URINAL SYSTEM, WATER CONSUMER SYSTEM HAVING A URINAL SYSTEM, AND METHOD FOR OPERATING A URINAL SYSTEM

Abstract

The invention relates to a urinal system (10), a water consumer system having such a urinal system, and a method for operating a urinal system. A urinal controller (8) of the urinal system has a data processing system (9) and/or is connected to a data processing system (9) which is designed to retrieve and/or receive and computationally evaluate data captured by at least one HF motion sensor (5) provided on a urinal bowl (1) and/or a urinal outlet (4) of the urinal system, and to recognize one of the following malfunctions based on the evaluated data and/or to initiate an action in order to avoid one of the fol-lowing malfunctions: that the urinal outlet is obstructed, and/or that there is a pressure fluctuation in a wastewater system connected to the urinal system, and/or that a fluid inlet (2) and/or an inlet valve (3) of the urinal system is malfunctioning, and/or that there is a failure of the HF motion sensor, and/or to recognize a predefined urinal usage situation and/or frequency of use on the basis of the evaluated data and, based on this, to adapt an opening time and/or an open-ing position and/or an opening frequency of the inlet valve to in a subsequent urinal flushing process.

Claims

1. Urinal system comprising a urinal bowl, a fluid inlet with an inlet valve, a urinal outlet, at least one HF motion sensor for detecting fluid motion provided on the urinal bowl and/or at the urinal outlet and a urinal controller coupled with the at least one HF motion sensor and the inlet valve, wherein the urinal controller comprises a data processing system and/or is connected with a data processing system, which is arranged to at least retrieve and/or receive data captured by the at least one HF motion sensor, to evaluate the data arithmetically and, based on the evaluated data, to detect at least one of the following malfunctions and/or initiate an action, in order to prevent at least one of the following malfunctions: that the urinal outlet is obstructed, and/or that there is a pressure fluctuation in a wastewater system connected to the urinal system, and/or that the fluid inlet and/or the inlet valve is malfunctioning, and/or that there is a malfunction of at least one of the at least one HF motion sensor, and/or to recognise a predefined urinal usage situation and/or frequency of use based on the evaluated data, and to adjust an opening time and/or an opening position and/or an opening frequency of the inlet valve based on the evaluated data during at least one subsequent urinal flushing process.

2. The urinal system of claim 1, wherein the urinal system further comprises at least one pressure sensor and/or at least one flow sensor in the fluid inlet and/or is coupled with at least one pressure sensor and/or at least one flow sensor in the fluid inlet via a meshed and/or a wireless local data transmission network.

3. Urinal system comprising a urinal bowl, a fluid inlet with an inlet valve, a urinal outlet, at least one HF motion sensor for detecting fluid motion provided on the urinal bowl and/or at the urinal outlet and a urinal controller coupled with the at least one HF motion sensor and the inlet valve, wherein the urinal system further comprises at least one pressure sensor and/or at least one flow sensor in the fluid inlet and/or is coupled with at least one pressure sensor and/or at least one flow sensor in the fluid inlet via a meshed data transmission network and the urinal controller comprises a data processing system and/or is connected to a data processing system, which is arranged to at least retrieve and/or receive data captured by the at least one HF motion sensor and/or the at least one pressure sensor and/or the at least one flow sensor, to evaluate the data arithmetically and, based on the evaluated data, to identify at least one of the following malfunctions and/or trigger at least one action, in order to prevent at least one of the following malfunctions: that the urinal outlet is obstructed, and/or that there is a pressure fluctuation in a wastewater system connected to the urinal system, and/or that pressure in the fluid inlet has dropped below a minimum pressure value, or has exceeded a maximum pressure value, and/or that the inlet valve is malfunctioning, and/or that there is a malfunction of the at least one HF motion sensor, and/or to identify a predefined urinal usage situation and/or frequency of use based on the evaluated data and adjust an opening time and/or an opening position and/or an opening frequency of the inlet valve based thereon during at least one subsequent urinal flushing process.

4. The urinal system of claim 1, wherein the urinal system comprises an error message and/or service notification output unit coupled with the data processing system.

5. The urinal system of claim 1, wherein the data processing sys-tem comprises at least one data processing block that is machine-learning and/or comprises an artificial neuronal net and/or includes an expert system.

6. Water consumer system comprising a urinal system according to one of the preceding claims, wherein the water consumer system comprises at least one additional water consumer in addition to the urinal system, where at least one additional sensor is provided, wherein the data processing system is coupled with the at least one additional sensor and is arranged to arithmetically evaluate the data captured by the at least one additional sensor and received by the data processing system and to include the data into the detection and/or prevention of at least one of the malfunctions.

7. The water consumer system of claim 6, wherein the water consumers and the urinal system are connected with each other via a meshed and/or a wireless local data transmission network.

