DE9210464U1 - Energy-saving control device for toilet flushes - Google Patents

Description

Energy-saving control device for toilet flushes

The invention relates to an energy-saving control device for toilet flushes. In particular, it addresses those toilet flushes that have both a passive and an active sensor. The passive sensor is designed so that it is in a standby mode and then, when a toilet user comes, detects the presence of the user and then activates the active sensor to switch on the function of a pump motor 50, through which a predetermined amount of water is released to clean the toilet.

State of the art:

A toilet flush control device as currently used typically uses an active infrared sensor, which has an infrared transmitter and an infrared receiver, to transmit infrared radiation to detect whether a toilet user is standing in front of the toilet. If a user is using the toilet, the infrared radiation emitted by the active sensor is reflected by the toilet user's body and received by the infrared receiver 33, whereby the receiver controls a microcomputer 10 to activate the toilet flush. The active sensor must continuously emit infrared radiation, which requires a relatively high power consumption and thus causes a relatively high power consumption. For example, to detect a 30 cm distance from an infrared transmitter 32, a pulse current of up to 1 A is required. The conventional toilet flush control device typically uses an AC power supply unit to provide electrical power because it has such a high power consumption. The

Wiring between the AC power supply unit and the control circuit is cumbersome.

The invention is based on the object of providing a toilet flush control device that consumes less energy than is usual in the prior art and therefore requires a plurality of batteries for power supply.

This invention is solved by the features of the main claim, advantageous further developments emerge from the subclaims. The present invention therefore relates to a toilet flush control device with a passive pyroelectric detector 20 for detecting a toilet user at a relatively large distance from the toilet and for triggering an active infrared detector 30 for detecting the user at a relatively short distance and for subsequently triggering a pump motor 50 in order to deliver a predetermined amount of water for cleaning the toilet.

It is therefore also an object of the invention to provide an energy-saving toilet flush control device, since the passive pyroelectric detector device 20 consumes very little energy.

Another object of the present invention is to design a toilet flush control device so that it enables detection of a toilet user over a longer distance and detection of a toilet user over a shorter distance.

The invention/innovation is explained in more detail using an exemplary embodiment in the figures of the drawings. These show:

Fig. 1 is a block diagram of a toilet flush control device related to the present invention;

Fig. 2 is a block diagram of the device according to Fig. 1;

Fig. 3 is a simplified schematic representation of the mechanical structure of the toilet flush control device according to the present invention.

First, reference is made to Fig. 1.

According to this, an energy-saving control device for toilet flushes has the following elements:

a DC voltage supply unit 60,

a passive pyroelectric detector device 20,

a microcomputer 10,

an active infrared detector device 30,

a switching device 40 and

a pump motor 50.

The DC power supply unit 60 has a 5 V output and a 9 V output. It is used to provide the required voltages for the entire control device. The pyroelectric detector device 20 is used to detect the temperature of a toilet user in the vicinity of the toilet and, as a result, to generate a first switching signal which is fed to the microcomputer 10. The microcomputer 10 is connected to the pyroelectric detector device 20.

roelectric detector means 20 to respond to the first switching signal and generate a second switching signal. The active infrared detector circuit 30 is also connected to the microcomputer 10 to respond to the second switching signal and thereby generate a third switching signal which is fed back to the microcomputer 10 to start a program which counts the time until the user leaves the toilet, turns off the third switching signal and stops the counting of the timer and to cause the sensing microcomputer 10 to emit a fourth switching signal. The fourth switching signal can have either a relatively long duty cycle or a relatively short duty cycle depending on whether or not the count result accumulated in the counter is greater than a reference value. If the count result is greater than the reference value, then the fourth switching signal will have a relatively long duty cycle, otherwise the duty cycle is comparatively short.

The switching device 40 has an activation terminal 41 which is connected to the microcomputer 10. The activation terminal 41 reacts to the fourth switching signal and consequently closes a switching contact and establishes a conductive connection between a ground terminal 43 and a terminal 42 connected to the pump motor 50. The pump motor 50 has a positive terminal which is connected to the 9 V terminal of the DC voltage supply unit 60. Its negative terminal is connected to the terminal 42 of the switching device 40. When the switch in the switching device 40 is closed and thus a connection exists between the terminals 42 and 43, the pump motor 50 is operated.

Reference is now made to Fig. 2, where the control device is shown in more detail.

The microcomputer 10 comprises the following components:

a timer which is program-controlled and operated as a counter when the microcomputer 10 is controlled by the first switching signal;

a first input terminal RB7 to respond to the first switching signal and then start a program that causes the counter to count;

a reset terminal MCLR that responds to a "low" input signal to clear the counter;

a first output terminal RB4 for outputting the second switching signal when the microcomputer 10 is controlled ;

a second input terminal RBO to receive the third switching signal and to trigger the timer to start the counter;

a second output terminal RB6 to respond to the counting result of the timer and to output the fourth switching signal with a longer duty cycle or a shorter duty cycle as already mentioned above.

