DE4324512A1 - Non contact operable sanitary system - uses output of radar movement detector to control mode of operation of system automatically - Google Patents

Abstract

The system has at least one fitting (5) through which water can be supplied to the apparatus, and a system (15) for controlling the operation of the system. The system also has at least one radar movement sensor (10) which determines the control of the operation. The sensor is preferably protected from the water, e.g. by an opaque plate which allows microwaves to pass through it. More than one detector can be provided to control different functions of the system. USE/ADVANTAGE - For e.g. automatic flush wc. Controls and-or varies quantity of water flowing without touch control. Ultrasound or microwave beam used instead of light beam, providing more reliable presence detection.

Description

The present invention relates to a contactless actuation bare sanitary facility with at least one fitting, through which che water of the device can be supplied, and with a Arrangement for controlling the operation of this device.

Facilities of this type are already known. Most of the time At least one of these devices is an optical beam for the detection of people and for contactless control of the sanitary facility. The optical beam is very narrow and therefore the spatial area of such a De tector by identifying people or their body parts can, very narrowly limited. There are also problems with the Changing the brightness in the rooms of the sanitary facility conditions, any reflections, etc. There are also situations in which the optical detection of a person is hardly possible. Here, for example, water closets can be pointed out.

It is also common, e.g. B. Ultrasound instead of light beam to use. All these known means are common sam that they allow or stop the flow of water but that they are unable to control the amount of through flowing water to change or control.

The object of the present invention is this and still white Eliminate other disadvantages of the prior art.

This task is mentioned when setting up the above Genus according to the invention solved as in the characterizing Part of claim 1 is defined.

The following are possible implementations of the present Set up with reference to the accompanying drawings tert. It shows:

Fig. 1 shows schematically and in a side view from a first execution possibility of the present invention,

Fig. 2 shows schematically and in a side view from a second guide possibility of the present invention,

Fig. 3 shows in perspective a device in which the motion detector is embedded in the base of the water outlet,

Fig. 4 shows in perspective a device which comprises more than one movement sensor,

Fig. 5 is a side view and partly in longitudinal section a device which is similar to the device shown in Fig. 1 and which has very against these three motion detector,

Fig. 6 in a front view of a device which also has more than one motion detector, the body of the sink has a curved bottom, Fig. 7 and 8 in a side view and in a front view of a device with several detectors, two of which are attached to the wall,

Fig. 9 is a side view of a device, that space is inserted in the one of the motion in the ground, in which the device is located,

FIGS. 10 and 11 the application of the motion detector in a shower installation,

FIGS. 12 and 13 the application of the motion detector on a toilet.

Fig. 1 shows schematically and in a side view a first embodiment of the present sanitary facility. The sanitary device shown comprises a wash basin 1 of a type known per se, which is attached to a wall 2 , also in a manner known per se. This sanitary device further comprises a fitting 5 , namely a water outlet, which or which is connected to a water supply line (not shown). The tap 5 is assigned to the sink 1 in such a way that water can get into the sink 1 through it. The sink 1 is connected via a drain 3 to a drain line which leads into the sewer system.

The present sanitary device also includes a radar motion detector 10 which is intended to control the operation of the present device. This radar motion detector 10 can, for. B. be one of the products of the company Reglomat AG, in St. Gallen / Switzerland. Such a motion detector has a microwave module 11 and an antenna 12 . The module 11 is designed such that it can generate, transmit and receive radar or microwaves and that it can also evaluate the signal received thereafter. Radar or microwaves are electromagnetic vibrations with a frequency that is greater than 1 GHz. The operation of the radar motion detector is based on the Doppler effect. An absolutely stationary body does not have a Doppler effect. Consequently, only moving objects, ie people, parts of the same, objects, etc. are detected by a radar motion detector. However, the principle mentioned offers the possibility of also determining the speed of the moving object. The device based on this principle can therefore also emit a signal relating to this. In the present case, the aforementioned property of the motion detector enables metering of the water flowing out of the water outlet 5 . This will be described in more detail below.

The waves generated by the microwave module 11 are punched or also with the aid of the antenna 12 without the antenna gebün directed and emitted as a cone 21st The waves reflected by the object are again received by the antenna 12 and fed to the microwave module 11 for processing. The signals processed by the microwave module 11 are supplied via a line 16 as an input signal to an arrangement 15 which, on the basis of the signals received, controls the operation of further parts of the present device, for example the water outlet 5 , via a line 17 . The water outlet 5 has a valve 6 , which is designed such that it can be actuated by electrical signals. The line 17 continuing from the arrangement 15 is connected to this valve 6 .

