is connected,
lungs result in an operating point stabilization and between the lines 7, 30 a sieve resistance is a stabilization against temperature influences. was provided 25, which together with a between 65 see the lines 7, II arranged capacitors also largely independent of specimen scatter tor 1 to smooth the generated by the oscillator I 'of the transistors. The latter is used in particular- high frequencies,
which are cheap for production. Has proven to be particularly useful, the

Feedback resistor 9, 10 of the oscillator 3, 4, 6 and the control resistor 19 of the input transistor 21 with similar resistances of the same order of magnitude. This measure advantageously results in extensive independence of the entire Circuit arrangement against temperature changes.

The mode of operation of the circuit arrangement shown in the exemplary embodiment is as follows:

If there are no electrically conductive objects in the vicinity of the coil 4 of the oscillating circuit 4, 6, the oscillator 3, 4, 6 can oscillate. The oscillation amplitudes of the oscillating circuit are 4.6 but not as in known circuit arrangements by the oscillator circuit I, in particular limited by the operating point setting of the transistor 3, but rather by the voltage divider 20, 24. The limitation is effective for one polarity of the oscillations and only when one is through the Voltage divider 20, 24 predetermined response amplitude is exceeded. In the intervening The oscillator 3, 4, 6 oscillates during a period without a dampening output of energy to control the flip-flop (as in known circuit arrangements) is required. This gives advantageously a great sensitivity to external on the coil 4 by means of an electrical conductive object acting dampening influence. - After falling below the response amplitude the resonant circuit 4, 6 absorbs energy until the response amplitude is reached again. the Energy consumption is determined by the feedback resistors 9, 10 and the transistors 3, 14. It can be set by selecting the resistors 9, 10 accordingly. The choice of resistors 9, 10 is synonymous with setting the sensitivity of the initiator.

The amplitude peaks (current peaks) resulting from the energy absorption specified above are used to control the flip-flop II. These current peaks are transmitted via the Diode 16 placed on the capacitor 17 and smoothed by this. The charge on the capacitor 17 can terminate via the resistors 18, 19, 23. The total resistance value is essentially determined by 19. When the capacitor 17 is appropriately charged, the transistor receives 21 therefore no control current and blocks. Then also blocks the transistor 29 and on the Terminal 31 is practically operating voltage.

The circuit arrangement according to the invention can also be created with an oscillator which has transformer feedback, but the circuit arrangement specified in the exemplary embodiment has, among other things, the following special features: When the operating voltage applied to line 30 changes, both that of the oscillator circuit change I output current peaks as well as the current determined by the resistor 19 in the same way. This gives a desired compensation. If the resistors 9, 10 and the resistor 19 are of the same order of magnitude and show the same behavior towards external influences {z. B. temperature), these influences are largely compensated for. - Since the oscillator circuit I is also stabilized against changes in transistor properties and temperature influences by negative feedback (resistors 2, 15, 8) and there is also a temperature stabilization of the response value of the flip-flop circuit II by counter-switching the diode 16 with the base-emitter path of the transistor 21, this results overall a very great independence of the properties of the circuit arrangement specified in the exemplary embodiment.

As soon as an electrically conductive object is approached to the coil 4, a corresponding one results Damping the oscillations of the resonant circuit 4.6. The current peaks supplied to the capacitor 17 become smaller and the transistor 21 is activated. The flip-flop II switches. Despite the Switching, however, the oscillator 3.4.6 also oscillates almost unchanged amplitude. This results in a high switching frequency; because a change of the output signal tapped from 31 is not associated with oscillation or non-oscillation of the oscillator connected.

The advantages achieved with der.Erfindung are in particular that a circuit arrangement was created for initiators of control devices that allow control over large distances allowed, has a high switching frequency and is largely independent of changes in the Has operating voltage. In addition, the circuit of the exemplary embodiment results in a great stability against temperature influences.

1 sheet of drawings

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Claims (3)

1 2 same of a ferromagnetic or electrical patent claims: conductive body is controlled. This body is connected to the moving part, its 1. Circuit arrangement for detecting a position is to be detected. Somehow it turns out Input variable by means of an oscillator circuit, 5 depending on the position of the ferromagnetic in which the oscillations of the oscillator by means of or electrically conductive bodies have an influence a rectifier circuit into a signal for the oscillation of the oscillator, which into a signal for downstream links are reshaped, and subsequent links of the control device are reshaped marked that a chip is formed. voltage divider (20, 24) is provided, which via an io It is already a circuit arrangement for Initia current measuring device (23, 19, 21) and a gate of control devices known in which mn Isolating diode (16) with a point (5) of the means of an oscillator circuit contact and calm-resonant circuit (4,6) of the oscillator (I) such an input variable is detected without a hitch (Siemens connected is that through the Spannstei magazine (1965), issue 4, p. 394). The vibrations Ler (20, 24) a response value of the Strommeßein- 15 of the oscillator control an inductively coupled direction (23, 19, 21) at a certain trigger amplifier, to which the oscillator signal via a Oscillation amplitude of the oscillating circuit (4,6) diode and a smoothing capacitor supplied results. will. The oscillator has a transformatoriscru 2. Circuit arrangement according to claim 1, there- feedback. There are in an open Scha characterized in that the current measuring device 20 handlebars the windings of the Schwingkrcisspuk device (23, 19, 21) differ from the base-emitter path of the feedback coil and the interrogation coil Input transistor (21) and housed at least. For the frequently requested accommodation a control of the coils connected to the base in a separate probe head, dui resistance (19) is formed. according to the current control 3. Circuit arrangement according to claim 2, that a ₅ would be formed, difficulties arise, d; characterized in that the input transistor requires more than two connecting wires (21) with a further transistor (29) in one. In addition, there is a risk of confusing the flip-flop circuit (II), with one connecting wire being given. The oscillator is controlled by a feedback resistor (22) at a connection point brought into the stray field of the coils by two resistors (19, 23) electrically conductive object. Form this eddy currents, which extract energy from the oscillating transistor (21) connected to the voltage divider circuit. The control of the oscilloscope. lators and thus corresponds to the delivery of a signal