DE202014007095U1 - Water leakage device for buildings - Google Patents

Abstract

A fluid leak protector device comprising - a shut-off valve disposed in a central supply line with inlet and outlet ports, a valve port interconnecting inlet and outlet ports, and a shut-off device releasing the valve port in an open position for passage of a medium from inlet to outlet ports; a control unit, which is mechanically connected to the shut-off device and designed to move the position of the shut-off device from the open to the closed position and back, a control unit that is signal-wise connected to the actuator and designed to the Actuator for a movement in the open and closed position to control - a sensor which is signal-wise connected to the control unit and adapted to detect a fluid requirement of a peripheral device and to transmit a fluid request signal to the control unit wherein the control unit is designed to actuate the actuator for movement of the shut-off device into the open position on receipt of the fluid request signal, characterized in that the sensor comprises: a sensor fitting with inlet and outlet opening and a sensor housing, the inlet and outlet An outlet opening connects to each other and defines an axial flow direction, - a rotor with wing sections and a magnetic north and south pole, which is rotatably mounted within the sensor housing, - mounted on the sensor armature magnetic field sensor for detecting a flow of a medium through the valve by detecting the rotor rotation , Wherein the control unit is designed to • upon receipt of a sensor signal from the sensor, which signals a flow, to bring the shut-off valve in an open position via the actuation of the actuator.

Description

The invention relates to a fluid leak protector device comprising a shut-off valve arranged in a central supply line with inlet and outlet ports, a valve channel interconnecting inlet and outlet ports, and a shut-off device which opens the valve port in an open position for passage of a medium from inlet to outlet ports releases and locks in a closed position, an actuator mechanically coupled to the shut-off device and configured to move the position of the shut-off device from the open to the closed position and back, a control unit that is signal-wise connected to the actuator and configured to to drive the actuator for movement to the open and closed positions, a sensor that is signal connected to the control unit and configured to detect a fluid requirement of a peripheral device and a fluid request signal to the Steuerseinh to transmit, wherein the control unit is designed to control the actuator for movement of the shut-off device in the open position upon receipt of the fluid request signal.

A water leak protector device of this type is made DE 10 2009 045 150 B3 known. The so-known water leak protector device serves to avoid water leaks and water damage caused thereby in buildings. It works on the principle that the central water supply is basically shut off by means of the shut-off valve and only in case of need, ie when one of the peripheral lines, which are connected to the central water pipe via a corresponding distributor, water should be removed, this central Closure in the central water pipe is opened. The central shut-off valve can therefore be actuated via an actuator, for example by means of an electromechanical actuation, and can therefore be correspondingly activated via the control unit.

The case of need is detected according to the prior art by motion sensors, which are installed in the respective rooms in which a peripheral water line opens. These motion detectors can detect the presence of a person who enter, for example, a bathroom, a toilet, or a kitchen and are signal technically coupled to the control unit to signal this entering a room with peripheral water collection point. The control unit may then open the shut-off valve in the central water line due to such a signal.

In principle, a high level of safety against water leaks can be achieved with such a water leak protection device. Fundamentally problematic in this case, however, is that not exclusively those peripheral water pipes are connected to the central water, which end at a water tap, which is operated by a person and therefore only perform in the presence of a person a water withdrawal. Instead, for example, in washing machines or dishwashers and a water extraction from the peripheral water pipe may be necessary if no person is present in the room. Out DE 10 2009 045 150 B3 For this purpose, it is known to close the central shut-off valve in certain rooms only after a predetermined period of time has elapsed, after the room has been entered by a person. Hereby, the water requirement by a washing machine or dishwasher, which is in such a room to be satisfactorily enabled. A disadvantage of this solution, however, is that in general, even if the person entering the room has not started the washing machine or dishwasher, an opening of the central shut-off valve will be initiated over a longer period of time, which in turn unnecessarily increases the risk of water leakage. In addition, a significant programming effort is required. Finally, even when the consumer, like a dishwasher, is in a kitchen that also has normal water taps and, moreover, is frequently stepped on, the central shut-off valve is opened for much longer periods of time than would actually be required.

Out WO 2013041699A1 In contrast, a previously improved system is already known. This system uses a sensor that can be coupled to an aquastop valve on a peripheral device and detect the triggering of this aquastop valve. The training makes it possible to generate a concrete sensor message when a water-consuming peripheral device requests water from a peripheral water line, in which the opening of the aqua-stop valve of this peripheral device is detected. Basically, with the thus developed Aqualeckprotektorrrichtung higher security against water damage can be achieved and this peripheral devices such as dishwashers or washing machines are included in the system in a satisfactory manner. The system can still be improved. Thus, the Aquastopp valves are not easily accessible in some water-consuming devices, so that the installation of the sensor is complicated and possibly makes a partial disassembly of the peripheral device necessary. In addition, some peripheral devices are not equipped with an aquastop valve or a functionally similar valve, so detection of an opening operation as a signal for requesting water from such devices is not possible. Especially at In the meantime, ice cube production refrigerators have become more widespread, or with humidifiers connected to the piping network, there is a need for improved control of the central stop valve to ensure the supply of water to such peripherals.