The radar motion detector 10 is arranged at a point at which it is protected from the action of water, in particular water splashes. This protection of the motion detector 10 can be achieved, for example, by being embedded in a wall. This can be, for example, that wall 2 to which the wash basin 1 is attached. For the stated purpose, a niche 13 can be implemented in the wall 2 . The dimensions of the interior of such a niche 13 should be considerably larger than the dimensions of the motion detector 10 . Because it should be possible to direct the motion detector 10 so that the microwave beam or beam cone 21 can propagate in the direction required to carry out the desired function. In order to give the necessary direction to the motion detector, an adjustable stand 14 is provided. This is set up in the niche 13 and has a foot on which a holder for the motion detector 10 is pivotally attached.

The actual protection of the motion detector 10 against water or water splashes is achieved in that the radar motion detector 10 is preceded by a plate-like member 9 . This link or cover 9 is made of a material that is permeable to microwaves. One of these materials is ceramic, for example. The cover plate 9 can therefore be a ceramic tile. This can be one of the tiles with which the entire wall 2 is covered, to which the wash basin 1 is attached. Since the motion detector 10 is generally smaller than the dimensions of a common tile, a single tile can cover the mouth of the recess 13 .

The ceramic material of the cover 9 is normally opaque. If a light body (not shown) is embedded in the wall 2 , then the cover of such a niche 13 must be transparent or at least translucent. If the cover 9 is made of a material that is permeable to the microwaves, then the motion detector 10 can be located in such a niche together with the lighting fixture. If the cover 9 of the niche 13 is made of glass or plastic, then the motion detector 10 can be accommodated in this niche 13 without white teres. However, as said, the material of the cover 9 can also be opaque or opaque.

Referring to FIG. 1 there is the recess 13 for receiving the Be wegungsmelders 10 above the valve. 5 The motion detector 10 located in this niche 13 must be set so that its microwave beam 21 reaches the area where the hands or the like of a user of the wash basin 1 will move. In this case, the beam 21 is directed obliquely downwards.

The water outlet 5 shown in FIG. 1 has a housing 25 which is practically cylindrical. It is understood that the water outlet 5 can also have a different shape. A tube 26 extends through the interior of the housing 25 . The end of the tube 26 lying outside the housing 25 is connected to the water supply line already mentioned. The other end of the tube 26 is connected to an outflow nozzle 27 . The shape of the water jet emerging from the outflow nozzle 27 can be changed with the aid of a device known per se, which is located inside the nozzle 27 . This device has a lever 28 which protrudes from the outflow nozzle 27 and by means of which the shape of the water jet can be changed by hand. The outlet nozzle 27 is connected upstream of the valve 6 already mentioned in the tube 26 . This is designed so that it can not only release or block the flow of water through the water outlet, but that it can also determine the amount of water flowing through. This type of remotely operable valves is known. The regulation of the flow rate is based on the already mentioned fact that the motion detector 10 can also determine the speed of the targeted object. For example, the faster you move your hands in the sink, for example by rubbing, the more water will flow out of the water outlet 5 . The corresponding signal is obtained in the effective area 22 of the motion detector 10 , this effective area 22 being located in the interior of the wash basin 1 in the present case.

A section 30 of the tube 26 , which is located inside the housing 25 , has an enlarged diameter. Inside this expanded pipe section 30 there is a rotatably mounted, rotatable body 31 , which can be put into rotation under the action of the water flowing past it. This body 31 can be designed like a turbine wheel and it is coupled to a generator of electrical energy (not shown). The output signal of the electrical generator is fed into a line 32 which leads to the arrangement 15 .

The signal delivered by the turbine wheel 31 or the generator can be used, for example, in such a way that the line 32 is connected to an energy store. This energy storage (not shown) can be a battery or a capacitor. These components can be accommodated in the arrangement 15 . The energy obtained during the flow of water through the pipe 26 in the water outlet 5 with the help of the Turbinenra of the 31 is fed via line 32 to the energy store. The movement detector 10 and the circuitry in the arrangement 15 can then be supplied with energy from this memory. This type of energy generation works with all water applications disclosed here. The embodiment of the present device just described can be used expediently when it is cumbersome or even impossible to supply this device with energy from the network. This impossibility is often coupled with a lack of water, so that valuable water can be saved by the present device.

