NL1040309C2 - TOILET SYSTEM. - Google Patents

Description

Title: Toilet system

The present invention relates in general to a toilet system. More specifically, the present invention relates to a way to save flushing water in a toilet.

Conventional toilet systems are equipped with a flushing system that flushes the toilet after use. Typically, a water reservoir is provided which is connected to the toilet bowl via a pouring pipe, wherein a valve is normally included in the pouring pipe. After using the toilet, the valve is opened so that water can flow from the reservoir into the toilet bowl, and from the toilet bowl the water flows via a drain pipe to the sewer, taking what the user has left behind in the toilet bowl. After a predetermined amount of water has flowed from the reservoir to the toilet bowl, the valve is closed and the water flow stops; the reservoir is refilled, and the system is ready for the next use. The system is provided with a control mechanism for adjusting the amount of water that is dispensed per rinsing, hereinafter referred to as rinsing volume.

The flush volume is an important parameter. If the flushing volume is too small, the toilet bowl will not be flushed sufficiently. If the flushing volume is unnecessarily large, an unnecessary amount of water is used, which is a cost item. Toilet water consumption is an important cost item, particularly in buildings with many users, such as office buildings, schools, airport terminals, etc. Furthermore, for environmental reasons, it is desirable to save on water use.

It is already known that the required flushing volume depends on the nature of what the user has deposited in the toilet bowl. If that is only liquid, a smaller flushing volume will suffice than if solid substances are involved. A common size is 6 liters for flushing out urine and 9 liters for flushing out stools. There are already systems where the flushing mechanism has two control buttons, one button for a small flushing volume and the other button for a large flushing volume, so that the user can adjust the water consumption according to the circumstances by choosing the right control button. However, the success of such a system depends on the discipline of the user; It has been found that many users use the large flush volume knob as standard, even if that is not necessary.

The object of the invention is to overcome these drawbacks. To this end, the present invention provides a toilet system where the flush volume is automatically adjusted to the need.

Figure 1 is a block diagram illustrating a toilet system 1 according to the present invention. The toilet system 1 comprises a toilet bowl 2 with a water reservoir 3 which is connected to the toilet bowl 2 via a pouring pipe 4, which pouring pipe is provided with a controllable valve 5. That valve 5 can be positioned at any location along the pouring pipe 4, but in In the example shown, the valve 5 is positioned at the entrance of the dump pipe 4 and integrated into the water reservoir 3. It is noted that the water reservoir 3 and the toilet bowl 2 can be integrated with each other, so that the dump pipe 4 can be quite short or even left out. to be.

The reference numeral 100 denotes a control system for the valve 5. The control system 100 comprises a central control member 110, which may be designed, for example, as a suitably programmed microprocessor, and which will be referred to as a controller in the following. When a flush is required, the controller 110 supplies the valve 5 with a control signal to open the valve and then close it again. The coil volume is set by the controller 110, for example, by setting the time during which the valve 5 is open.

The control system 100 is provided with detection means 140 for detecting when a rinse is required. Said detection means may comprise an interface to be operated by the user, for example a push button, but preferably said detection means 140 comprise an approach sensor 142 which can detect whether a user is moving away. Since ultrasonic proximity sensors are known per se, and since the present invention can be implemented with such a known ultrasonic proximity sensor, this sensor will not be described further.

The control system 100 is provided with detection means 120 for detecting how large flush volume is required. According to a core idea of the present invention, said detection means are adapted to measure the consumption of the toilet paper. This aspect of the present invention is based on the experience that toilet users generally use significantly more toilet paper after a "large message" than after a "small message".

There are various ways of measuring the amount of toilet paper that is used. A preferred embodiment because of its simplicity, and because it is easy to add to existing systems of the toilet paper roll type, includes a rotatable holder 121 for holding a paper roll, a feeler 122 for determining the current diameter of the paper roll, and a rotation counter 123 for counting the number of revolutions of the holder 121. The sensor 122 and the rotation counter 123 supply their output signals to the processor 110, which can determine the length of the used paper strip from these two data. calculation, as will be clear to an expert. Moreover, it is now possible in a simple manner for the processor 110 to detect whether the toilet roll is nearly empty, and to signal this to maintenance personnel, for example via wireless communication. For example, it is also possible to press a running wheel against the outer circumference of the toilet roll: the revolutions of that running wheel are then proportional to the length of the paper used.