The invention has for its object to provide a fluid leakage protection device which overcomes the aforementioned disadvantages of the prior art and allows reliable integration of water consuming peripherals.

This object is achieved according to the invention by developing a fluid leak protection device of the construction described above such that the sensor comprises: a sensor fitting with inlet and outlet openings and a sensor housing which connects the inlet and outlet openings and defines an axial flow direction, a rotor with wing portions and a magnetic north and south pole, which is rotatably mounted within the sensor housing, a sensor attached to the sensor magnetic field sensor for detecting a flow of a medium through the valve by detecting the rotor rotation, wherein the control unit is adapted to receive a sensor signal from the sensor, which signals a flow to bring the shut-off valve in an open position via the actuation of the actuator.

With the advanced fluid leak protector device according to the invention, a secure detection of a fluid requirement by a peripheral device is made possible in this way. In principle, it should be understood that the fluid leakage protection device according to the invention can be used to protect the water supply network of a building, but gas can also be used as fluid instead of water as fluid, thus securing the gas network of a building with the fluid leakage protection device according to the invention ,

The fluid leakage protection device according to the invention comprises a sensor which is designed as a fitting with rotor arranged therein. The rotor is disposed between an inlet and outlet and rotatably supported, in such a way that when flowing through the valve, from the inlet to the outlet opening of the rotor is rotated. The rotor has a magnetic north and south pole, in particular wings of the rotor can be magnetized or the rotor can be connected to a corresponding magnet, the north and south pole also rotate about the axis of rotation of the rotor at rotor rotation and thereby the rotation of the rotor Rotor allows by means of a magnetic field sensor from outside the flow channel.

The inventive principle is based on the practical knowledge that, although theoretically in the moment in which a peripheral fluid such as water requests and this opens an internal valve, the shut-off valve in the central fluid line is closed, although no fluid can flow, practical but due to elasticities in the conduit network and low compression effects or pressure equalization effects a short minimum flow occurs as soon as a peripheral shut-off valve is opened in a conduit network having a centrally closed shut-off valve. This short-term, low flow can be detected by the sensor according to the invention with rotor due to its high sensitivity. The rotation of the rotor, which possibly only comprises a few revolutions or may comprise only an incomplete revolution, is detected by the magnetic field sensor and forwarded as a small flow within the sensor fitting as a sensor signal to the control unit. The control unit can then open the central shut-off valve via the actuator and thereby enable the operation of the peripheral device with fluid removal. In this case, the fluid flows through the sensor fitting when the sensor fitting is arranged in the connecting line of the peripheral device to the peripheral fluid line. In principle, the sensor fitting can also be arranged as a bypass to the peripheral connection line of the peripheral device and, due to its high sensitivity, also regularly records the short-term flow that occurs when the valve of the peripheral device is opened.

The magnetic field sensor of the sensor designed according to the invention is attached to the sensor fitting. This attachment can be done by means of fastening means outside the sensor housing, or can be done in axial or radial bores, or recesses in the sensor housing. Basically, it should be understood that the magnetic field sensor of such a type should be arranged that it detects the magnetic north and south pole of the rotor and thus can detect the rotation of the rotor.

According to a first preferred embodiment, it is provided that the control unit is designed to bring the shut-off valve into a closed position upon receipt of a sensor signal from the sensor which does not signal a flow, wherein the control unit is preferably configured to actuate it a predetermined period of time after receipt of a sensor signal from the sensor, which signals no flow, via the actuation of the actuator, the shut-off valve in brings a closed position. With this training it is achieved that the central shut-off valve can be closed again, in particular after it has been opened due to a signal of the sensor according to the invention. The control unit can accordingly be designed to perform the closing operation only in response to a preceding opening operation on the basis of the signal of the sensor. In particular, the closing of the central shut-off valve can take place after a predetermined period of time has elapsed. Such a predetermined period of time can be preprogrammed individually into the control unit for each sensor or peripheral connection to which a sensor according to the invention is arranged. By such an individual pre-programming of the predetermined time period, the programs or removal cycles of a peripheral device can be taken into account and it can be avoided that the closing operation of the shut-off valve is triggered, although the peripheral device is still in operation and again requests water in a short time sequence. In principle, however, the closing of the shut-off valve can also take place immediately after no more water flows to the peripheral device, since upon renewed request the sensor would reliably detect this requirement and would cause a reopening of the shut-off valve.

According to a further preferred embodiment, it is provided that the rotor is rotatably mounted about an axially aligned axis, which is aligned parallel to the flow direction of the sensor housing. By such an arrangement of the rotor with an axis of rotation, that is aligned in the flow direction through the valve axis of rotation, a particularly high sensitivity of the rotor is achieved with respect to currents and it can also very short and very low currents are detected.