The pyroelectric detector device 20 comprises a pyroelectric sensor 21, a first transistor 25, a converter 22, an LED (light emitting diode) 26, a second transistor 23 and a third transistor 24. The pyroelectric sensor 21 is connected to the first trigger terminal of the first transistor 25. The first transistor 25 has an output terminal (its collector) which is connected to the converter 22. The converter 22 in turn has an output terminal which is connected to the cathode of the LED 26 and is also connected to a trigger terminal of the second transistor 23. The second transistor has a first output terminal (emitter) which is connected to

the first input terminal RB7 of the microcomputer 10 and a second output terminal (its collector) connected to the base of the third transistor 24. The third transistor 24 in turn has an output terminal (its collector) connected to the reset terminal MCLR of the microcomputer 10.

When a toilet user now approaches the toilet, the pyroelectric sensor 21 is turned on, causing the first transistor 25 to turn on and send a pulse to the converter 22, which in turn outputs a "low" pulse to turn on the LED 26 and to turn on the second transistor 23 and the third transistor 24. When the second transistor 23 is turned on, the first switching signal is generated and sent to the first input terminal RB7 of the microcomputer 10. When the third transistor 24 is turned on, the "low" input signal is generated and sent to the reset terminal MCLR of the microcomputer 10 to reset the microcomputer 10.

The active infrared detector device 30 comprises a fourth transistor 31, an infrared transmitter 32, an infrared receiver 33, a first filter 34, a second filter 35, a third filter 36 and a plurality of reference resistors 39, a multiple switch 38 and an amplifier 37.

The fourth transistor 31 has a switching terminal (its base) connected to the first output terminal RB4 of the microcomputer 10 and an output terminal connected to the infrared transmitter 32, which is further connected to the infrared receiver 33 by reflected infrared radiation from a toilet user in front of the toilet.

The infrared receiver 33 is connected between the inverter input and the non-inverting input of the first filter 34. The first filter 34 is connected in a cascade-like manner with the second filter 35, which in turn is connected in a cascade-like manner

is connected to the third filter 36. The plurality of resistors 39 cooperate with the multiple switch 38 to adjust the gain of the amplifier 37. The output of the amplifier 37 is connected to the second input terminal RBO of the microcomputer 10. When the second switching signal is output from the first output terminal RB4 of the microcomputer 10, the fourth transistor 31 is turned on, activating the infrared transmitter 32 to send an infrared signal towards the user's body, which is then reflected therefrom and received by the infrared receiver 33, passed through the filters 34, 35 and 36 and fed to the amplifier 37, generating the third switching signal and feeding it to the second input terminal RBO of the microcomputer 10, starting the timer and running until the third switching signal disappears. The third switching signal disappears when the user leaves the toilet and the infrared receiver 33 can therefore no longer receive infrared radiation.

Also, when the user leaves the relatively long detection path of the pyroelectric detector device 20 and the pyroelectric sensor 21 turns off, the transistor 25 is turned off and consequently also the second transistor 23 and the third transistor 24. Since the second transistor 23 has turned off, the first output terminal RB4 of the microcomputer 10 outputs a "low" signal and consequently turns off the fourth transistor 31, which in turn turns off the transistor 32. As a result of these operations, the control device returns to a standby mode in which it can detect another toilet user.

The switching device 40 comprises an NPN transistor, the base of which is connected to the second output terminal of the RB6 of the microcomputer 10, the emitter of which is connected to ground and the collector of which is connected to the negative terminal of the pump motor 50.

Reference is now made to Fig.3 which shows a simplified toilet flush mechanism. A tank 901 is filled with water. Outside the tank 901 there is a handle 92 which is connected to a pivot 93. The pivot 93 is located on the edge of the tank 901 and is connected to an arm 94 inside the tank 901. One end of the arm 94 engages the pivot 93, the other end is connected to a valve 95 via a stainless steel wire 96. Thus, when a user presses the handle 92, the valve 95 is raised as shown in phantom, thereby discharging the water through the valve 95. The foregoing only relates to the manual operation of the toilet flush mechanism, which is known per se.

According to the present invention, the toilet flush control device is housed in a first housing 7 and has an electrical connection to a pump motor 50 (no longer shown in Fig. 3) which mechanically interacts with the center of a disk 3, whereby the disk 3 rotates synchronously with the pump motor 50. The pump motor 50 is housed in a watertight manner within a second housing 1. A frame 5 is provided to support the second housing 7 and the pump motor 50. The disk 3 is provided with a protruding pin 4 in the area of its edge, which acts on the arm 94. When the control device detects the presence of a toilet user, the disk 3 rotates and causes the arm 94 to raise the valve 95, as shown in dashed lines, thereby cleaning the toilet.

