FR2922015A1 - Water system management and water leakage detection device for use in e.g. hotel's toilet, has water presence sensors detecting water leakage in water pipes and structured parts of building and abnormal presence of water outside pipes - Google Patents

Abstract

The device has solenoid valves (19a1, 19a2) mounted on water pipes of a water system, where the valves are controlled to move from a open state to a closed state or vice versa. Water presence sensors (3a, 5a) detect leakage of water in the water pipes and structured parts (15) of a building, and detect abnormal presence of the water outside the pipes. An electronic module is integrated with a centralized control module that transmits the data towards a computer. The sensors send a signal to a local cutting module (9) for cutting arrival of the water during leakage. An independent claim is also included for a method for detecting water leakage and centralized management of a water system in structured parts of a building.

Description

The present invention relates, in general, to the field of water management, and more specifically to a device and a device for detecting water leaks and to a centralized management of a water network in a building. method of detecting water leaks and centralized management of a water network in several rooms of a building.

For built structures, such as hotels, water damage can cause significant inconvenience. In addition, controlling your water consumption is important. If there is a leak, it can be annoying for the users and can generate damage and then significant costs. An objective here is to prevent and avoid damage caused by water leaks. Another objective is to facilitate the management of the network and / or the water consumption of these built structures. A solution proposed to achieve all or part of these objectives consists of a device comprising: in the parts of the built structure concerned, or even just upstream of these parts: detection means comprising at least one of: at least one detector of presence of water 30 out of pipeline, as on the ground in at least some of said rooms of the building or just upstream thereof, the detector (s) being associated (s) with first means data transmissions from said detector (s) in connection with a water detection, at least one water flow detector above a predetermined flow threshold, in one or more several pipes of the said part (s) considered, this flow detector being associated with a second local means for transmitting data from this detector in connection with an excessive flow detection of water, solenoid valves placed on some at least the said water pipes of the parts considered, electronic modules of cut: o sensing the data transmitted by the detectors, o interacting with a centralized control module to transmit to it the detected detection data and to receive from him cut-off and opening orders for the water, via the solenoid valves, and, in a control room, centralized computer management means connected to the centralized control module and able to: provide information on a state of the network; water in at least some of said parts as detected by the different detectors, 25 o control each solenoid valve, by means of said electronic modules cutoff. It is therefore an autonomous system for managing water leaks. Very advantageously, this device will incorporate three levels of protection against these water leaks, comprising said detector (s) of presence of water especially on the ground, detector (s) of water flow beyond said threshold of predetermined flow, in one or more pipes, and centralized computer management means which are adapted to control at least some solenoid valves, by means of said electronic cutting modules, for a voluntary water cut, preventive or not, from the control room via all or part of these solenoid valves. Thus, we will be able to manage at the same time the risks of floods, the cuts of safety and the leaks of low flows (toilets, faucets of washbasins ....). As regards the detection and centralized management method proposed here, it is characterized in particular by the fact that. the parts of the building in question are equipped with said solenoid valves mounted on the mains water pipes and controllable to pass from an open to closed state, and conversely, water detectors to detect a leak in the least a water pipe of these parts and / or an abnormal presence of water off the pipe, such as on the ground, and transmit this information remotely, 25 - and remotely communicate these water sensors and solenoid valves with a central computer that centralizes the data from the detectors and can control the change of state of these solenoid valves. If necessary, in case of leakage or preventative manner, it will be possible to isolate by piece or group of parts said pipes and / or trigger the intervention of an operator for repair or maintenance. Other characteristics and advantages of the invention will become apparent from the following more detailed description, given in a nonlimiting manner, with reference to the accompanying drawings, in which: FIG. 1 schematizes a body of water with risers for its water supply; FIG. 2 schematizes a water presence sensor 10 placed on the ground, to detect a leak of the early flood type; FIG. 3 schematizes an assembly comprising the aforementioned water presence sensor, controlled valves located at the input of a room and a local breaking module 15 according to the invention; FIG. 4 shows the electrical connections between the main electronic components (modules / cards) of the device according to the invention; FIGS. 5, 6 schematize a water presence sensor comprising an elongated strip provided with long sensitive conductive wires; to the water to detect a leak around a pipe, - and Figure 7 shows a possible operational diagram of the detector circuit of Figure 2. The technical characteristics common to several figures are each designated by the same reference numeral in the figures concerned. The device 1 in question is an electronic system for controlling and closing water inlets for rooms, such as hotel rooms. The example of these hotel rooms is given below. This device is automatically controlled in case of water leaks or, in case of vacancy of the / each room controlled by a computer.