Furthermore, the fluid leakage protection device according to the invention can be further developed by an inlet stator with inlet stator vanes positioned between rotor and inlet opening, wherein the rotor vanes and the inlet stator vanes have a mutually different orientation with respect to the direction of flow. Such an inlet stator is to be understood as a flow-conducting element arranged statically in the region of the inlet opening or in the region behind the inlet opening; in particular, this element can also have a plurality of individual flow-conducting elements. These flow-conducting elements, ie the inlet stator blades, are differently oriented according to the invention than the rotor blades. It is thereby achieved that a fluid flowing through the inlet port is directed through the inlet stator in a direction different from the orientation of the rotor blades. This causes a direct response of the rotor to a low flow through the inlet opening and increases the sensitivity of the sensor according to the invention.

According to a further preferred embodiment, the fluid leak protector device according to the invention can be developed by means of an outlet stator with outlet stator vanes positioned between rotor and outlet opening, wherein the rotor vanes and the outlet stator vanes have a matching orientation with respect to the direction of flow. Such an outlet stator can basically be designed in the same way as an inlet stator, that is to say have one or more fluid-conducting elements. The outlet stator lies in the outlet opening or in the flow direction in front of the outlet opening and according to the invention has a matching orientation to the rotor. Hereby it is achieved that a flow of a fluid, which enters the valve according to the invention backwards through the outlet opening, is directed through the outlet stator in such a way that the fluid direction coincides with the orientation of the rotor blades. Such a backward flow therefore does not trigger movement of the rotor. By providing such an outlet stator can therefore be achieved that the sensor according to the invention has a directional sensitivity and only generates a sensor signal when a fluid in a certain direction, ie from the inlet to the outlet port, flows through the valve, but not, when the sensor is flowed through in a direction reverse thereto. Such a function is particularly advantageous when the fitting according to the invention is used in a drinking water network and the central shut-off valve also serves to prevent unwanted return of water into the central supply line. In this case, the central shut-off valve must not be opened just when a reverse flow through the sensor occurs.

According to a further preferred embodiment, it is provided that the rotor blades are aligned axially straight and the Einlasstatorflügel have a relative to the axial direction inclined wing portion, in particular curved or axially aligned obliquely. In this development, a fluid flowing through the inlet opening is deflected by the inlet stator of such type that a flow direction in the axial and in the circumferential direction is generated from the purely axially directed flow, ie a flow with a vortex around the longitudinal axis of the valve corresponding flow component. This flow, conducted in this way, meets, according to the invention, a rotor with rotor blades aligned axially straight, and triggers a rotation of this rotor with high sensitivity.

In this case, this embodiment can be further developed by the Auslassstatorflügel are aligned axially straight. Particularly advantageous in this embodiment, the axial straight alignment of the rotor blades, which already in a conventional fluid flow, which enters backwards through the outlet opening, no rotation of the rotor triggers, due to the typically purely axial flow direction. In particular, this can be ensured by the exhaust stator is also designed with straight wings and thus causes an alignment of such a backward flow exactly parallel to the rotor blades. As a result, tangential or radial direction components of the flow caused by line curvatures in the area behind the outlet opening can be eliminated and reliably achieved that the rotor does not rotate in such a reverse flow.

According to a further preferred embodiment, it is provided that the rotor blades have a wing portion inclined relative to the axial direction, in particular curved or axially obliquely aligned and that the inlet stator blades are aligned axially straight. This embodiment is a reversal of the aforementioned preferred orientation principle and operates on the same principle by directing a fluid flowing into the fitting through the inlet port through the inlet stator of such type as to cause rotation of the rotor in which the inlet stator blades are oriented differently the rotor blades. The inlet stator blades are aligned axially straight in this embodiment, so cause no deflection of a flowing in a straight axial direction fluid. The rotor has an inclined or domed wing or vane portion, such that such axially straight flow causes rotor rotation.

In this case, it can be provided, in particular, that the outlet stator blades have a wing section which is inclined relative to the axial direction, in particular curved or axially obliquely aligned. According to this embodiment, the outlet stator is designed such that it aligns a fluid flowing through the outlet opening into the valve, that is, a backward flow, such that it does not cause any rotation of the rotor.

According to a further preferred embodiment, the fluid leakage protection device according to the invention can be developed by a backflow preventer disposed between the rotor and the inlet opening, which blocks a backflow of fluid from the outlet opening to the inlet opening and releases a flow of fluid from the inlet to the outlet opening. Such a non-return valve may be formed in a known manner, for example as a spring-loaded valve that is opened only by a flow in a predetermined direction against the spring force and otherwise closed or by other types of such directionally locking valves, or check valves. The integration of such a non-return valve in the sensor according to the invention provides a functional advantage by allowing a flow through the sensor only in a predetermined direction, namely from the inlet to the outlet, and thus only when such a flow, the sensor emits a flow signal, because the rotor turns. In contrast, a flow directed backwards from the outlet to the inlet opening can not occur in the sensor fitting, so that triggering of the sensor and consequently an opening of the shut-off valve due to such a backward flow can not occur.

