DE2515654A1 - Proximity switch using oscillator, demodulator and amplifier - has RC circuit connected in series with oscillator output - Google Patents

Abstract

The proximity switch has an oscillator (13), a demodulator (16) with a shorter reaction time and a switch amplifier (18), contained in a common switch housing (11), together with positive and negative current supply lines (19, 21). An RC circuit is connected in series with the AC output of the oscillator (13) and one of the current supply lines (19), the time constant of the RC circuit being greater than the reaction time of the oscillator (13). A transistor (T) is connected wit the its output in parallel with the capacitor (C) of the RC circuit, this capacitor (C) having a capacitance of less than microfarad. A low ohmic resistance is connected between the current supply line and the switch amplifer, with the transistor input between the amplifier and the resistance.

Description

PROXIMITY SWITCH The invention relates to a normally open proximity switch with a damped oscillator, with a demodulator following the oscillator, which has a significantly shorter settling time than the oscillator, and with a switching amplifier following the demodulator, all of these parts sitting in a common proximity switch housing, as well as with a plus power supply line leading to these parts and a minus power supply line ##### ###### ### ####.

The problem with approach shocks is basically that little Use components as much as possible, since the housing is often only the size of a small one Have fingers.

Since the available interior space is usually cylindrical, has it is also more difficult to accommodate the existing components and lines than e.g. where printed circuits can be used or available standing room is quite flat.

In the case of approaching slugs, the heat development always prepares Difficulties as the space available is limited and special cooling is required cannot be provided.

In the case of proximity switches, particular importance must be attached to the fact that the failure rate is as low as possible. For example, shows a proximity switch on his The only reason that the output is a "machine part present" signal is because in the proximity switch If there is an error, this can lead to very great damage.

A "closer" in this terminology is understood to mean one Proximity switch whose open resonant circuit coil is damped by the machine part whose oscillator then no longer oscillates and which then at its output emits a signal "machine part present". Gerode at these proximity switches it happens regularly when they are switched on to the network that a certain time passes until - with the machine part not damping - the oscillator starts to oscillate. The following demodulator briefly receives the same signal as when a machine part would actually be present.

This can lead to the great destruction mentioned above, because in In reality there is no machine part, rather the oscillator is still vibrating not. A so-called "switch-on flip" now occurs at the output of the switching amplifier. which has to be suppressed. The applicant has proposed internally for this purpose, a R-C element from the input of the demodulator to plus. Now becomes the proximity switch switched on, the capacitor initially presents a very small resistance and the input of the demodulator is pulled to plus. A change in tension in this direction is synonymous with "no machine part available" and therefore there is no output signal at the output of the switching amplifier, although the oscillator initially does not oscillate. Only when the capacitor is fully charged does it turn on it represents an infinitely high resistance and the input of the demodulator is now controlled by the oscillator and no longer by the R-C-Glted.

According to the main application, it is known a contactless voltage switch to protect against the consequences of a short circuit in the load circuit. At time intervals, which are determined by an R-C element, checked whether the short circuit still exists. Since this and the test time can be kept extremely short, time intervals can be relative If they are far apart, the contactless switch does nothing during the test process off when the short-circuit current flows through it for a short time, as it is during the breaks Can dissipate lost heat again.

The object of the invention is to find a circuit that works with normally open contacts both avoids the switch-on flip and can also be used according to the Main login the contactless voltage switch from the consequences of a short circuit to protect. The number of components should not, or at least not be essential should be increased and at the same time despite the solution of these two subtasks the volume occupied by the components can be reduced.

According to the invention, this object is achieved by the following features: a) An R-C element is connected in series with the alternating current output of the oscillator to one of the power supply lines, the time constant of this R-C element is longer than the settling time of the oscillator, on the other hand also that for the Short-circuit delete has the required time constant.

b) A transistor has its output parallel to the capacitor, which is significantly smaller than 1 microfarod.

c) There is a low resistance from the power supply line to the switching amplifier and between the switching amplifier and resistor is the input of the transistor.

The arrangement according to claim 2 leads to particularly favorable reloading ratios and time constants, low load and few components.

R2 The features of claim 3 support the work resistance and the capacitor switch-on suppression capability of the aforementioned R-C link.

Further advantages and features of the invention emerge from the following Description of a preferred embodiment. The only drawing shows a schematic circuit diagram.