It is in principle possible for the detection means 120 to communicate with a processor 110 via a wire. In general, in particular in pre-existing situations, it is, however, not possible, or not simply, to arrange such wiring invisibly. In a preferred embodiment, this problem is solved by the invention in that the detection means 120 comprise a transmitter 124 for wireless communication with the processor 110, for example via WiFi or zigbee or the like.

A practical aspect is then the power supply for the transmitter 124. In general, in particular in pre-existing situations, it is not, or not simply, possible to obtain power supply for the transmitter 124 from the mains. A power source 130 for the transmitter 124 therefore comprises a battery or battery or capacitor 131. To minimize energy consumption, the transmitter 124 is normally off, and only becomes a signal from the rotation counter 123. But also with minimum energy consumption the stored amount will energy are exhausted at some point. To prevent this, or at least to postpone it for as long as possible, the power supply 130 is provided with a generator 132, for example a dynamo, which is driven by the rotating holder 121.

The rinsing volume, which is proportional to the rinsing time or the time during which the valve 5 is kept open, is set by the controller 110 on the basis of the measured paper consumption. In a possible embodiment, the controller has two operating modes, namely "normal" and "few", which, for example, correspond to 9 liters and 6 liters respectively. The controller 110 compares the measured paper length with a preset threshold value; if the measured paper length exceeds that preset threshold value, the controller chooses "normal" coil volume, and if the measured paper length remains below that preset threshold value, the controller chooses "little" coil volume.

In another possible embodiment, the controller 110 selects the rinsing time in proportion to the measured paper length.

Claims (10)

A method for controlling the flushing volume of a flushing toilet, wherein the amount of toilet paper consumed by the user of that toilet is measured, and wherein the flushing volume is adjusted in dependence on the measured amount of toilet paper consumed. The method of claim 1, wherein the flush volume is adjusted in proportion to the measured amount of toilet paper that has been consumed. A method according to claim 1, wherein a choice is made between a larger and a smaller flush volume depending on whether the amount of toilet paper used is larger or smaller than a predetermined threshold value. A control system (100) for controlling the flush volume of a flush toilet, comprising: a central controller (110) for opening and closing a valve (5) in the flush mechanism of the flush toilet; trigger means (140) that provide a control signal to the controller (110) for starting a rinse; detection means (120) adapted to measure toilet paper consumption; wherein the controller (110) is programmed to open the valve (5) upon receipt of the trigger signal from the trigger means (140), and to close the valve (5) again after a rinsing time that depends on the detection means ( 120) measured paper consumption. The control system of claim 4, wherein the controller (110) compares the measured paper length with a preset threshold value; wherein the controller (110) sets the rinsing time to a first predetermined value if the measured paper length exceeds that preset threshold value, and sets the rinsing time to a second predetermined value less than the first rinsing time value if the measured paper length remains below that preset threshold value. The control system of claim 4, wherein the controller (110) sets the rinsing time in proportion to the measured paper length. A control system according to any of claims 4-6, wherein the detection means (120) comprise a sensor (122) for determining the actual diameter of the paper roll, and a rotation counter (123) for counting the number of revolutions of the holder (121). A control system according to any of claims 4-7, further comprising a transmitter (124) for wireless communication of the measurement signals to the controller (110). The control system of claim 8, further comprising a rotatable toilet roll holder (121) coupled to a generator (132) for generating power energy for the transmitter (124). A toilet system (1), comprising: a toilet bowl (2) with a water reservoir (3); a controllable valve (5) between the water reservoir (3) and the toilet bowl (2); a control system (100) according to any of claims 4-7, wherein the control member (110) is connected for controlling the valve (5).