According to a further preferred embodiment, the fluid leak protector device is developed by a particle filter arranged between rotor and inlet opening. Such a particle filter, which may be designed, for example, as a close-meshed screen, but possibly also as a magnetic separator, is particularly preferred for a longer trouble-free operation of the sensor according to the invention. Just when a fluid is passed through the sensor, which contains magnetizable or magnetic or iron-containing particles, such a particle filter is advantageous, since this can be a disturbance of operation by addition of such particles to the north or south pole of the sensor can be prevented.

Finally, the fluid leakage protection device according to the invention can be further developed by a rotor housing on which the rotor is rotatably mounted and which is mounted in the sensor housing. Such a rotor housing allows pre-assembly of the rotor assembly or turbine according to the invention and the integration of such a preassembled precision mechanical unit in a robust sensor housing, to thereby construct the sensor according to the invention.

Another aspect of the invention is a fluid leakage protection device for securing a riser in a building against leakage, comprising a control unit with an alarm signal device for optical, acoustic or electronically transmitted alarm signaling, which is characterized by a sensor installed in the riser of the building, the signal technology with the Control unit is connected and adapted to detect a return current through the riser and send return warning signal to the control unit, wherein the control unit is configured to output an audible, visual and / or electronically transmitted warning signal upon receipt of the reverse flow warning signal, and the sensor comprises: a sensor fitting having inlet and outlet ports and a sensor housing interconnecting inlet and outlet ports defining an axial flow direction Rotor having wing portions and a magnetic north and south pole, which is rotatably mounted within the sensor housing, a sensor attached to the sensor magnetic field sensor for detecting a flow of a medium through the valve by detecting the rotor rotation, the sensor is installed in such a way in the riser the flow from the inlet to the outlet corresponds to a vertically downward return flow through the riser.

With the thus formed Fluidleckprotektorvorrichtung a riser can be monitored reliably by the previously described sensor inversely, d. H. with the inlet port connected to the upper portion of the riser and the outlet port to the lower portion of the riser. The sensor can be arranged directly in the riser or in the bypass to the riser. If a leak occurs in the lower section of the riser, the sensor flows from top to bottom, ie from the inlet to the outlet line, causing the rotor to rotate. This can be interpreted as a reliable signal for a leak. From the thus detected leakage, a warning signal can be generated. If necessary, one or more automatically activatable shut-off valves in the riser can be closed or a shut-off valve arranged in the central water line can be closed in order to prevent water damage in the building.

Basically, it should be understood that the fluid leakage protection device can also be used to protect other line sections in a building by the sensor in this line section or - seen in the regular flow direction - downstream of the hedged line section is inserted into the line and thus by a leakage in the Line section can detect conditional return current.

The water leak protector device may be further developed by developing the sensor according to the previously described developments.

Furthermore, the water leak protector device may be formed by disposing a shut-off valve in the riser section which is coupled to an actuator for actuator-actuated opening and closure of the shut-off valve and signal connected to the control unit, wherein the control unit is configured to operate upon receipt of a Sensor signal from the sensor, which signals a return flow through the sensor to control the actuator to close the shut-off valve. By such a check valve, a further leakage of water from the leak can be prevented. It is basically ideal if the shut-off valve is arranged as close as possible to the leakage point. The shut-off valve must be located downstream of the leak to prevent backflow and leakage of water through the leak. For this reason, it is advantageous if a plurality of such shut-off valves are provided spaced apart from each other in longer riser or when securing longer line sections.

When the water leak protector device for securing risers and pipe sections is combined with the previously described fluid leak protector device with shut-off valve in the central supply line, it is advantageous if the control unit is designed to receive a signal from the sensor in the riser section Return current detects activating the actuator of the shut-off valve in the central supply line so that the shut-off valve in the central supply line is closed if it is open and kept closed, if it is closed. Basically, a leak in a riser or a line section in the direction of flow before a riser lead due to the gravitational pressure conditions to water leakage and water damage, even if the shut-off valve is closed in the central supply line. This water damage is amplified when a water supply from the central supply line takes place. Therefore, it is preferable to close the central shut-off valve automatically, or to keep it closed, as long as such leakage exists.

A further aspect of the invention is a method for securing a domestic fluid line system against leaks, comprising the steps of shutting off a central supply line by means of an actuator-operated shut-off valve arranged therein, detecting a fluid requirement at a peripeheria connection by means of a sensor, transmitting a fluid request signal from the sensor to a control unit, Driving the actuator of the shut-off valve to open the shut-off valve by means of the control unit, wherein the Fluidbedatrf is detected by a flow of the fluid is detected by the Peripeherieanschluss by means of a flow sensor having a rotor disposed in the fluid flow.

The inventive method can be developed by the rotation of the rotor by means of detection of magnetic pulses of a magnetic north and south pole, which are formed on the rotor.