8. Method for operating a urinal system comprising a urinal bowl, a fluid inlet with an inlet valve, a urinal outlet, at least one HF motion sensor for detecting fluid motion provided on the urinal bowl and/or at the urinal outlet and a urinal controller coupled with the at least one HF motion sensor and the inlet valve, by means of which the inlet valve is opened for a predefined time if draining fluid is detected by the at least one HF motion sensor, wherein the urinal controller comprises a data processing system and/or is connected to a data processing system, which at least retrieves and/or receives data captured by the at least one HF motion sensor, evaluates the data arithmetically and, based on the evaluated data, recognizes when there is one of the following malfunctions and/or triggers at least one action, in order to prevent one of the following malfunctions: that the urinal outlet is blocked and/or that there is a pressure fluctuation in a waste water system connected to the urinal system and/or that the fluid inlet and/or the inlet valve is faulty and/or that there is a malfunction of the at least one HF motion sensor and/or to identify a predefined urinal usage situation and/or frequency of use based on the evaluated data and adjust an opening time and/or an opening position and/or an opening frequency of the inlet valve based thereon during at least one subsequent urinal flushing process.

9. The method of claim 8, wherein a fluid pressure is captured by means of at least one pressure sensor and/or a fluid flow is captured by means of at least one flow sensor in the fluid inlet, the captured fluid pressure and/or the captured fluid flow is/are transmitted to the data processing system, the data processing system arithmetically evaluates the captured fluid pressure and/or the captured fluid flow along with the data retrieved and/or received by the at least one HF motion sensor and, based on the evaluated data, recognizes when there is at least one of the following malfunctions and/or triggers at least one action in order to prevent at least one of the following malfunctions: that the urinal outlet is blocked and/or that there is a pressure fluctuation in a waste water system connected to the urinal system and/or that the pressure in the fluid drops below a minimum pressure value or exceeds a maximum pressure value in the fluid inlet and/or that the fluid inlet and/or the inlet valve is faulty and/or that there is a malfunction of at least one of the at least one HF motion sensor and/or to identify a predefined urinal usage situation and/or frequency of use based on the evaluated data and adjusts an opening time and/or and opening position and/or an opening frequency of the inlet valve based thereon during at least one subsequent urinal flushing process.

10. Method for operating a urinal system with a urinal bowl, a fluid inlet with an inlet valve, a urinal outlet, at least one HF motion sensor for detecting fluid motion provided on the urinal bowl and/or the urinal outlet and a urinal controller coupled with the at least one HF motion sensor and the inlet valve, by means of which the inlet valve is opened for a predefined time if draining fluid is detected by the at least one HF motion sensor, wherein a fluid pressure is captured with at least one pressure sensor and/or a fluid flow is captured with at least one flow sensor in the fluid inlet and the urinal controller comprises a data processing system and/or is connected with a data processing system, which at least retrieves and/or receives data captured by the at least one HF motion sensor and/or the at least one pressure sensor and/or the at least one flow sensor, evaluates the data arithmetically and, based on the evaluated data, recognizes when there is at least one of the following malfunctions and/or triggers at least one action in order to prevent at least one of the following malfunctions: that the urinal outlet is blocked and/or that there is a pressure fluctuation in a waste water system connected to the urinal system and/or that the pressure in the fluid drops below a minimum pressure value or exceeds a maximum pressure value in the fluid inlet and/or that the fluid inlet and/or the inlet valve is faulty that there is a malfunction of at least one of the at least one HF motion sensor.

11. The method of claim 8, wherein the data processing system recognizes that the urinal outlet is blocked and/or the fluid inlet is faulty, if no draining fluid is detected by the HF motion sensor even though the inlet valve is open and/or it is detected by means of the at least one HF motion sensor that at least a lower area within the urinal bowl is filled with standing fluid.

12. The method of claim 11, wherein the data processing system recognizes whether the urinal outlet is blocked or the fluid inlet is faulty, if no draining fluid is detected by the at least HF motion sensor even though the inlet valve is opened and fluid pressure has been captured by the at least one pressure sensor and/or fluid flow has been captured by the at least one flow sensor and/or it is detected by means of the at least one HF motion sensor that at least a lower area within the urinal bowl is filled with standing fluid.

13. The method of claim 9, wherein the data processing system recognizes that the urinal outlet is partially blocked and/or the fluid inlet is faulty, if it is detected by the at least one HF motion sensor that there is a delayed drainage of fluid from the urinal bowl even though the inlet valve is opened.

14. The method of claim 13, wherein the data processing system recognizes, whether the urinal outlet is partially blocked or the fluid inlet is faulty when it is detected by the at least one HF motion sensor that fluid drains from the urinal bowl with a delay even though the inlet valve is opened and fluid pressure has been captured by the at least one pressure sensor and/or fluid flow has been captured by the at least one flow sensor.

15. The method of claim 9, wherein a respective opening time of the inlet valve is adjusted to the respective fluid pressure and/or the respective fluid flow in the fluid inlet by the urinal controller.

16. The method of claim 8, wherein the data processing system recognizes that the fluid inlet is faulty, if the at least one HF motion sensor detects no fluid flow and/or a permanent fluid flow and/or a fluid flow beneath a fluid flow threshold value.