The dashed position of the arm 94 shown in Fig. 3 is set when the user remains in front of the toilet for a relatively long period of time. If the user uses the toilet for a short time, the protruding pin 4 assumes a position which corresponds to the three o'clock position (with respect to a clock face) and thereby causes a reduced water outflow through the valve 95.

The toilet flush mechanism as described above is merely a simplified device which can cooperate with the controller and is not self-contained. The control device described above is, however, not limited to any particular toilet flush mechanism.

Claims (6)

PROTECTION CLAIMS 1. Energy-saving control device for toilet flushes with - a DC power supply unit (60) for providing the energy for the entire control device, in particular with a 5 V output and a 9 V output; a pyroelectric detector device (20) for detecting the temperature of an approaching toilet user and for generating a first switching signal accordingly; a microcomputer (10) connected to said pyroelectric detector device (20) for responding to the first switching signal and generating a second switching signal; an active infrared detector device (30) connected to said microcomputer (10) to respond to the second switching signal and to be activated thereby to generate a third switching signal which is fed back to said microcomputer (10) to start a program which counts the time until the user leaves the toilet, which switches off said third switching signal, stops the counting of the timer and causes said microcomputer (10) to emit a fourth switching signal; a switching device (40) with an activation terminal (41) connected to said microcomputer (10) to respond to the fourth switching signal to react and is activated so that it conducts to ground; a pump motor (50) having a positive terminal connected to said 9 V terminal of the power supply (60) and having a negative terminal connected to the switching device (40) such that when the switching device (40) is switched on, the pump motor (50) operates as long as the switching device (40) is switched on. 2. Energy-saving control device for toilet flushes according to claim 1, characterized, that the microcomputer (10) has the following features: a timer device which is programmably controlled to count the time when the microcomputer (10) is controlled; a first input terminal (RB7) which responds to the first switching signal and starts a program which causes the timer to count; a reset terminal (MCLR) to respond to a "low" input signal and to reset the timer; a first output terminal (RB4) for outputting the second switching signal when the microcomputer (10) is controlled; a second input terminal (RBO) for receiving the third switching signal and for triggering the Switching signal that causes the timer to start the counter; a second output terminal (RB6) which responds to the counting result of the timer and outputs a fourth output signal with either a long duty cycle or a short duty cycle, which is carried out by comparing the counting result with a predetermined reference value such that if the counting result is greater than the reference value, the fourth switching signal lasts long, otherwise the short duty cycle is switched on. 3. Energy-saving control device for toilet flushing according to claim 1 or 2, characterized, that the pyroelectric detector device (20) has a pyroelectric sensor (21) which is connected to the first switching terminal of a first transistor (25), the terminal of which is connected to a converter (22) which has an output terminal (LED) (26) which is connected to the cathode of a light-emitting diode (26) and furthermore a switching terminal of a second transistor (23) is provided which has a first output terminal (RB4) which is connected to the first input terminal (RB7) of said microcomputer (10) and whose second output terminal (RB6) is connected to the switching terminal of a third transistor (24) which has an output terminal which is connected to the reset terminal (MCLR) of said microcomputer (10) such that when a user approaches the toilet, the pyroelectric sensor (21) is switched on, a pulse which is fed to the converter (22) which then emits a "low" switching pulse to switch on the LED (26) and to switch on the second transistor (23) and the third transistor (24), wherein the second transistor (23) in its switched-on state generates a switching signal which is passed on to the first output terminal (RB4), and the third transistor (24) in its switched-on state generates a "low" input pulse to reset the microcomputer (10). 4. Energy-saving control device for toilet flushes according to one of the preceding claims, characterized, that the infrared detector device (30) is provided with a fourth transistor (31) having a switching connection which is connected to the first output connection (RB4) of said microcomputer (10), further having an output connection which is connected to the infrared transmitter (32) which interacts with an infrared receiver (33) via infrared radiation reflected from the user, wherein said infrared receiver (33) is connected to three cascade-connected filter devices (34, 35 and 36) which are connected to an amplifier (37) and via a second input connection (RBO) of said microcomputer (10), whereby when the second switching signal is emitted by the first output signal (RB4) of the microcomputer (10) and the fourth transistor (31) switches through, the infrared transmitter (32) switches on to send infrared radiation towards the body of the user, which is reflected therefrom and received by the infrared receiver (33) is received, whereby the third switching signal is generated, passed through the filters (34, 35 and 36) and the amplifier (37) and applied to the second input terminal (RBO) of the microcomputer 10 to switch on the timer until the said third switching signal is switched off. 5. Energy-saving control device for a toilet flush according to one of the preceding claims, characterized, that the switching device (40) is designed as an NPN transistor, the base of which is connected to the second output terminal of said microcomputer (10), the emitter of which is connected to ground and the collector of which is connected to the negative switching terminal of the pump motor (50). 6. Energy-saving control device for toilet flushes according to one of the preceding claims, characterized, that the infrared detector device (30) has a multiple switch (38) which is connected to a plurality of reference resistors (39) in order to enable a gain control of the amplifier (37).