Furthermore, the inventive method can be developed by upstream of the rotor in the flow direction, an inlet stator is arranged, which directs a flowing in the flow direction flow such that the rotor is rotated by the guided flow in rotation, and that preferably downstream of the rotor in the flow direction, an outlet is arranged, which directs a flowing counter to the flow direction flow such that the rotor is not rotated by the guided flow in rotation.

The method according to the invention serves to protect a line system within a building against leaks, which may in particular be a water pipe system, but it is also possible to secure a gas line system in a housing by the method according to the invention. In this case, the method according to the invention works according to the principle which was explained above in connection with the fluid leakage protection device. With regard to the method according to the invention and the further developments of this method, reference is made to the above explanations, the advantages, functions and embodiments of the water leak protection device according to the invention.

Another aspect of the invention is a method for securing a riser of a domestic fluid line system against leaks, comprising the steps of detecting a return current in the riser by means of a sensor, transmitting a return current warning signal from the sensor to a control unit, outputting an audible, visual or electronically transmitted warning signal the control unit, characterized in that the sensor is designed as a flow sensor and the return flow is detected by a flow of the fluid through the flow sensor is detected in accordance with a rotation of a rotor disposed in the fluid flow.

With this method, an undesirable leakage of water from a riser of a building or parts thereof, which are above an occurred leak detected, be signaled by a warning signal and, if necessary, be prevented by blocking measures in the riser. The signal can also be used to close an arranged in the central water line shut-off valve and prevent further water leakage.

The method can be developed as described above, wherein the flow direction corresponds to the return flow direction through the riser.

In principle, the method is also suitable for securing horizontally extending line sections within a building, in particular when connecting vertical line sections to such line sections.

The method can be developed by, upon detection of a return flow by means of a control unit, an actuator of a shut-off valve in the riser or the line section is activated to close the shut-off valve.

When the method is combined with the above-described method for securing a house fluid piping against leakage with the step of shutting off a central supply line by means of an actuator-operated shut-off valve disposed therein, it is preferable that upon detecting a return flow by means of a control unit, the actuator of the shut-off valve in the Central supply line is controlled to close the shut-off valve if it is open and to hold the closed state, if it is closed.

A further aspect of the invention is a sensor for detecting a water request signal, comprising a sensor fitting with inlet and outlet openings and a sensor housing which connects inlet and outlet openings and defines an axial flow direction, a rotor with wing sections and a magnetic north and south pole, rotatably mounted within the sensor housing, a magnetic field sensor mounted on the sensor armature for detecting a flow of a medium through the armature by means of rotor rotation detection, an inlet stator positioned between the rotor and inlet opening with inlet stator vanes, the rotor blades and the inlet stator vanes being mutually different in orientation have on the flow direction.

The sensor can be further developed by one of the features of the sensor of the previously discussed fluid leakage protection device.

Another aspect of the invention is the use of such a sensor for detecting fluid demand on a peripheral device connected to a peripeherifluid line connected to a central fluid line shut off by a shut-off valve.

Finally, another aspect of the invention is a use of such a sensor for detecting a return flow in a riser of a building by the sensor is connected in a riser or as a bypass to a riser and the inlet opening of the sensor to a lying above the sensor portion of the riser is connected and the Outlet of the sensor is connected to a lying below the sensor portion of the riser and the sensor is connected to a warning device that receives a return warning signal when detecting a return current from the upper portion to the lower portion by the sensor and an acoustic, optical or electronically transmitted Warning signal outputs.

Preferred embodiments of the invention will be explained with reference to the accompanying figures. Show it:

1 FIG. 2 is a schematic plan view of a building equipped with the water leak protector device according to the invention, FIG.

2 a perspective exploded view of the sensor according to 1 .

3 FIG. 3: a longitudinal section of a sensor of the water leak protection device according to the invention, FIG.

4 FIG. 4: a perspective, longitudinally cutaway view of the sensor according to FIG 1 .

5 : a view of the turbine insert in the sensor according to the invention in a perspective view from the input side,

6 FIG. 2: a view of the turbine insert in the sensor according to the invention in a perspective view from the outlet side, FIG.

7 FIG. 4 is a longitudinal sectional view of a second embodiment of the sensor according to the invention, FIG.

8th FIG. 4 is a longitudinal sectional view of a third embodiment of the sensor according to the invention, FIG.

9 FIG. 3 is a longitudinal sectional view of a fourth embodiment of the sensor according to the invention; and FIG

10 : A longitudinal sectional view of a fifth embodiment of the sensor according to the invention.

Referring first to 1 is a building in the illustrated plan 1 shown a utility room 10 comprising a connection to the public water pipe network. This connection first opens in a water meter 11 , in flow direction behind this water clock 11 is a safety valve 12 arranged.

Also in the utility room is a control electronics unit 13 arranged, which communicates wirelessly with a plurality of motion detectors explained below. The control unit 13 is wired with an actuator 12a coupled, which can operate the safety valve from an open to a closed position and vice versa.

