DE2739786A1 - Capacitive proximity switch with two concentric electrodes - forms capacitor encircled by earthed screen electrode - Google Patents

Abstract

The capacitive proximity switch has a screen and is designed to operate at the same point even in the presence of dust and other contaminants. Two concentric electrodes (15, 16) form the capacitor coupled into the resonant circuit of an oscillator. The two electrodes are encircled by the earthed screen electrode (17). The central electrode may be a plane disc or it may comprise radial arms making a multi-point star. Alternatively, the concentric ring structure may be replaced by alternate screen, first-plate and second-plate segments.

Description

Capacitive proximity switch with a

dividing proximity electrode The invention relates to a capacitive one Proximity switch with a multi-part proximity electrode, one of which Electrode part as a sensing electrode to the input of a vibratory, counter-coupled Circuit and another electrode part as a negative feedback electrode to the Negative feedback potential are connected.

In the case of the known capacitive proximity switches, which in addition to the actual sensing electrode still have a shielding electrode is disadvantageous, that they protect against external disturbances such as dust, condensation, wetting or Soiling are final with the consequence that the approach distance at which a switching process is triggered, often significantly compared to the target switching distance shifts, where ii Extreme case alone due to such interference a switching process triggered or the switching capability of the proximity switch can be canceled.

The invention is based on the object with capacitive, with a ibschiriwig provided proximity switches ensure compliance with the target switching distance even if there are external disturbances such as dust, condensation, wetting or To ensure pollution.

Starting from a capacitive proximity switch of the generic type Art, the solution to this problem according to the invention is that the proximity electrode has a third, grounded electrode part as a ground electrode and that the sensing electrode is geometrically between the negative feedback electrode and the ground electrode.

Through these measures, the proximity electrode embodies two capacitors, namely a ground electrode / sensing electrode capacitor and a sensing electrode / negative feedback electrode capacitor, whose capacity increases with dust, condensation or the like. So that about in the same measure, in the energy to earth via the first-mentioned capacitor flows away, energy via the second-mentioned capacitor vol negative feedback circuit is on the sensing electrode is delivered later.

This creates an automatic compensation if it is present the mentioned interfering influences reached, whereby the target switching point of the proximity switch is kept constant.

In the subclaims several types of embodiment of a three-part Proximity electrode specified according to the invention.

The invention is explained in more detail below with reference to the drawing, 1 shows a circuit diagram of a capacitive proximity switch according to FIG of the invention Fig. 2 in an end view the geometric shape of the three-part Approach electrode, Fig. 3 shows the approach electrode in a vertical section FIGS. 2, 4, 5 and 6 show three further embodiments of the proximity electrode in an end view and FIGS. 7 and 8 show yet another embodiment in an end view and in axial section the proximity electrode.

Fig. 1 shows a contactless and non-contact working capacitive Proximity switch with an oscillator 1, an HF rectifier 2, a switching amplifier 3 and an output stage 4, the output of which is a relay that is only given as an example 5 switches. All circuits are from a common, not shown power supply Supplied with DC voltage via supply lines 6, 7.

The oscillator 1 has an input transistor T1 in a base circuit, its collector via a resistor 8 to the plus supply voltage and its The emitter is connected to the minus or zero supply voltage via a resistor 9, to which the base of T1 is also connected via a resistor 10 Oscillator 1 also includes a current amplifier transistor T2 in an E-collector (base) circuit, whose collector is connected to the supply line 7, while its emitter has a Potentiometer 11 is connected to the supply line 6. The base of T2 is connected to the collector of T1, so that there is a voltage at the base of T2, which of the voltage divider formed from the resistors 8 and 9 and the transistor T1 is delivered. When the transistor T1 is blocked (at the moment it is switched on), T2 is conductive.

Since the emitter of T2 has a negative feedback resistor 12 with connected to the base of T1, T1 receives a certain conductance, which makes the base of T2 assumes a certain voltage potential, the emitter of T2 is over the Potentiometer 11 and a capacitor 13 fed back to the emitter of T1. Of the Degree of feedback is set by the potentiometer 11 such that the In the basic state, oscillator 1 does not oscillate and therefore does not pass to rectifier 2 AC voltage signal supplies.

The oscillator 1 has a three-part proximity electrode 14, whose central electrode part is connected as a sensing electrode 15 to the base of T1 and has an electric field. When a body approaches the sensing electrode 15 becomes the state of equilibrium present in the basic state in a known manner between negative feedback via resistor 12 and feedback via the potentiometer 11 and the capacitor 13 are canceled and the oscillator 1 is brought to oscillate, so that an AC voltage is supplied to the rectifier 2, through the over the circuits 3 and 4 a switching of the relay 5 is effected.

Proximity switches of the type described above require information of the filling electrode 15, if it is only on a body approaching axially from the front should address.