17. The method of claim 8, wherein the urinal system comprises an error message and/or service notification output unit coupled with the data processing system and that the data processing system puts out a service notification to the error and/or service notification output unit when it recognizes at least one of the malfunctions.

18. The method of claim 8, wherein the data processing system recognizes that there is a pressure fluctuation in the waste water system connected to the urinal bowl if a series of consecutive faulty urinal flushing processes on the urinal system results from the process of the data of the at least one HF motion sensor and/or a signal pattern of the data of the at least one HF motion sensor corresponds to a characteristic fluctuation of the fluid level in the urinal outlet.

19. The method of claim 8, wherein when the data processing system recognizes that there is a pressure fluctuation in a waste water system connected to the urinal system, the urinal controller changes a sensitivity of the at least one HF motion sensor and/or when a signal pattern of the data of the at least one HF motion sensor corresponds to a characteristic fluctuation of the fluid level in the urinal outlet, does not initiate a urinal flushing process.

20. The method of claim 8, wherein the data processing system comprises at least one data processing block, which is machine-learning and/or works based on an artificial neuronal net and/or is an expert system.

21. The method of claim 8, wherein the urinal system is integrated into a water consumer system, which comprises at least one additional water consumer in addition to the urinal system, where at least one additional sensor is provided, wherein the data processing system is coupled with the at least one additional sensor and also arithmetically evaluates the data received by the at least one additional sensor, wherein at least one flushing time and/or blockage in an outlet and/or pressure fluctuation in a waste water system and/or defect of an inlet device of the at least one additional water consumer determined thereby, is included in the detection of at least one of the malfunctions.

22. The method of claim 21, wherein the water consumers and the urinal system communicate with each other via a meshed and/or a wireless local data transmission network.

23. The method of claim 8, wherein there is a malfunction of at least one of the at least one HF motion sensor if the data processing system does not receive data from at least one of the at least one HF motion sensor or the data of at least one of the at least one HF motion sensor received by the data processing system are not processible by the data processing system and/or at least one of the at least one HF motion sensor issues at least one service signal.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0166] The invention is explained in more detail below with reference to exemplary embodiments and the associated figures, without being restricted to these.

[0167] In the figures:

[0168] FIG. 1: is a schematic view of an embodiment of a urinal system according to the invention during a flushing process;

[0169] FIG. 2: is a schematic view of an embodiment of a urinal system according to the invention with a completely obstructed urinal outlet;

[0170] FIG. 3: is a flow diagram of a water pressure-adapted flush control of a urinal system according to the invention;

[0171] FIG. 4: is a flow chart for recognizing a reaction to an obstruction of an embodiment of a urinal system according to the invention;

[0172] FIG. 5: is a flow chart for valve diagnosis in an embodiment of a urinal system according to the invention;

[0173] FIG. 6: is a flow chart for saving water in an embodiment of a urinal system according to the invention.

DETAILED DESCRIPTION

[0174] FIG. 1 is a schematic view of an embodiment of a urinal system 10 according to the invention during a flushing process.

[0175] The urinal system 10 has a urinal bowl 1 with a fluid inlet 2 and a urinal outlet 4.

[0176] An inlet valve 3 is provided on the fluid inlet 2, with which the fluid inlet 2 can be opened or closed. When the inlet valve 3 is open, flush water 6 flows from the fluid inlet 2 via the urinal bowl 1 to the urinal outlet 4.

[0177] In the exemplary embodiment shown, an HF motion sensor 5 is attached to the back of the urinal bowl 1. In other embodiments of the present invention, several HF motion sensors 5 can also be provided on the urinal bowl 1 and/or at the urinal outlet 4.

[0178] The HF motion sensor 5 is oriented in such a way that its capture field 7 is inside the urinal bowl 1. The HF motion sensor 5 is thus able to register a motion of flowing flush water 6 as soon as it passes the capture field 7 of the HF motion sensor 5.

[0179] The data captured by the HF motion sensor 5 is transmitted to a data processing system 9 of a urinal controller 8 of the urinal system 10 and evaluated computationally by the same. In the exemplary embodiment shown in FIG. 1, the data processing system 9 is a microcontroller integrated into the urinal controller 8; but in other embodiments of the invention, it can also be provided separately from the urinal controller 8 and be, for example, a cloud or a gateway. In the exemplary embodiment shown, the data processing system 9 is coupled to an error message and/or service message output unit 11.

[0180] If at least one malfunction in the urinal system 10 is recognized on the basis of this transmitted data, the data processing system 9 can trigger at least one corresponding action in order to prevent the at least one malfunction. Such an action can, for example, be preventing the inlet valve 3 from reopening, and/or sending an error message and/or service message to the error message and/or service message output unit 11.

[0181] In the embodiment of the invention shown in FIG. 1, a pressure sensor 12 is arranged in the fluid inlet 2. In other embodiments of the present invention, a flow sensor can also be arranged instead of the pressure sensor 12 or in addition to the pressure sensor 12. In addition, a plurality of pressure sensors 12 and/or flow sensors can also be arranged in the course of the fluid inlet 2. Furthermore, there are simple embodiments of the present invention in which the urinal system has neither a pressure sensor nor a flow sensor in the fluid inlet 2.