The building also includes a bathroom 20 , a nursery 30 , a guest WC 40 , a bedroom 50 , a living room 60 and a kitchen 70 , In the respective area of a corridor 80 outgoing entrance doors to the bathroom 20 , the guest toilet 40 and the kitchen 70 is in each case a motion detector 21 . 41 . 71 arranged. This motion detector detects the entry of a person into the respective room and the presence of a person in the respective room.

Every motion detector 21 . 41 . 71 communicates wirelessly with the control electronics unit 13 in the utility room and reports the entry or the presence of a person in the respective monitored room. If such a message from the control electronics unit 13 received, so this actuates the actuator 12a to the safety valve 12 to open.

In this case, the control electronics unit is programmed such that it receives a presence signal from the motion detectors 21 and 41 keep the safety valve open as long as the person stays in the respective room and immediately closes the safety valve as soon as the motion detector does not detect the presence of a person in the bathroom 20 or guest WC 40 more reports.

Will the presence of a person in the kitchen 70 through the motion detector 71 reported, the control unit continues to ask wirelessly communicating electronic modules 72 . 73 off, which signal the operation of a dishwasher and a washing machine. Is through these electronic modules 72 . 73 reported to the control electronics unit the run of one or both devices, the control electronics unit keeps the safety valve for the duration of this run open and closes it only after the device has finished its flushing or washing process. Alternatively or in addition to the direct query of the electronic modules 72 . 73 is a Aquastopventil, which is inserted into the water supply to the sink or washing machine, scanned by a sensor. The sensor comprises a magnetic field sensor, which detects an actuation of the electromagnet of the aqua-stop valve and transmits it as a signal by means of a radio transmission to the control unit. The signal is amplified, low-pass filtered and a control signal rectified, in order to achieve a control of the shut-off valve.

In the kitchen 70 is still a refrigerator 80 It is connected to the domestic water network and removes water from the domestic water network at intervals for ice cube production and for providing cooled drinking water. The refrigerator 80 is connected to the domestic water network via a peripheral connection line. In this peripheral connection line is a flow sensor 81 used.

2 - 6 show the basic structure of a sensor according to the invention for flow measurement of peripheral devices. The sensor basically comprises a sensor housing 110 on which a magnetic field sensor, here executes as a Hall sensor 120 is attached. The fastening of the Hall sensor 120 done by means of two screws 121 . 122 formed in two threaded holes in a plane circumferential surface 111 of the sensor housing can be screwed.

The sensor housing defines an inlet opening 112 and an outlet opening 114 , In the area of the inlet opening is an external thread 113 arranged, in the region of the outlet opening is a corresponding external thread 115 arranged, both external threads are coaxial with the central longitudinal axis 100 of the sensor housing 110 and serve to be able to connect the sensor housing in a fluid-tight manner to a water pipe or a water fitting.

In the sensor housing a turbine insert is arranged, which consists in principle of three components. The turbine insert 130 includes an inlet stator 140 , a rotor 150 and an outlet stator 160 , The rotor is by means of two bearing pins 151 . 152 rotatably mounted in corresponding bearing receptacles in the inlet stator housing and in the outlet stator housing. This rotatable bearing is coaxial about the axis 100 educated. The longitudinal axis 100 also corresponds to the flow direction through the sensor housing.

The rotor 150 is between inlet stator 140 and outlet stator 160 arranged. The inlet stator therefore lies between the inlet opening 112 and the rotor 150 , the outlet stator 160 lies between the rotor 150 and the outlet opening 114 ,

The inlet stator has a total of five inlet stator blades 140a -E on. Each inlet stator wing 140a E has an initially axially straight wing section 141 on, by a subsequent flush wing section 142a followed. This second wing section 142a is axially obliquely arranged in a sense of an axial direction of inclination in such a way that the second wing portion 142a comprising a circumferentially oriented directional component. Due to this orientation of the inlet stator blades 140a -E, water entering through the inlet opening and impinging on the inlet stator in an axially directed flow from the inlet opening is deflected in such a way that a circumferential flow component is present behind the inlet stator.

The rotor 150 has a total of four rotor blades 150a -D up. The rotor blades are aligned axially straight.

The inlet stator is fixed to a turbine housing 170 Connected by placing each inlet stator blade on the outer circumference fixed to the inner wall of the turbine housing 170 connected is. At its radially inward end are the inlet stator vanes with a cylindrical tube section 145 connected, as a bearing receptacle for the bearing journal 151 of the rotor 150 serves.

The rotor is by means of the bearing pin 151 in the pipe section 145 the inlet stator housing rotatable about the longitudinal axis 100 stored, at the opposite end of the rotor 150 by means of the bearing pin 152 in a mirror-symmetrically matching pipe section 165 the Auslassstators rotatably mounted. As a result, the rotor has a very easy-to-rotate, rotatable bearing which is set to rotate only briefly for flow from the inlet opening through the inlet stator.

The outlet stator 160 has four exhaust fan blades 160a -D, which are aligned axially straight. The Auslassstatorflügel are therefore in the same direction in the flow direction to the rotor blades 150a d. The exhaust stator blades, like the inlet stator blades, are fixed to the turbine housing at their outer end 170 connected and at its radially inwardly directed end fixed to the pipe section 165 connected, which the journal 152 of the rotor.