As illustrated in FIG. 1, in each part concerned, it is checked by presence or water flow sensors such as 3a, 5a. It serves to prevent any water leaks that can occur at any time, for example in the bathroom associated with a room. Two types of sensors are preferably provided: as shown in FIG. 2, detectors 3a for the presence of water outside the pipeline, as here on the floor 4 in at least some of the rooms of the building under consideration. The detector illustrated is associated with said first local means 90a1 for transmitting data from the detector, as shown in FIGS. 3 and 4, detectors 5a for the flow of water beyond a predetermined flow threshold ( a priori weak, such as leakage of drips from a flush or a tap), in one or more pipes of the rooms, such as 15, considered, each of these water flow detectors, here 5a1, 5a2, being associated with a second local means, such 90a2, of data transmission from the detector. For multiple security, in particular triple, referred to, a use of several groups of detectors or sensors 3a, 5a is preferably provided. 25, Figs. 1 and 3, the group of water flow detectors 5a comprises two detectors respectively mounted on the hot water inlet 16a and the cold water inlet 17a in the room 15. These arrivals are connected respectively to the hot water risers 18a and 30 of cold water 19a usually located in the technical sheath 20. Optionally, the detectors on pipes (5a or 5b, see fig.5) may be arranged in the technical sheath 20 just upstream / entry of the part 35 to be monitored.

Preferably, each detector 3a will be placed at a small distance above the level of the ground on which it will be placed, to detect the water only in case of onset of flooding.

The sensors can be found especially in a bathroom, under the sink, the bathtub, the toilet. They can also be found in particular around a riser, for detecting flow leakage along the outer wall of this pipe. Figures 2 and 3, we see that under the housing 30 of the detector 3a schematically, there are two electrodes 130a1,130a2 which act as a switch, which is open without the presence of electrically conductive fluid between them. If water in particular limestone (that is to say tap water) is between them, the electrical circuit to which they belong will close against and detection data of this water will be transmitted via the 32a electronic processing 90a1 transmission module that can be equipped with a zigbee transmission chip. The electrodes extend under the housing to a level (H) higher than that of the lower limit of the feet 31, so that, placed on the floor 4 of the room, this device will detect a beginning of water leak in the room. Via the feet 31 (Figure 2), a height H between 0.5 and 20 mm can be established. Preferably this height will be between 1 mm to 4 mm, for better efficiency. If the electrodes closes the circuit, an output signal (voltage) will be sent to a signal conditioning unit whose output will itself be amplified, via an operational amplifier (OA) preferably to achieve a signal ratio / noise the - the weak, in order to avoid untimely detections due to

electrical noise. At the output of the OA, the transmission can be provided by the zigbee chip. A possible operational diagram of this circuit 100 is shown in FIG. 7, which circuit can be used for the detector 5b presented below. Thus, each sensor, when it will be in contact with water will be able to send a signal to a local cut-off module 9, to cut off the corresponding water supply.

A priori remotely, in a separate room, 150, a computer management, via the appropriate software of a centralized computer management means 7 (computer) can also provide real-time all useful information: operation, leaks or consumption of the modules. Each break module is designed as an electronic module. The transmissions can in particular be RF (radio frequency) or wired.

Thus, a zigbee type transmission can be provided, as already indicated. In this case, the cutoff module 9, which is built around an electronic card, will include a 100al communication module zigbee standard able to communicate with the transmitter 90a1. FIG. 3 shows that the module 9 also comprises an ion communication module (low water flow) 100a2 connected to the detectors 5a1, 5a2 to receive their data and transmit them to the central computer 7.

Each water cutoff module will be at an appropriate distance from the sensor (s) connected with it, preferably in a technical duct. From Fig.3, it should be understood that via a system of solenoid valves, such 19a1, 19a2 mounted therefore on the arrivals; respectively hot water 16a and cold 17a in the room 15, and each controlled by the

microcontroller 101, the cutoff module considered 9 can cut the water in one and / or the other of these pipes 16a, 17a, this when all or part of the sensors in question will have detected a flow of water in the room . A minimum trigger threshold may be provided, so that the / each flow detector 5a1, 5a2 functions as a detector, or flowmeter, of low ion rate, in connection with the module 100a2.

Each detector 5a1, 5a2 may comprise several electrodes 21, for example three for each of them. If calcareous water is between them, the electric circuit to which they belong will close and detection data of this water will be transmitted to the module 100a2 for retransmission of the information to the centralized control module 23 (Figs. 1 and 3). Thus, from each piece as equipped with the aforementioned means, the local detection of leaks on the ground or in the water supply will cause the transmission of detection data to the computer 7, via a centralized module of command 23 serving as an interface between all the local modules 9 of water cutoff and the computer 7.