Another possibility for the exploitation of the output signal from the turbine 31 or from the electrical generator connected to it is that a circuit is present in the arrangement 15 which is designed and designed to monitor the flow of water through the water outlet 5 . The output signal of the generator is fed to this circuit arrangement. This circuit arrangement can be used to check whether the valve 6 in the water outlet 5 is tight, and / or the amount of water flowing through the water outlet 5 can be measured. In this scarf arrangement, the amount of speed of the rotating body 31 is thus evaluated and the output of this evaluation circuit is used to monitor the operation in the fitting 5 .

The arrangement 15 can for example be designed as a house control center, in which other signals or data are also fed ge. Based on these signals, the house control center can, under certain circumstances, even initiate and carry out corresponding and necessary operations automatically. In the present case, for example, it will issue a message as soon as the monitored water outlet 5 leaks.

Fig. 2 shows a second embodiment of the present device. This embodiment differs from the embodiment described above essentially in that the motion detector 10 is housed in the Ar maturity or in the water outlet 35 itself. The motion detector 10 is only indicated schematically in FIG. 2.

The water outlet 35 has a housing 36 . The dimensions of this housing 36 are selected such that, among other things, the motion detector 10 can also be accommodated therein. To take on the motion detector 10 , a cavity 37 is made in the material of the housing 36 . The shape of this cavity 37 is selected so that the beam cone 21 generated by the motion detector 10 has the desired direction. In the illustrated case, the cavity 37 is located in the upper region of the housing 36 . In such a case, at least the housing 36 should be made of a material which is permeable to microwaves.

The motion detector 10 is connected to the control arrangement 15 ( FIG. 1) via the already described device 16 . A channel 38 is formed in the housing 36 , through which water can reach the wash basin 1 . In the channel 6 , a Ven valve 6 is arranged, by means of which the flow of water through the water outlet 35 can be controlled. This valve 6 is connected via line 17 to one of the outputs of the control arrangement 15 . The channel 38 has the already described section 30 with an enlarged cross-section, in which the impeller 31 is located. The generator of electrical energy connected to this impeller 31 is connected to the control arrangement 15 via the line 32 .

In the initial region of the channel 38 , a piece of pipe 39 connects to the relevant side wall of the housing 36 . This pipe piece 39 is provided with a thread, by means of which the water outlet 35 is connected to the water supply line 40 . A spout 41 protrudes from the housing 36 from the opposite side surface of the housing 36 and in the extension of the channel 38 , which represents a continuation of the channel 38 . The operation of this embodiment of the present device is essentially the same as the operation of the device according to FIG. 1.

Fig. 3 shows in perspective a further possible embodiment of the present device. In that area of the washbasin 1 , above which the washbasin 1 can be connected to a wall, a bench 42 is formed, on which soap, among other things, is normally also deposited. A base 43 is arranged on the bench 42 in the central region of this bench 42 . The water outlet 5 is rotatably embedded in this base 43 . In Be rich that wall of the base 43 , which faces the interior of the wash basin, a cavity in the base 43 is ausgebil det, in which the motion detector 10 is inserted. The front mouth of this cavity can be completed with the already described plate-shaped member so that the motion detector 10 is protected against water. The motion detector 10 is arranged in the cavity so that the beam cone 22 generated by it is directed into that portion of the interior of the washbasin 1 where the user's hands normally move while using this device. The operation of the water outlet 5 is controlled in the manner already described.

A further sanitary device is shown in perspective in FIG. 4. The wash basin 1 together with the water outlet 5 is practically of the same design as in FIG. 4. In this case, no motion detector is inserted in the base 43 . For this purpose, this device has three motion detectors 10 , 18 and 19 . These are arranged at three different locations in the facility. The beam cones 21 , 33 and 34 of these motion detectors 10 , 18 and 19 are directed into the interior of the wash basin 1 . The first motion detector 10 is at the 5 gegenüberlie constricting wall 51 disposed to the water outlet of the washbasin. 1 One of the remaining motion detectors 18 and 19 is attached to one of the side walls 52 and 53 of the sink 1 . If the sink 1 is made of a ceramic material and if this basin 1 has a simple wall, the loading motion detectors 10 , 18 and 19 can be attached to the outside of the basin body. The motion detectors 10 , 18 and 19 are connected to the control arrangement 15 via separate lines.