The rotor 150 is made of a ferromagnetic material and magnetized in such a way that the opposing rotor blades 150a and 150c both a north pole and the wings opposite each other 150b and 150d both form a south pole. As a result, upon rotation of the rotor alternately a north and a south pole to the Hall sensor 120 passed and detected a total of four poles per revolution. This allows a sensitive detection of the rotation of the rotor and possibly also the rotational speed of the rotor. Basically, it should be understood that a different number of rotor blades may be formed and / or another type of Training and arrangement of North and South Pole. For example, a rotor with only two opposing rotor blades can be used, one of which forms a north pole and the other a south pole. Likewise, for example, three-bladed rotors can be used, with two of these rotors then form the north and south poles.

This magnetic north and south pole can through the Hall sensor 120 be recorded. The Hall sensor 120 is by means of sensor cables 123 connected to a control unit, if necessary, the sensor 120 by means of the sensor cable 123 also be connected to a wireless transmission station to send sensor signals to a control unit.

7 shows a second embodiment of the sensor according to the invention. In this second embodiment, as in the first embodiment, a rotor 250 in a turbine housing 270 rotatable about a longitudinal axis 200 , which is the flow direction of a sensor housing 210 with an inlet opening 212 and an outlet opening 214 corresponds, stored. In the embodiment according to 7 however, neither an inlet stator nor an outlet stator is provided. Instead, it is a backflow preventer 280 between the inlet opening 212 and the rotor 250 arranged in the flow path. This backflow preventer is designed as a spring-loaded check valve and leaves water only in the direction of flow from the inlet opening 212 to the outlet opening 214 therethrough. The rotor 250 is designed with curved or axially obliquely oriented rotor blades and is driven by water flowing through the rotor housing 210 flows through it, set in rotation. This rotation is, as in the first embodiment, detected by a Hall sensor, detects the magnetic north and south pole running rotor blades of the rotor. The Hall sensor is in a tangentially aligned bore 216 in the sensor housing 210 used.

The embodiment according to 7 also has a particle filter 290 in the area of the inlet opening, ie upstream of the non-return valve 280 , is arranged. This particle filter 290 serves to retain particles and prevent such particles from attaching to the rotor and hindering its function.

8th shows a third embodiment of the invention, which are in principle coincident to 7 is constructed. In this embodiment, a rotor 350 in a plastic housing 370 rotatably mounted, the plastic housing 370 is in the sensor housing 310 firmly anchored.

9 shows a fourth embodiment of the sensor according to the invention, which in principle coincides with the embodiment according to 8th is. Here again becomes a turbine housing 470 with rotatably mounted rotor (not shown) disposed therein. The embodiment according to 8th differs from the embodiment according to 7 in that the Hall sensor in this embodiment in a substantially axially aligned bore 416 in the sensor housing 410 is arranged.

10 shows a fifth embodiment of the sensor according to the invention. In this fifth embodiment, the entire unit of the rotor and the Hall sensor is a plastic component 570 trained and the Hall sensor 520 is integrated in this plastic component. The plastic component 570 has an inlet-side external thread 571 and an outlet-side external thread 572 on, which serve to be connected to inlet-side and outlet-side valve sections, in order to connect the sensor housing to the inlet and outlet pipes or fittings can.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009045150 B3 [0002, 0004]
• WO 2013041699 A1 [0005]

Claims (20)