For this communication, which can in particular be carried out by carrier current, a CPL module 90a2 has preferably been provided on the electronic card of the local module 9 of each room, this module receiving, in return, the data sent by the central module 23, to remotely activate the closure of the / each solenoid valve concerned, if a decision to cut was made. FIG. 4 schematizes the exchanges and commands on each local module 9: The communication card 100al receives the signals from the detectors 3a installed and can exchange with the central module 23. It is also in

exchange with the microcontroller 101 and the communication card (CPL) 90a2. The latter is in exchange with the rate control card 100a2, the microcontroller and the central module 23 for transmitting the data of the detectors concerned to the computer 7 and receive back the cut orders. These orders are transmitted to the solenoid valves via the microcontroller. the flow control card 100a2 is in exchange with the detection electrodes 21.

Each solenoid valve will integrate or not its electronic control board (if necessary equipped with a zigbee transmission chip). If this is not the case, this card will be deported. On the computer 7, a suitable processing software is provided, including a communication application and module management with the computer. On the basis of the foregoing, the functionalities will preferably be as follows: - for controlling a cut-off of hot and / or cold water arrivals (preferably hot and cold for a total prevention and identification of the origin of the leak) via the corresponding solenoid valve (s), such as 19a1 and / or 19a2, the following operations will be performed: * retrieve the information from / from each water presence sensor with which the local module is in an I / O link, such as 3a. * give an order to a solenoid valve, if the sensor concerned detects a flood or a water leak, * receive the orders sent by the computer to remotely activate the / solenoid valves, * transmit the state of the sensor (s) 3a ..., 35 * transmit the state of the / each solenoid valve concerned, * transmit the state of the / each solenoid valve concerned, * transmit leak indications, * self-test; * self-test; for the communication between the system for shutting off the hot and cold water inlets, via the solenoid valves and the computer 7, the following operations are performed: * communicate with the local cutoff modules 9, * communicate with the computer 7, via the central module 23, * dissociate the information of each module, 15 for, if necessary, a traceability and individualized monitoring by local module. Preferably, the management software of the computer 7 will be as follows: * it can operate with a current personal computer 20 integrating an operating system, * it will present a priori a graphical interface, * it will display the states of one or more of the local cut-off modules 9 corresponding to the room (s) considered, with an identification linked for example to the number of the room if one is in a hotel, it will automatically record, preferably in real time, the operating incidents, favorably with date, time, place ..., * it will receive in real time the state of the 30 sensors 3a ... and local systems 9 control of the arrival cutoff (s) hot water and / or cold water. * it will send an order to one or more of these opening or closing modules of the valve (s) 19al, 19a2 concerned (s), 10 * preferably it will be able to test the state in operation / out of operation of these modules and sensors, * preferably, it will furthermore make it possible to print all the states recorded, * preferably, it will moreover present a network function for remote maintenance, * preferably, will also make it possible to display on the computer screen flows and water consumption of one or more of the parts concerned. Via the microcontroller 101 and the above-mentioned communication means, the operator will be able to know continuously, from the computer 7, in which state (open or closed) each solenoid valve is located, in the various parts that are considered. In case of leakage, or in a preventive manner (for example, if a chamber is unoccupied beyond a certain duration), the operator will thus be able, by means of the data center 7 and from this location, to isolate water pipes by room or group of rooms, closing the solenoid valves. By telephone and / or the Internet, it can also trigger the intervention of a technician for repair or maintenance. It will be understood that between each local module 9 and the central module 23 the communications will be via the sector, by carrier current, or wirelessly, via the zigbee modules. In Figs.5-6, the electrodes of the sensor 5b comprise electrically conductive strands 131a1, 131a2 held on an elongate strip 133 where they are spaced from each other and remain water-sensitive. This band and the stripped wires are flexible to be able to wrap around a water pipe here 16a.

The son are connected to the circuit already shown fig.3 or 4 or connected to a housing 300 (see Figs.5-6) containing the same components as the housing 30 with, then, at least one data transmission means 900a1 specific to transmitting water detection data to the water leak detection and centralized management system of a water network in each room. The electronic unit of the aforementioned sensor 5a may also be associated with the sensor 5b, for retransmission to the central module 23 and relay to the solenoid valves. Thus, the links with the detector 5b can be in particular zigbee or CPL. Favorably, the band 133 will be hydrophilic. Fig-6, the strip is helically wound, as are the spaced apart wires 131a1, 131a2. Thus, if water flows along this pipe, up between the wires 131a1, 131a2, the detection circuit will close and a water presence data will be transmitted by the unit 900a1, this the pipe is horizontal or vertical. The strip is here a sticky tape, glued around the water pipe 16a against which it applies the two electrodes 131a1, 131a2.