[0182] In the urinal system 10, urine flows into the urinal outlet 4 via the inside of the urinal bowl 1, which is typically made of ceramic. The flowing fluid, i.e. the urine, is recognized by the HF motion sensor 5. The HF motion sensor 5 sends a corresponding signal to the urinal controller 8, which opens the inlet valve 3 in the fluid supply line 2 for a certain time when a certain amount of fluid motion is detected, and thus triggers the urinal to be flushed.

[0183] For example, the inlet valve 3, which is, for example, a solenoid valve, is opened for about 2 to 8 seconds depending on the set flushing volume. After the inlet valve 3 is closed, the water continues to flow for a certain time, due to various effects: [0184] hydraulic delay of the inlet valve 3, which is typically on the order of 1 to 2 seconds, and/or [0185] slow replacement of fluid from hoses or pipes between the inlet valve 3 and the urinal inlet and/or a water reservoir, which can take place over a longer period of up to 30 seconds, and/or [0186] slow drainage of fluid from the ceramic surface of the urinal bowl 1, which can occur over a period of 5 to 10 seconds, and/or [0187] slow drainage of fluid due to a partially obstructed urinal outlet 4, which leads to a longer observation of the drainage of the fluid by the at least one HF motion sensor 5.

[0188] Because, in the present invention, motion data captured continuously or in stages by the at least one HF motion sensor 5 is transmitted to the urinal controller 8, according to the invention a typical behavior is learned by the data processing system 9 connected to or integrated into the urinal controller 8, wherein deviations from normal operation, such as a beginning obstruction due to slowly increasing drainage time of fluid at the urinal system 10, are recognized via a trend analysis carried out by the data processing system 9. In the present invention, environmental conditions such as cleaning processes in the urinal system 10 and/or a water pressure detected in the fluid supply line 2, must be taken into account.

[0189] FIG. 2 shows a schematic view of a urinal system 10 designed as in FIG. 1, with a completely obstructed urinal outlet 4. In the urinal bowl 1, there is a fluid 13 above the obstructed urinal outlet 4. The detection area 7 of the HF motion sensor 5 shown in FIG. 1 is completely covered with the fluid 13 in the state shown in FIG. 2.

[0190] Since the HF motion sensor 5 cannot penetrate the fluid 13, it does not register any motion of the arriving urine, and accordingly does not register any use of the urinal. The data processing system 9 thus does not trigger any opening of the inlet valve 3 of the fluid inlet 2. In addition to preventing the inlet valve 3 from reopening, an obstruction can be reported to a mobile device or a building control.

[0191] FIG. 3 shows a flow diagram of a flush control adapted to the water pressure of an embodiment of a urinal system 10 according to the invention, which can be designed similarly to the embodiment in FIGS. 1 and 2, which is why reference is made below to the reference numerals used in FIGS. 1 and 2.

[0192] The urinal controller 8 is coupled to at least one HF motion sensor 5 for detecting the use of the urinal system 10 and at least one actuator for triggering a flush. The at least one actuator is an inlet valve 3, which is designed as a solenoid valve in the exemplary embodiment shown. The urinal controller 8 captures usage data, among other things, via the at least one HF motion sensor 5. Based on this data, the urinal controller 8 determines, for example, the water consumption of the urinal system 10, usage statistics and/or a time profile of a usage process. For example, 8 flushes are counted by the urinal controller for this purpose, multiplied by the given flushing volume and, if necessary, pressure and/or flow values are added.

[0193] For the water supply of the urinal system 10, parameters such as the water pressure and/or the flow rate are detected as operating data of the water supply. For this purpose, the at least one pressure sensor 12 and/or the at least one flow sensor are arranged in the fluid inlet 2.

[0194] The usage data captured by the urinal controller 8 and the operating data of the water supply are transmitted to the data processing system 9 and used for computational evaluation. The computational evaluation is carried out using AI algorithms and/or modeling.

[0195] An analysis of the pressure and flow rate takes place in the data processing system 9. There is a recognition of overpressure or underpressure, a recognition of pressure fluctuations, pressure peaks and other problems of the water supply, and a recognition of trends. Furthermore, the data processing system 9 establishes a relationship with the usage data of the urinal system 10.

[0196] In the event of critical pressure conditions, such as overpressure or underpressure, an error message and/or service message is sent to the building operator, a plumber, a building management system, a cloud and/or the responsible water supplier. A warning or an alarm can also be triggered.

[0197] In the case of regular pressure conditions, a flushing volume regulation takes place in the urinal system 10 through the urinal controller 8. In this case, a flushing time in the urinal system 10 is adapted to a detected water pressure or a detected flow rate, with fluctuations and trends being taken into account. The aim is a proper flushing of the urinal system 10, as completely as possible. When the flushing time is adjusted, the operating parameters of the urinal system 10 are adjusted, and in turn are transmitted to the urinal controller 8.