A fluid leak protector device comprising - a shut-off valve disposed in a central supply line with inlet and outlet ports, a valve port interconnecting inlet and outlet ports, and a shut-off device releasing the valve port in an open position for passage of a medium from inlet to outlet ports; a control unit, which is mechanically connected to the shut-off device and designed to move the position of the shut-off device from the open to the closed position and back, a control unit that is signal-wise connected to the actuator and designed to the Actuator for a movement in the open and the closed position to control - a sensor which is signal-wise connected to the control unit and adapted to detect a fluid requirement of a peripheral device and to transmit a fluid request signal to the control unit wherein the control unit is designed to actuate the actuator for movement of the shut-off device into the open position on receipt of the fluid request signal, characterized in that the sensor comprises: a sensor fitting with inlet and outlet opening and a sensor housing, the inlet and outlet An outlet opening connects with each other and defines an axial flow direction, a rotor with wing sections and a magnetic north and south pole, which is rotatably mounted within the sensor housing, a sensor attached to the sensor magnetic field sensor for detecting a flow of a medium through the valve by detecting the rotor rotation , Wherein the control unit is designed to • on receipt of a sensor signal from the sensor, which signals a flow, to bring the shut-off valve in an open position via the actuation of the actuator. Fluid leakage protection device according to claim 1, characterized in that the control unit is designed to bring on receiving a sensor signal from the sensor, which does not signal flow, via the actuation of the actuator, the shut-off valve in a closed position, wherein preferably the control unit is formed that they a predetermined period of time after receipt of a sensor signal from the sensor, which signals no flow, via the control of the actuator brings the shut-off valve in a closed position. Fluid leak protection device according to claim 1 or 2, characterized in that the rotor is rotatably mounted about an axially aligned axis which is aligned parallel to the flow direction of the sensor housing. Fluid leakage protection device according to one of the preceding claims, characterized by an inlet stator positioned between the rotor and inlet opening with inlet stator blades, the rotor blades and the inlet stator blades having a mutually different orientation with respect to the direction of flow. Fluid leakage protection device according to one of the preceding claims, characterized by an outlet stator positioned between the rotor and the outlet opening with outlet stator blades, the rotor blades and the outlet stator blades having a matching orientation with respect to the flow direction. Fluid leakage protection device according to claim 4 or 5, characterized in that the rotor blades are aligned axially straight and the Einlasstatorflügel have a relative to the axial direction inclined wing portion, in particular curved or axially aligned obliquely. Fluid leakage protection device according to claims 4-6, characterized in that the outlet stator blades are aligned axially straight. Fluid leakage protection device according to claim 4 or 5, characterized in that the rotor blades have a relative to the axial direction inclined wing portion, in particular curved or axially obliquely aligned and that the inlet stator blades are aligned axially straight. Fluid leakage protection device according to claims 4, 5 and 8, characterized in that the Auslassstatorflügel have a relative to the axial direction inclined wing sections, in particular curved or axially aligned obliquely. A fluid leak protector device according to any one of the preceding claims, characterized by a backflow preventer disposed between the rotor and the inlet port which blocks backflow of fluid from the outlet port to the inlet port and releases a flow of fluid from the inlet port to the outlet port. Fluid leak protection device according to one of the preceding claims, characterized by a arranged between the rotor and the inlet opening particulate filter. Fluid leakage protection device according to one of the preceding claims, characterized by a Rotor housing on which the rotor is rotatably mounted and which is fixed in the sensor housing. A fluid leak protector device for securing a riser or conduit section in a building against leakage A control unit with an alarm signal device for optical, acoustic or electronically transmitted alarm signaling, marked by A sensor installed in the riser or conduit section of the building, which is signal connected to the control unit and configured to detect a return flow through the riser or line section and to send the return flow warning signal to the control unit, Wherein the control unit is designed to output an audible, visual and / or electronically transmitted warning signal upon receipt of the reverse-flow warning signal, and the sensor comprises: A sensor fitting with inlet and outlet openings and a sensor housing which connects the inlet and outlet openings and defines an axial flow direction, A rotor with wing sections and a magnetic north and south pole, which is rotatably mounted within the sensor housing, A magnetic field sensor attached to the sensor armature for detecting a flow of a medium through the armature by means of detection of the rotor rotation, - The sensor is installed in such a way in the riser that the flow from the inlet to the outlet port corresponds to a vertically downward return flow through the riser. Fluid leakage protection device according to claim 13, characterized by one of the features of the sensor of the fluid leakage protection device according to one of the preceding claims 2-12. A fluid leak protector according to claim 13 or 14, characterized by a shut-off valve in the riser or conduit section coupled to an actuator for actuator-actuated opening and closing of the shut-off valve and signal connected to the control unit, the control unit being adapted to receive a sensor signal from the sensor, which signals a return flow through the sensor, to control the actuator to close the shut-off valve. The fluid leak protector device according to claim 1 and any one of claims 13 to 15, characterized in that the control unit is adapted to receive the actuator of the shut-off valve in the central supply line so as to receive a signal from the sensor in the riser or conduit section which detects a return flow to control that the shut-off valve in the central supply line is closed if it is open and kept closed, if it is closed. A sensor for detecting a water request signal, comprising: A sensor fitting with inlet and outlet openings and a sensor housing which connects the inlet and outlet openings and defines an axial flow direction, A rotor with wing sections and a magnetic north and south pole, which is rotatably mounted within the sensor housing, A magnetic field sensor attached to the sensor armature for detecting a flow of a medium through the armature by means of detection of the rotor rotation, An inlet stator with inlet stator blades positioned between the rotor and the inlet opening, wherein the rotor blades and the inlet stator blades have a mutually different orientation with respect to the direction of flow. Sensor according to claim 17, characterized by one of the features of the sensor of the fluid leakage protection device according to one of the preceding claims 2-12. Use of a sensor according to claim 17 or 18 for detecting a fluid requirement on a peripheral device connected to a peripheral fluid line connected to a central fluid line shut off by a shut-off valve. Use of a sensor according to claim 17 or 18 for detecting a return flow in a riser of a building by the sensor is connected in a riser or as a bypass to a riser and the inlet opening of the sensor is connected to a lying above the sensor portion of the riser and the Outlet opening of the sensor is connected to a lying below the sensor portion of the riser and the sensor is connected to a warning device which receives a return warning signal upon detection of a return current from the upper portion to the lower portion by the sensor and an acoustic, optical or electronically transmitted Warning signal outputs.

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