In a housing 11, which is only shown in dashed lines, are potted and arranged an open resonant circuit coil 12. This is with a Oscillator 13 connected e.g.

which can be seen from DT-PS 1 616 280 shape. The oscillator 13 controls a demodulator 16 via a line 14. This can in itself known manner essentially consist of only a single transistor. He demodulates the AC voltage of the oscillator 13 and outputs the demodulated voltage as DC voltage with the correct polarity via a line 17 to a switching amplifier 18. The Working resistance for the demodulator 16 is the resistance R 2, which of the Line 17 is after the plus line 19. An output capacitor C 1 is connected to the line 17 to the minus line 21. The switching amplifier 18 gives its output signal on the output line 22.

From the line 14, a resistor R 1 goes in series with one Capacitor C. Resistor R 1 is 120 kilohms and capacitor C is 0.01 Microfarads. From the point of view of short-circuit protection, the resistance corresponds to R 1 the resistor R in the principle of the main application, which has 3.3 megohms there. The capacitor C corresponds to / the capacitor C of the main application, which there 1 microfarad, the mode of operation of the capacitor C of the main application is inverted.

From the switching amplifier 18 to the positive line 19 is the protective resistor Rs, which corresponds to the resistance of the same name in the main application.

Finally, a transistor T is provided, the base of which between Rs and the switching amplifier 18 is connected. The emitter of the transistor T is connected to the positive line and the collector of transistor T is between R 1 and C.

When comparing this circuit with that of the main application What is particularly noticeable in terms of volume is that the capacitor C is around a hundred times smaller Has capacity, which is very noticeable in terms of volume. The resistor R 1 has here 120 kilohms, while the resistor R of the main application has 3.3 megohms. the A different number of ohms does not lead to a significant reduction in volume in the case of resistors. However, a lower resistance is better than the one in factories there are fewer interference pulses that are always present, either wirelessly or via wire catches.

With regard to the short-circuit protection, the components R s, T, C and R 1 oscillating exactly as described in the main application. After expiration that determined by C and R 1 Time constant is checked whether the Short circuit is still present and if so, the switching amplifier 18 is over the line 17 of the demodulator 16 is enabled. The time constant of the oscillation is dimensioned so that the transistor in the switching amplifier 18 is in the pauses can give up its power loss and the power loss during the test period is limited to a permissible value.

In the case of switch-on flip suppression, on the other hand, the components are R s and T not involved.

Only components C and R 1 are effective here: Put it on the plus line 19 and the minus line 21 the corresponding voltage, then the oscillator oscillates 13 only after voltage has been applied. The demodulator sees within this period of time 16 on the line 14 so the same signal as when the resonant circuit coil 12 would be attenuated by a machine part or the like, and on the output line 22 the signal "machine element present" is then available. However, this prevents that R-C element R 1, C. At the moment the voltage is applied to the positive line 19 and the minus line 21, the capacitor C provides negligible AC resistance The line 14 therefore goes to plus. This corresponds to the signal "no machine part present "and a corresponding signal is then of course also on the output line 22 displayed.

So the ad is correct.

As this embodiment shows, you can use the same number of components and with a considerable reduction in volume both the switch-on flip suppress and protect the switching amplifier 18 in the event of a short circuit.

From a comparison of the circuit of the main application with the present Circuit can also be seen that now the diode D has been saved, since the Transistor with its collector-emitter path and its collector-base path a discharge of the capacitor C is prevented in the absence of a short circuit.

Claims (3)

Claims Proximity switch designed as a normally open contact with a dampenable oscillator, with a demodulator following the oscillator, having a significantly shorter settling time than the oscillator and with a switching amplifier following the demodulator, all of these parts sitting in a common proximity switch housing, as well as with one to these parts leading plus power supply line and a minus power supply line characterized by the following features: a) An RC element is connected in series from the alternating current output of the oscillator to one of the power supply lines, whereby the time constant of this RC element is greater than the settling time of the oscillator and, on the other hand, also has the time constant required for short-circuit extinction . b) A transistor has its output parallel to the capacitor, which is considerably smaller than 1 microfarad. c) There is a low resistance from the power supply line The input is to the switching amplifier and between the switching amplifier and the resistor of the transistor. 2. Proximity switch according to claim 1, characterized in that the emitter of the Transistor on the positive power supply line lies, and that the capacitor with its one pole is also there. 3. Proximity switch according to claim 1, characterized in that the working resistance of the demodulator from the collector of the demodulator transistor to plus and a capacitor from the collector to minus. Blank page