[0198] FIG. 4 shows a flow chart for recognizing and reacting to an obstruction in an embodiment of a urinal system 10 according to the invention. The same reference numerals are used here as above; reference is made to the description above.

[0199] The urinal controller 8 is coupled to at least one HF motion sensor 5 for detecting various parameters and to at least one actuator for triggering a flush. The parameters recognized by the at least one HF motion sensor 5 are urinal use, flowing flush water 6, drainage behavior and speed, as well as fluid 13 being in the urinal bowl 1 in the form of retained water.

[0200] The at least one actuator in this case is an inlet valve 3 which, in the embodiment shown, is designed as a solenoid valve.

[0201] The urinal controller 8 captures usage data and sensor data. The usage data contains, for example, the water consumption of the urinal system 10, usage statistics, or the profile of a usage process over time. The sensor data contains a flush water flow, the drain rate, and/or the presence of an obstruction and/or fluid 13 located in the urinal bowl 1, such as retained water, for example.

[0202] For the water supply of the urinal system 10, parameters such as water pressure, flow rate, water quality and/or water temperature are captured as operating data of the water supply. For this purpose, at least one pressure sensor 12 and/or at least one flow sensor and/or at least one temperature sensor are arranged in the fluid inlet 2. For example, water quality data relate to the lime content of the water.

[0203] For a wastewater line connected to the urinal outlet 4, the flow rate and/or a possible obstruction are captured as operating data of the wastewater line.

[0204] The usage data and sensor data from the urinal controller 8, the operating data of the water supply and the operating data of the wastewater line is then analyzed with the help of AI algorithms. An analysis of the drainage behavior, a trend analysis to detect changes, the detection of existing and beginning obstructions, the detection of a declining drainage performance, and/or the detection of service requirements are carried out.

[0205] If the urinal system 10 is completely obstructed, fluid builds up in the urinal bowl 1, as can be seen schematically in FIG. 2. If the capture area 7 of the HF motion sensor 5 in the urinal bowl 1 shown in FIG. 1 is filled with fluid, the HF motion sensor 5 no longer detects a flow of fluid because the HF signal from the HF motion sensor 5 typically cannot penetrate the standing fluid 13. In this situation, no use is detected and, if the device is completely obstructed, no flushing is detected.

[0206] With the present invention, this situation can be recognized without delay. Due to the gradually-increasing re-fill time of fluid in the urinal system 10, the trend analysis carried out by the data processing system 9 results in the decision that obstruction is beginning. When evaluating the re-fill time, environmental conditions such as water pressure, cleaning, optionally flushing of further fittings, etc. can be taken into account.

[0207] If an obstruction, a beginning obstruction or a decreasing drainage capacity is detected in the urinal system 10, the urinal controller 8 and/or the data processing system 9 sends an error message and/or service message to the building operator, a plumber, a building management system and/or a cloud. The drain should then be checked and, if necessary, a water seal in the urinal system 10 should be changed.

[0208] If neither an obstruction nor a beginning obstruction or a declining drainage capacity is detected, settings on the urinal system 10 may be adjusted, such as adjusting the flushing time or adjusting the flushing interval. With the adjustment of the flushing time and/or the flushing interval, the operating parameters are adjusted, which in turn are transmitted to the urinal controller.

[0209] FIG. 5 is a flow diagram for valve diagnosis on an inlet valve 3 of an embodiment of a urinal system 10 according to the invention, which is designed in accordance with or similar to the embodiment of FIGS. 1 and 2, to which reference is made below.

[0210] In the method shown in FIG. 5 and carried out with the urinal system 10, operating parameters are detected and/or stored continuously or at predetermined time intervals by the urinal controller 8 of the urinal system 10. Such operating parameters can, for example, also be operating parameters initiated by the urinal controller 8 itself, such as a flushing time at one or more urinals of the urinal system 10 and/or actions carried out on the urinal system 10, such as the opening and/or closing of at least one inlet valve 3 of the urinal system 10.

[0211] The urinal controller 8 is coupled to at least one HF motion sensor 5 arranged on the urinal bowl 1 and/or the urinal outlet 4. The urinal controller 8 can also form a structural unit with the at least one HF motion sensor 5.

[0212] The at least one HF motion sensor 5, together with the urinal controller 8, for example, detects a urinal use and/or flowing flush water 6 and/or a drainage behavior at a urinal and/or a drainage speed at the urinal and/or fluid 13, such as retained water, in the urinal bowl 1.

[0213] Furthermore, as already mentioned above, the urinal controller 8, which is also coupled to at least one inlet valve 3 provided in the fluid inlet 2, and can control it, detects and/or saves actions performed at the inlet valve 3, such as triggering a flush and the duration thereof.

[0214] The data captured and/or stored by the urinal controller 8 can be subdivided into usage data and sensor data.

[0215] The usage data can contain data on the water consumption of the urinal system 10 and/or on the usage statistics of the urinal system 10 and/or on the chronological profile of uses of the urinal system 10.

[0216] The sensor data can include data on the flush water flow in the urinal system 10 and/or on the flow rate in the urinal system 10 and/or on an obstruction in the urinal system 10 and/or on the presence of retained water in the urinal bowl 1 and/or on a flow profile at the inlet valve 3.