Claims (14)

1. Device for detecting water leaks and centralized management of a water network in several rooms (15) of a building, characterized in that it comprises: - in the rooms (15) of the built structure concerned, or even just upstream of these parts: * detection means comprising at least one of. at least one detector (3a) for the presence of out-of-pipe water (3a, 5b), such as for example on the ground in at least some of said rooms of the building or just upstream thereof, the detector (s) ) being associated with first local means (90a1, 900a1) for transmitting data from said detector (s) in connection with a water detection, at least one detector (5a) of flow of water beyond a predetermined flow threshold, in one or more pipes of the at least one part (s) considered, this flow detector being associated with a second means (90a2) local data transmission from this detector in connection with a detection of excessive flow of water, 25 * solenoid valves (19a1, 19a2) placed on at least some of said pipes (16a, 17a) of water parts considered , * electronic cut-off modules (19). o capturing the data transmitted by the detectors, o interacting with a centralized control module (23) to transmit the sensed detection data to it and to receive from it orders of cutoff and opening of the water, via the solenoid valves, and, in a control room (150), centralized computer management means (7) connected to the centralized control module and able to: provide information on a state of the water network in at least some of said rooms as detected by the different detectors, 10 o control each solenoid valve, through said electronic cutoff modules. 2. Device according to claim 1, characterized in that it incorporates three levels of protection against water leakage in said rooms, comprising: - presence detector (s) out of pipes (3a), 20 - detector ( s) of water flow beyond said predetermined flow threshold (5a), in one or more of the pipes, and, - centrally managed computer means (7) which are adapted to control at least some of the solenoid valves , by means of said electronic cutoff modules (9), for a voluntary water cutoff, preventive or not, from the control room via all or part of these solenoid valves. 30 3. Device according to one of the preceding claims, characterized in that the / each detector (5a) of water flow beyond a predetermined flow threshold comprises a low ion flow detector. 4. Device according to one of the preceding claims, characterized in that the / each detector (3a) for the presence of water out of pipes is placed at a short distance above the ground level (4) to detect the water that 'in case of beginning of flood. 5. Device according to one of the preceding claims, characterized in that the / each detector (3a) for presence of water out of pipes and / or detector (5a) of water flow beyond said flow threshold predetermined device comprises a plurality of electrodes (21, 130a1, 130a2) which, in the presence of calcareous water between them, transmit detection data of this water to said first and / or second local data transmission means (90a1, 90a2). 6. Device according to one of the preceding claims, characterized in that it comprises at least two said solenoid valves (19a1, 19a2) for a common cutoff of hot water and cold water in at least some of said parts. 7. A method for detecting water leaks and centralized management of a water network in a plurality of rooms (15) of a building, characterized in that: - the rooms are equipped with solenoid valves (19a1, 19a2) mounted on water pipes of said network and controllable to move from an open state to closed, and vice versa, ^ water detectors (3a, 5a) to detect a leak in at least one water pipe of these parts and / or an abnormal presence of water out of pipelines, and transmit this information remotely, - these water detectors and the solenoid valves are remotely communicated with a central computer (7) which centralizes the data coming from the detectors and can control the change of state of these solenoid valves. 10 8. A method according to claim 7, characterized in that: the solenoid valves (19a1, 19a2) are mounted on the water inlets (16a, 17a) of said parts, and, 15 - in case of leakage or preventatively, and via the central computer (7) is isolated by room or group of parts said pipes, closing the solenoid valves, and / or initiates the intervention of an operator for repair or maintenance. 9. Detector (3a, 5b) for the presence of water outside a pipe, in a room of a building, for the device according to one of claims 1 to 6, characterized in that it comprises several electrodes (21, 130a: 130a2, 131a1, 131a2) belonging to an electrical circuit for detecting the presence of this water, these electrodes acting as a switch, which is open out of the presence of water between the electrodes and 30 is closed in presence of this water. 10. Detector according to claim 9, characterized in that it comprises data transmission means (90a1, 900a1, 90a2) for transmitting water detection data to said water leak detection and management device centralized. 11. Detector according to one of claims 9 or 10, characterized in that it comprises a housing feet (31) under which extend said electrodes (21, 130a1, 130a2), to a level higher than that of the lower limit of these feet, so that, placed on a floor (4) of the room, it allows to detect an early water leak in this room. 12. Detector according to claim 11, characterized in that said electrodes (21, 130a1, 130a2) extend between 0.5 and 20 mm above the ground (4). 13. Detector according to one of claims 9 to 12, characterized in that said electrodes comprise electrically conductive strands (131a1, 131a2) held on an elongated strip (133) where they are spaced from each other and remain sensitive to water. 14. Detector according to claim 13, characterized in that the elongate strip and stripped son are flexible to be able to wrap around a pipe (16a) of water.