DE19639285C1 - Optical sensor built-in circuit operating method for non=contact controlled toilet flush - Google Patents

Abstract

The method involves using a circuit device (1) connected to at least one optical sensor (2) for a non-contact controlled toilet flush with an electrically controllable valve (5) for switching water on and off. The sensor has a light transmitter (6) and at least one light detector (7). The transmitter is excited time-wise to generate light pulses. The pulse time of the light pulse is increases to a fixed value when the sensor measures no use of the flush during a predetermined time interval. The pulse time of the pulse is reduced back to its start value as soon as the sensor detects use of the flush.

Description

The invention relates to a method for operating a circuitry connected to at least one optical sensor direction for a non-contact controllable sanitary fitting with those specified in the preambles of claims 1 and 3 Characteristics.

Such a circuit device for a contactless controllable sanitary fitting is for example from DE 40 19 927 A1 known. This circuit device includes one optical sensor downstream amplifier and a Transmission generator and an evaluation circuit for the extraction of Control signals for a water on and off Magnetic valve. The light transmitter of the optical Sen sors by the transmission generator in cycles to generate Light pulses stimulated.  

A disadvantage of this known circuit device among other things, that they have a relatively high energy consumption has what is particularly in battery-powered Circuit devices makes disturbing noticeable.

The invention has for its object a method for Reduction of the energy consumption of a circuit device device for a non-contact controllable sanitary fitting give.

This object is achieved by the features of characterizing parts of claims 1 or 3 solved. Further, particularly advantageous embodiments of the invention are open the subclaims.

The invention is essentially based on the idea that Power consumption of the circuit device for a long time Not using the sanitary fitting (e.g. while on vacation time or during the night).

This can preferably be done in that the cycle time the light pulse is increased to a predetermined value, if the sensor has not been used for a specified period Use of the tap measures. As soon as the sensor is one If the valve is used, the cycle time of the Light pulses reduced back to the initial value.

For fittings that are primarily a vacation or illness Take into account the contingent absence of the respective user , it is recommended to increase the cycle time if the Sensor within a period of 3 to 5 days none Use of the tap measures.  

For fittings that should take into account above all that It is uncommon for the fitting to be used in the dark proved to be expedient, the cycle time of the light pulses increase the sensor to a predetermined value when the Brightness in the area of the fitting a predetermined threshold worth less. As soon as the brightness reaches the preset Threshold exceeds and / or the sensor is in use the valve is detected, the cycle time of the circuit pre direction again reduced to the initial value.

In an advantageous embodiment of the invention the brightness in the area of the fitting from the radiation receiver of the sensor measured.

Further advantages of the invention result from the following exemplary embodiments explained with reference to figures. It shows gene:

Fig. 1 shows the block diagram of a circuit device for performing the method according to the invention and

FIGS. 2a-2c are diagrams for explaining the invention.

In Fig. 1, 1 denotes a circuit device which is connected to an optical sensor 2 and via an electrical line 4 with a controllable solenoid valve 5 of a non-contact controlled sanitary fitting.

The optical sensor 2 contains a light transmitter 6 (e.g. an LED) and a radiation receiver 7 (e.g. a photodiode). The light transmitter 6 is connected to a transmission generator 8 and this is connected to a microcontroller 10 via an electrical line 9 . The radiation receiver 7 is followed by an amplifier 11 , the output of which is connected to the microcontroller 10 via a line 12 .

In addition, the microcontroller 10 is connected via a Schaltver stronger 13 to the line 4 for controlling the valve 5 .

In the following, the mode of operation of the circuit device and of the method according to the invention will be discussed in more detail using the diagrams shown in FIGS. 2a-2c:

In this case, Fig 2a illustrates. The trigger signals generated by the microcontroller 10 15, which via the line 9 to the transmitting genes rator reach. 8 This generates corresponding electrical signals which cause the light transmitter 6 to emit pulsed light signals.