[0217] In addition, operating data from a water supply connected to the urinal system 10 and/or from the surroundings of the urinal system 10 is captured for the urinal system 10. Such operating data can, for example, be a water pressure detected with the pressure sensor 12 provided in the fluid supply line 2 and/or a water flow rate detected in the fluid supply line and/or data on the water quality, such as lime content, the water supplied to the urinal system 10 and/or the water temperature of the water supplied to the urinal system 10.

[0218] The usage data, the sensor data and the operating data are processed by the data processing system 9. The data processing system 9 works using artificial intelligence (AI) methods and on the basis of modeling.

[0219] Each of the following processes can be carried out individually or in combination in the data processing system 9 on the basis of an analysis of the sensor data, the usage data and the operating data of the water supply: [0220] Analysis of pressure and/or flow rate during a flushing process in the urinal system 10 [0221] Analysis of a water flow during a flushing process in the urinal system 10 [0222] Analysis of a drainage behavior in the urinal system 10 [0223] Trend analysis [0224] Detection of changes to the urinal system 10 [0225] Detection of at least one valve malfunction at the inlet valve 3 in the event of a failure to open or a failure to close [0226] Detection of insufficient flow in the urinal system 10 [0227] Analysis of a power consumption at the inlet valve 3 to detect electrical valve malfunctions and/or to draw conclusions about a water flow in the inlet valve 3.

[0228] If at least one of these processes detects a valve malfunction at the inlet valve 3, the data processing system 9 triggers at least one damage limitation step.

[0229] Such a step can be, for example, triggering a repeated valve closing process on the inlet valve 3 and/or prevent further opening of the inlet valve 3, for example until the next service appointment, and/or adapting a flushing time of the urinal system 10 to a detected flow of fluid through the fluid supply line 2. The step or steps taken to limit the damage are incorporated as control data in the operating parameters of the urinal system 10 mentioned at the outset, stored by the urinal controller 8, and included in further analyses by the data processing system 9.

[0230] Additionally or alternatively, the data processing system 9 can send at least one message to a device operator, a plumber, a building management system, and/or a cloud. This message can contain information and/or data on the presence of an obstruction and/or other malfunction in the urinal system 10. The message can also contain specific instructions at this point, such as instructions for removing the obstruction and/or for checking the drainage and/or for changing a water seal on the urinal system 10.

[0231] Furthermore, the data processing system 9 preferably transmits a signal to a main shut-off valve. As a result of this signal, the water supply to the urinal system 10 is shut off if the inlet valve 3 does not close.

[0232] FIG. 6 shows a flow diagram of processes in an embodiment of a urinal system 10 according to the invention, which can be used to save water. The urinal system 10 shown in FIGS. 1 and 2, to which reference is made below, or a similar urinal system can again be used as the urinal system 10.

[0233] In the method shown in FIG. 6 and carried out in the urinal system 10, operating parameters of the urinal system 10 are captured and/or stored by a urinal controller 8 continuously or at predetermined time intervals. Such operating parameters can, for example, be a flushing volume in one or more urinals of the urinal system 10 and/or a sensitivity of at least one sensor used in the urinal system 10 and/or a maximum cycle time of the urinal system 10 and/or a flow through the urinal system 10 and/or a hybrid mode of the urinal system 10 and/or a water saving program set in the urinal system 10 and/or actions carried out in the urinal system 10, such as opening and/or closing at least one inlet valve 3 of the urinal system 10 and/or a cleaning procedure lock and/or switching off of a water supply to the urinal system 10 and/or performing a thermal disinfection on the urinal system 10 and/or activating lighting in the urinal system 10 and/or other product-specific actions in the urinal system 10.

[0234] The captured and/or stored operating parameters and actions are processed in a data processing system 9.

[0235] The urinal controller 8 is coupled to the at least one HF motion sensor 5 to detect uses of the urinal system 10, and to the inlet valve 3 to trigger a flush; the latter can be a solenoid valve, for example.

[0236] In the exemplary embodiment shown, the urinal controller 8 is, unlike in FIGS. 1 and 2, connected to the data processing system 9 formed separately from the urinal controller 8, which in other embodiments of the invention, as can be seen in FIGS. 1 and 2, can also be part of the urinal controller 8.

[0237] In the exemplary embodiment shown in FIG. 6, the urinal controller 8 transmits operating data, which can contain, for example, data on water consumption in the urinal system 10, flow data, data on water pressure in the urinal system 10, data on a chronological profile of water consumption, flow rate and/or water pressure in the urinal system 10 and/or on the user frequency of the urinal system 10, to the data processing system 9.

