NL7906299A - PROXIMITY SWITCH, ESPECIALLY FOR SANITARY PURPOSES. - Google Patents

Description

- 1 -

E 5617-1 P & C

*

Proximity switch, especially for sanitary purposes.

The invention relates to a proximity switch, in particular for sanitary purposes / with a transmitter emitting a modulated radiation, a receiver which converts the received modulated radiation into a modulated electric signal, an amplifier and a switching stage for the modulated electric signal, whereby the switching stage • controls a consumer, for example a magnetic valve, after a switching threshold has been exceeded.

Such devices are used in two versions for sanitary purposes.

According to one embodiment, the receiver responds to subsequent electronics, respectively, to static reflections on the monitored object. However, such embodiments have the drawback that, if the switching threshold is inaccurately adjusted, the continuously occurring reflection, for example at the bottom of a washbasin, also leads to energization of the consumer, ie the magnetic valve. Conditions may then arise in which the water supply can no longer be switched off at all.

In the second embodiment, the electronics respond only to signals indicating movement of the monitored object. This ensures that continuously present objects, such as for instance the bottom of the washbasin, cannot lead to false alarms. On the other hand, such embodiments have the drawback that the user must have insight into his operation. For example, if the user is not familiar with the mode of operation and omits his movements under the taps, the supply of water will be absent.

The object of the invention is to provide a device of the type intended in which, on the one hand, there is no danger of a false alarm due to continuously present objects and, on the other hand, no special requirements are imposed on the user's understanding of the operation of the device.

To this end, the invention is characterized by an amplifier with a variable sensitivity, wherein a second switching path is provided which increases the sensitivity of the amplifier when movements occur in the range monitored by the transmitter and the receiver.

Preferably, the amplifier is a voltage controlled amplifier. In that case, the second switching path includes a demodulator, the input of which is connected to the output of the receiver and the output of which is connected directly or indirectly via an AC amplifier and a rectifier. 790 6 2 99 '{- 2 - with the control terminal of the voltage controlled amplifier. A passive low-pass filter is preferably included between the output of the demodulator and the input of the AC amplifier to further suppress disturbing signals and residual demodulation frequencies.

For further filtering for the same reasons, an active low-pass filter can be inserted between the output of the AC amplifier and the input of the rectifier.

To avoid oscillations and other instabilities, a time chain can be included between the output of the rectifier and the control input of the voltage controlled amplifier.

The adaptation of the signal supplied by the second switching path to the voltage-controlled amplifier preferably takes place by means of a DC-adjustment amplifier which is also included between the output of the rectifier and the input of the voltage-controlled amplifier.

In the embodiment according to the invention, the switching threshold is automatically placed closer to the bottom of the washbasin when movements are observed, such as those which occur, for example, when washing hands. If these movements are not forthcoming, the switching threshold is brought closer to the receiver for safety reasons, but the device can nevertheless be actuated, after crossing the switching threshold, like a conventional device.

The invention is explained in more detail below with reference to the drawing, which shows a block dimension of a device according to the invention.

As appears from the drawing, the device essentially consists of two branches. The one branch, which comprises components 3, R, R, 4, 5, 6, 7 and 8, a 6, corresponds to a known embodiment, apart from a further description to be described.

This first branch starts at the receiver 3, which is connected in a manner not shown 30 to the power supply device 1 and receives radiation from the transmitter 2.

Infrared light is particularly suitable as radiation, but other electromagnetic radiation or acoustic radiation can also be used.

The transmitter 2, which is also fed by the power supply part 1, radiates in an area to be monitored, for instance in the outlet area of a sanitary tap. When an object, for example a hand, is brought into this area, light from the transmitter is reflected to the receiver 3, causing a signal to appear in the line 9. This signal reflects, on the one hand, the modulation communicated to the radiation by the transmitter 2.

On the other hand, the strength of the signal depends largely on the distance 40 between the object and the receiver.

790 62 99 - 3 -

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The modulated output signal of the receiver 3 is fed via the resistors and existing voltage parts to an amplifier 4, the special embodiment of which will be explained later.

The output signal of the amplifier 4 is rectified and the amplifier 5 is supplied to the time chain 6 and from there to the switching stage 7 to avoid instabilities. The switching stage 7 switches on one or more magnetic valves as at the input of the amplifier. 4 a sufficiently high voltage is present.

In the case of washbasin fittings, this voltage must be set with the resistor Rl designed as a potentiometer so that the radiation reflected by the bottom of the washbasin which reaches the receiver 3 does not activate the magnetic valve. Only an object closer to the receiver establishes water supply.