For this purpose, a grounded electrode which surrounds the flat electrode 15 is used Shielding electrode provided, the two electrode parts form a capacitor, its capacitance in the event of stowage, condensation or the like. Interference is increased, whereby the Oscillator inadvertently caused to oscillate and trigger a switching process can be. If, on the other hand, the sensing electrode 15 is surrounded by a negative feedback potential shielding electrode, is used in the case of the aforementioned interfering influences the capacitance between the shielding electrode and the base electrode 15 is also increased, However, with a simultaneous increase in the negative feedback potential at the base of Ti, whereby the conditions for an oscillation release of the oscillator 1 in such a way be shifted so that the oscillator only goes beyond the target approach Approach of the body to be detected swings.

In the present case, the approach electrode 14 is designed in three parts and consists - compare also FIGS. 2 and 3 - of the ring-shaped sensing electrode 15, which encloses a central negative feedback electrode 16 and itself from a annular outer ground or earth electrode 17 is enclosed. The earth electrode 17 is grounded via the supply line 6, while the central negative feedback electrode 16 is connected to the emitter of T2 and is at negative feedback potential. The proximity electrode 14 thus represents two capacitors 15/16 and 15/17, the capacities of which are both increased in the event of dust, condensation or the like will.

The geometrical dimensions of the electrodes 15, 16 and 17 will be chosen such that to the same extent, in the energy through the capacitor 15/17 A flows, energy through the capacitor 15/16 from the negative feedback circuit to the sensing electrode 15 is subsequently delivered, so that the described interference is automatically compensated and the setpoint switching point of the proximity switch remains constant.

Fig. 4 shows a modified embodiment of the three-part proximity electrode, whose central negative feedback electrode 18 is approximately star-shaped and from a sensing electrode 19 provided with an adapted internal toothing and this as in the embodiment according to FIG. 2 again from a smooth-edged, annular Shielding or ground electrode 20 is enclosed. This is in adaptation to the circuit-based oscillator design compared to the capacitance of the capacitor 18/19 the capacitance of the capacitor 19/20 is increased and at the same time a more uniform compensation achieved with dust or condensation fluctuating over the entire electrode surface.

Fig. 5 shows a further embodiment in which the proximity electrode consists of a disc divided by eight diametrical sections, in which two diametrically opposing sectors 21, 22 to ground or earth (line 6), two vertically oriented diambtrally opposite sectors 23, 24 at the emitter of T2 and four, each between a ground (k) and an emitter (E§ sector lying sectors 25 to the base of T1 are connected, By such a multiplication of the three electrode parts becomes a particularly good compensation for fluctuating dust or condensation achieved. According to FIG. 6, the proximity electrode 26 can also consist of a grid-like pattern A large number of very small individual electrodes X, B, E exist, each with one Sense electrode area B in row and column direction between a negative feedback electrode area E and an earth resp.

Ground electrode area M lies.

7 and 8 show a proximity electrode 27 in which the ring-shaped sensing electrode 28 encloses a central ground or ground electrode 29 and is enclosed by an annular negative feedback electrode 30. The oscillator circuit is enclosed by an additional shielding sleeve 31. The electrode parts 28, 29, 30 sit here, as in all other embodiments, on a rearward one Plastic support plate 32 and are on their front side by a plastic cap 33 protected against the effects of corrosion.

Claims (6)

Claims Capacitive proximity switch with a multi-part Proximity electrode of which one part of the electrode is attached to the input as a sensing electrode an oscillating, negative feedback circuit and another electrode part are connected as a negative feedback electrode to the negative feedback potential, thereby characterized in that the proximity electrode (14) has a third, grounded electrode part as a ground electrode (17) and that the sensing electrode (15) geometrically between the negative feedback electrode (16) and the ground electrode (17). 2. Proximity switch according to claim 1, characterized in that the sensing electrode (15) is designed as a ring, which has a central electrode part and enclosed by an outer annular electrode part itself is0 3. Proximity switch according to claim 2, characterized in that either the central electrode part as a negative feedback electrode (16) and the outer electrode part as an earth electrode (17) or that the central electrode part as an earth electrode (29) and the outer electrode part is connected as a negative feedback electrode (30), 4th Proximity switch according to Claims 1 and 2, characterized in that the central negative feedback electrode (18) is star-shaped and within a sensing electrode (19) provided with an adapted internal toothing. 5. Proximity switch according to claim 1, characterized in that the three electrode parts each from a group of electrically interconnected There are individual electrodes, each individual sensing electrode (25) geometrically between a single negative feedback electrode (23, 24) and a single earth electrode (21, 22) lies. 6. Proximity switch according to claim 1, characterized in that the approach electrode (26) consists of a grid of individual electrodes (M, B, E), which are electrically interconnected to form a three-part electrode.