[0238] In the example of FIG. 6, [0239] operating data from a water supply of the urinal system 10, which can contain data on water pressure, flow rate and/or their respective chronological profile, and/or [0240] operating data of a further building system, such as a light controller and/or a door controller, which can contain, for example, access data from door controllers and/or data from motion or presence detectors of the light controller, and/or [0241] user data from users using the urinal system 10 and/or the building in which the urinal system 10 is located, such as data on presence, age, gender, mood and/or user feedback from users, and/or [0242] data from other data sources, such as at least one transit timetable, at least one flight schedule, at least one cleaning schedule, at least one game time, opening times and/or data of at least one weather forecast, from which predictive data is created

[0243] is/are transmitted to the data processing system 9 in addition to the operating data from the urinal controller 8.

[0244] The data processing system 9 uses artificial intelligence algorithms and at least one modeling function for the further processing of the transmitted data.

[0245] In the exemplary embodiment shown in FIG. 6, the data processing system 9 creates an operating model by establishing a correlation between the operating data transmitted from the different sources, establishes interactions between various elements, such as between the water supply and water consumers of a water consumer system in which the urinal system 10 is integrated, and recognizes and predicts usage scenarios.

[0246] Such usage scenarios can, for example, be classified by the data processing system 9 into normal operation with occasional use of the urinal system 10, a temporary high frequency of use of the urinal system 10, for example during an intermission in a theater, a standby period when the urinal system 10 is not being used, a cleaning or service operation, or other application-specific scenarios.

[0247] The data processing system 9 preferably already contains a basic model of the installation for describing the water supply, the water consumers of the water consumer system, the further building systems, the influence of the predictive data, the users, and the interactions between these elements. This model can preferably be further developed by the data processing system 9 continuously or step by step, and thereby improved.

[0248] From the operating model and the basic model, decisions and/or proposals are preferably created by the data processing system 9 which, for example, relate to or include predicting usage situations and/or optimizing the operating parameters, such as optimizing the consumption of water and/or other consumed supplies of the urinal system 10 or the water consumption system, optimizing the user experience of users of the urinal system 10 or the water consumer system, and/or optimizing service of the urinal system 10 or the water consumer system, and/or triggering actions on the urinal system 10 or the water consumer system, and/or outputting at least one piece of information to the user and/or to a building management and/or a plumber.

[0249] The decisions and/or suggestions are included as control data in the operating parameters of the urinal system 10 mentioned at the outset, stored by the urinal controller 8, and included in further analyses by the data processing system 9.

[0250] The exemplary embodiments explained above can also be combined with each other.

[0251] In the present invention, malfunctions in the at least one HF motion sensor 5 can also be detected. In some cases, different malfunctions in the HF motion sensor 5 can lead to the same or similar effects. If, for example, the HF motion sensor 5 does not detect flushing water flowing during a flush, this can be due to the following causes: [0252] complete obstruction, whereby the HF motion sensor 5 does not detect any motion because it is “blind,” [0253] malfunction in the inlet valve 3 or electronics malfunction resulting in the inlet valve 3 not opening, [0254] malfunction in the water supply and/or absence of water supply to the urinal.

[0255] A distinction between these situations can be made in the data processing system 9 by combining the signals from the HF motion sensor 5 with one or more of the following additional pieces of information: [0256] at least one pressure sensor 12 in the fluid supply line 2 detects whether the water supply is intact, [0257] at least one flow sensor in or on the fluid supply line 2 detects independently of the at least one HF motion sensor 5 whether water is flowing, [0258] information from other sensors as to whether other sensors have detected a malfunction in the water supply, [0259] plausibility/learning of typical signal processes (for example, a complete obstruction is unlikely immediately after a use is detected) [0260] sensory detection of complete obstruction.

[0261] The corresponding situations can be recognized and distinguished from each other in the data processing system 9 on the basis of typical signal profiles in conjunction with data from further sensors with the aid of a classifier and using methods of artificial intelligence.

[0262] By combining the data from various sources and methods of artificial intelligence, functions are enabled according to the invention that are not possible with a conventional sensor or are only possible through human decisions and human intervention.

[0263] For example, the present invention enables the following applications:

[0264] For example, a) a flushing volume regulation and/or a pressure warning is possible as follows:

[0265] A urinal system 10 is flushed by opening an inlet valve 3 for a defined time. The flushing time is usually set so that a desired amount of water (flushing volume) flows into the urinal bowl 1 at a defined water pressure (nominal pressure, usually 3 bar). The actual flushing volume depends on the actual water pressure and can vary significantly from the desired flushing volume.

[0266] A flushing volume which is too low can lead to increased urine scale formation or bacterial growth in the water seal or in the drain pipe as a result of insufficient replacement of the water seal of the urinal system 10, and consequently to an obstruction. Too high a flushing volume unnecessarily increases water consumption.

[0267] If the water pressure is low, it may not be possible to achieve adequate replacement of the water seal even by extending the flushing time. This can quickly lead to obstruction.

[0268] By networking the urinal flush system, for example via a wireless or mesh data transmission network, such as Bluetooth or Bluetooth mesh, with the pressure sensor 12 or a flow sensor, or by integrating the pressure sensor 12 or a flow sensor directly into the urinal flush system of the urinal system 10, the flushing time can be adjusted as a function of the actual water pressure or the flow rate, so that the flushing volume can be set much more precisely (flushing volume regulation).