FIG. 2b shows the time course of the received signals on line 12 ( FIG. 1). The measured values denoted by 16 are essentially due to the scattered light entering the radiation receiver. These signals are far below a predetermined threshold value 17 and are therefore not used by the microcontroller 10 to control the valve 5 .

If a user approaches the fitting and holds his hands 18 ( FIG. 1) in the area monitored by the sensor 2 , the received signal measured by the radiation receiver 7 increases due to the reflected radiation of the light. At the output of the amplifier 11 there is a measured value 19 ( FIG. 2b) which exceeds the threshold value 17 .

If the microcontroller 10 does not measure use of the fitting during a predetermined period T2, ie no measured values 19 exceed the threshold value 17 , the cycle time of the trigger signals 15 is increased from an initial value To to a predetermined value T1. The cycle time of the light pulses generated by the light transmitter increases accordingly. As soon as the sensor 2 or the microcontroller 10 detects a renewed use of the fitting, the cycle time is reduced again to the initial value To. In addition, a corresponding, the valve opening pulse 20 ( Fig. 2c) is fed to the solenoid valve 5 via line 4 .

Another possibility to control the cycle time of the trigger signals 15 and thus also the light pulses is to carry out a brightness measurement with the radiation receiver 7 at predetermined times. If the brightness in the area of the fitting falls below a predetermined threshold value (for example, there is no light in the washroom, etc.), the cycle time of the trigger signals 15 is increased again to a predetermined value T1. On the other hand, as soon as the brightness exceeds the predetermined threshold value (e.g. light has been switched on) and / or the sensor ( 2 ) detects use of the fitting, the cycle time is reduced again to the initial value To.

The two methods described above can can of course also be combined with each other.

Reference list

1 switching device
2 optical sensor
4 electrical wires
5 solenoid valve
6 light transmitters
7 radiation receivers
8 transmission generator
9 electrical line
10 microcontrollers, evaluation circuit
11 amplifiers
12 line
13 switching amplifiers
15 trigger signal
16 measured value
17 threshold
18 hand
19 measured value
20 pulse

Claims (5)

1. A method for operating a circuit device ( 1 ) connected to at least one optical sensor ( 2 ) for a contactlessly controllable sanitary fitting with an electrically controllable valve ( 5 ) for switching the water on and off, the sensor ( 2 ) being a light transmitter ( 6 ) and at least one radiation receiver ( 7 ) and wherein the light transmitter ( 6 ) is cyclically excited to generate light pulses, characterized in that the cycle time of the light pulses is increased to a predetermined value if the sensor ( 2 ) during a predetermined Period (T2) does not measure use of the fitting, and that the cycle time of the light pulses is reduced to their initial value (To) as soon as the sensor ( 2 ) detects use of the fitting. 2. The method according to claim 1, characterized in that the cycle time is increased if the sensor ( 2 ) does not measure use of the valve within a period of 3 to 5 days. 3. Method for operating a circuit device ( 1 ) connected to at least one optical sensor ( 2 ) for a contactlessly controllable sanitary fitting with an electrically controllable valve ( 5 ) for switching the water on and off, the sensor ( 2 ) being a light transmitter ( 6 ) and at least one radiation receiver ( 7 ) and wherein the light transmitter ( 6 ) is cyclically excited to generate light pulses, characterized in that the cycle time of the light pulses is increased to a predetermined value (T1) when the brightness in the area of the fitting falls below a predetermined threshold value, and that the cycle time of the light pulses is reduced to their initial value (To) as soon as the brightness exceeds the predetermined threshold value and / or the sensor ( 2 ) detects use of the fitting. 4. The method according to claim 3, characterized in that the brightness in the area of the fitting from the radiation receiver ( 7 ) of the sensor ( 2 ) is measured. 5. The method according to any one of claims 1 to 4, characterized in that the measured values ( 16 , 19 ) determined by the radiation receiver ( 7 ) of the sensor ( 2 ) are given, if appropriate after amplification and digitization, to a microcontroller ( 10 ) which evaluates these signals and generates trigger signals ( 15 ) for controlling a transmission generator ( 8 ) connected to the light transmitter ( 6 ).