For safety reasons, this response threshold should be as far as possible from the bottom of the washbasin and as close as possible to the receiver. However, this has the drawback that during washing movements by hand, the sensitivity range can be unintentionally left, whereby the supply of water is terminated at an undesired time.

In order to prevent this, a second switching branch is present. It ends at the already known amplifier 4, which here is designed as a voltage-dependent amplifier. By this is meant that the amplification factor of the amplifier can be influenced with an external control voltage.

The rationale of the second switching branch is as follows: as long as an object moves in the monitored area, the sensitivity of the amplifier must be increased and thereby the response threshold must be placed at a great distance from the receiver. Only when the movements (of hand washing) have ended, the amplifier 4 returns to its normal amplification factor, whereby the response threshold again comes closer to the receiver 30.

For that purpose, the signal applied by the receiver 3 to the line 9 is also supplied to the demodulator 10 which is the input circuit of the second switching branch. At the output of demodulator 10, a signal occurs which is free from the carrier frequency and consists of a DC voltage signal if no movements take place in the monitored area.

This DC voltage signal is not further processed in the second switching branch.

If movements occur in the monitored area (by hand washing), a demodulated signal having a variable amplitude, i.e. an AC voltage signal, occurs at the output of demodulator 10. This 790 62 99 - 4 - or a.c. voltage signal is supplied through an RC-pass low-pass filter to an amplifier 11 and from there to a further low-pass filter 12, which is preferably designed as an active circuit. The cut-off frequency of this low-pass filter is approximately 10 Hz.

The output signal of the low-pass filter 12 is rectified in the rectifier 13 and is supplied via the line 14 to the control input of the amplifier 4. In order to adapt the two switching branches to each other, an amplifier 15 may be included in the line 14. Furthermore, it may be desirable to include a time chain 16 to avoid instabilities in line 14.

The described device works as follows:

It is first assumed that there is no object in the monitored area. The entire radiation received by the receiver 3 then comes from the reflection at the bottom of the washbasin.

The output of demodulator 10 is constant, as a result of which amplifier 4 is not controlled by a control voltage and has a relatively small gain factor. With the aid of the resistor, the response threshold of the switching stage 2 is placed at a great distance from the bottom of the sink and in the vicinity of the receiver. As a result, spontaneous operation of the taps is certainly prevented. An object placed inadvertently on the bottom of the washbasin cannot cause a water supply.

If an object, in particular hands that are being washed, are now brought into the monitored area and carry out movements there as are customary in washing, an AC voltage signal is produced at the output of demodulator 10. This is processed by the circuits 11, 12, 13 and possibly 14 and 15 into a control voltage for the voltage-controlled amplifier 4. This control voltage results in the amplifier 4 becoming more sensitive. Thereby the response threshold for the switching stage 2 is placed at a greater distance from the receiver and closer to the bottom of the sink.

There is therefore no danger of the waxing hands unintentionally leaving the area of safety of the device, whereby the water supply would be stopped at an undesired time.

790 62 99

Claims (7)

1. Proximity switch, in particular for sanitary purposes, with a transmitter emitting a modulated radiation, a receiver converting the received modulated radiation into a modulated electrical signal, an amplifier and a switching stage for the modulated electrical signal, the switching stage after exceeding a switching threshold controls a consumer, for example a magnetic valve, characterized by an amplifier (4) with variable sensitivity and a second switching branch (10 to 15) which increases the sensitivity of the amplifier (4) as in the area movements monitored by transmitter (2) and receiver (3) occur. Device according to claim 1, characterized in that the amplifier (4) is a voltage-controlled amplifier. Device according to claim 2, characterized in that the second switching branch comprises a demodulator (10), the input of which is connected to the output of the receiver (3) and of which the output signal is via an AC amplifier (11) and. a rectifier (13) is supplied directly or indirectly to the control terminal of the voltage controlled amplifier (4). Device according to claim 3, characterized in that a passive low-pass filter is included between the output of the demodulator (10) and the input of the AC amplifier (11). Device according to claim 3 or 4, characterized in that an active low-pass filter (12) is included between the output of the AC amplifier (11) and the input of the rectifier (13). Device according to one or more of claims 3 to 5, characterized in that a time circuit (16) is included between the output of the rectifier (13) and the control input of the voltage-controlled amplifier (4). Device according to one or more of claims 3 to 6, characterized in that a DC adjustment amplifier (15) is applied between the outputs of the rectifier (13) and the input of the voltage controlled amplifier. is included. \ \ t t 790 62 99