[0269] If the water pressure or flow falls below a certain minimum for a certain time, a diagnosis message can be triggered to inform a responsible person about the increased risk of obstruction and to initiate appropriate measures.

[0270] Furthermore, b) an obstruction or risk of obstruction can be recognized and reported as follows:

[0271] In the event of a complete or partial obstruction of the urinal outlet 4, fluid accumulates in the urinal bowl. In this situation, the at least one HF motion sensor 5 does not recognize a use, and the urinal controller 8 also does not initiate any flushing until the obstruction is cleared. This situation is usually only recognized by users or cleaning staff after complete obstruction, and then leads to complaints and/or service calls.

[0272] The at least one HF motion sensor 5, in combination with the urinal controller 8 and the data processing system 9 connected to it, effects an evaluation of the flow and drainage behavior in the urinal system 10 during and after flushing. In this way, when “no drainage” is detected, it is recognized that there may be a complete obstruction, and when “changed drainage behavior” is detected, it is recognized that there may be a beginning obstruction. By means of a trend analysis carried out in the data processing system 9, which is carried out over a longer period of time, a beginning obstruction can thus be predicted in good time.

[0273] A complete obstruction of one or more urinals of the urinal system 10 can also be detected by sensors by evaluating sensor signals from the at least one HF motion sensor 5 or another sensor, as explained above under point a).

[0274] To assess the risk of obstruction, the data processing system 9 can also use additional data, if available, such as the water quality, such as the lime content of the water, the flow rate in the wastewater disposal system, information about the gradient of wastewater lines, or the given temperature. All of these factors can, for example, influence urine scale formation and bacterial growth and thus the risk of obstruction.

[0275] If a complete or partial obstruction is detected, a diagnostic message can be output by means of the data processing system 9.

[0276] In addition, it is c) possible to carry out an expanded valve diagnosis of the urinal system 10 as follows:

[0277] Inlet valves 3 in the form of solenoid valves are used to control the water flow for flushing urinals and other electronic products in the water sector. As electronic components, solenoid valves are always a weak point in the system due to their limited service life, for example due to contamination. Defective solenoid valves can lead to a functional failure of the urinal system 10 in which no flushing is carried out, and/or can lead to continuous operation of the urinal system 10 if they do not perform a closing function.

[0278] In contrast, the present invention enables valve diagnosis of the inlet valve 3.

[0279] The at least one HF motion sensor 5 can detect the flowing and draining fluid in the event of a flush. It can thus be recognized with the urinal system 10 according to the invention whether water is flowing during a flush and whether the water flow stops again after the flush. Through a combination with data from other networked sensors, such as pressure sensor(s) 12 and/or flow sensor(s) in the fluid supply line 2, and/or a detection of the flow behavior in the drain of the urinal system 10, it is possible in embodiments of the present invention to distinguish between a valve malfunction and situations such as a use directly after a flush, a cleaning, and a shut-off water supply, among other things. For this purpose, rules and methods of artificial intelligence, such as learning typical usage situations, can be used by the data processing system 9.

[0280] In the event a valve malfunction is detected, the data processing system 9 can trigger a diagnostic message. If the malfunction leads to a permanent flow of water, the water supply of the affected area—such as a room—can be shut off in cooperation with a main shutoff valve, for example via a wireless or mesh data transmission network 14, such as Bluetooth or Bluetooth mesh.

[0281] Finally, d) the present invention allows for the possibility of a usage profile analysis proceeding as follows, and/or the application of the water-saving algorithms described as follows:

[0282] A standard function of urinal sensors in the prior art is a flush after each use of the urinal. For installations with high user frequency, such as in public buildings, stadiums, etc., water-saving programs can be implemented in known sanitary products that reduce the number of flushes in certain operating situations. The rigid controls of these operating modes mean that these programs do not come into effect in many installations, because, for example, the criteria of a stadium mode are not met despite high user frequency, or the ease of use is unnecessarily restricted, so that, for example, fewer flushes are performed despite low user frequency.

[0283] In the present invention, however, an analysis of the actual usage profile of a urinal system 10 is performed. In this case, typical usage scenarios of the urinal system 10 are recognized over a longer period of time, times of high usage of the urinal system 10 are identified, and suitable and effective water-saving programs are activated for the given situation.

[0284] In addition to the operating data of the at least one HF motion sensor 5, the analysis of the usage profiles can also include further data from other products, such as data from other sanitary products in the room, which provide a measure of how often the room is used, schedules/opening times of a building, theater schedules and/or airport flight schedules, etc., in order to predict times of high traffic and to activate water-saving programs tailored to the given situation. In this way, a flush interval and the flushing volume can be adapted to an expected number of users, and a cleaning flush with a high flushing volume can be triggered at suitable times.

[0285] Intervention by the respective user or building operator is possible in principle, but not necessary for the present invention to function.

[0286] With the aid of the present invention it is also possible to optimize the cleaning cycles of the urinal system 10. For example, consumables such as soap or towels can be replenished before anticipated traffic, and cleaning can be carried out after a use frequency.