The use of several motion detectors offers the possibility to control the device depending on several parameters. In the case just outlined, the water outlet 5 can also contain a mixer tap for cold and hot water in addition to the valve 6 . The first detector 10 is responsible for controlling the size of the flow of water through the tap 5 and therefore controls the valve 6 via the control arrangement 15 . This is arranged in the spout 41 of the water outlet 5 or it is connected upstream. Each one of the remaining motion detectors 18 and 19 controls via the control arrangement 15 a valve (not shown), which are located in the supply lines for hot and cold water. If the water running out of the river 5 is supposed to be colder, then one moves the hands to the left, for example. If the water is supposed to be hotter, you move your hands to the right.

If the pelvic body is double-walled, the motion detectors 10 , 18 and 19 can be arranged between the walls of the pelvic body. Since it can be cumbersome to mount the first movement detector 10 so far away from the rear wall of the pelvic body, the device according to FIG. 3 can be provided with the second and third motion detectors 18 and 19 , which have been explained in connection with FIG. 4 .

Fig. 5 shows a side view and partially in longitudinal section of a device which is very similar to the one shown in Fig. 1 direction. The main difference between the sen is that the radar motion detector 10 is arranged in the device of FIG. 5 in the head of the water outlet 5 . The water leakage detector 10 is arranged on the underside of the head so that the beam cone 21 can be easily directed into the area in which the hands of the user are normally located.

Fig. 6 shows a front view of a device which also comprises more than one movement sensor, wherein the body of the sink 1 has a curved bottom. The first motion detector 10 is arranged in this device on the underside of the head of the water outlet 5 , as shown in Fig. 5. Of the remaining two motion detectors 18 and 19 , one is attached to the left or right of the water drain 3 on the underside of the wash basin 1 . These motion detectors 18 and 19 are arranged so that the beam cones 33 and 34 thereof are directed obliquely upwards in the middle. However, the operation of such motion detectors is practically the same as that of the detectors in the device according to FIG. 4.

FIGS. 7 and 8 show a further device having a plurality Be motion detectors. The first motion detector 10 is, similar to the device according to FIG. 5, attached to the head of the water outlet 5 and directed towards the bottom. The remaining two motion detectors 18 and 19 are placed on or in the wall 2 , to which the sink 1 is attached. The attachment of the remaining two detectors 18 and 19 can be carried out in the same way as is the case with detector 10 according to FIG. 1.

Fig. 9 shows a side view of a device in which the first motion detector 10 is in the floor 53 of the room in which the device is located. According to FIGS. 10 and 11, the present device is designed as a shower system. FIG. 10 shows this device in a side view and FIG. 11 shows this device in a front view. On one of the walls 2 of the shower room, the water outlet 5 is attached, which is preceded by a mixing device 55 . This is left in the wall 2 waterproof and it includes the control arrangement 15 and a mixer tap for cold and hot water. The Mischvorrich device is also equipped with manually operable taps 56 , so that alternatively a hand-guided operation of the device is possible. Motion detectors are connected to the control arrangement in the manner already described. The first motion detector 10 is embedded in the floor 53 where the showering person is normally and his beam cone 21 is directed upwards. This motion detector 10 opens and closes the water outlet 5 . The second Bewegungsmel of 18 is approximately at the level of the shoulders and its cone of rays 33 is directed practically perpendicular to the wall 2 . The third motion detector 19 is arranged approximately at the height of the upper leg and its beam cone 34 is directed obliquely against the bottom 53 .

FIGS. 12 and 13 shows the application of the motion detector on a toilet. According to Fig. 12 showing a toilet device in a front view, two motion detectors 18 and 19 are used, which are attached to the toilet bowl 54th These are brought to the bowl 54 practically in the same way as has been explained in connection with FIG. 6.

Fig. 13 shows a toilet device in a side view. In this case, all three motion detectors 10 , 18 and 19 are used. The first motion detector 10 is embedded in the wall 2 in the manner already described. The second movement detector 18 is in the rear section of the bowl 53 and the third motion detector 19 is arranged in the front section of the bowl 53 . The beam cones 33 and 34 of these two last-mentioned motion detectors 18 and 19 lie in the longitudinal direction of the bowl 53 and they also intersect.

The radar motion detectors can also be attached to other types of sanitary facilities. Fig. 14 shows the application of a motion detector 10 to a hand dryer 58th The movement detector 10 is arranged on the underside of the housing of the hand dryer 58 and it is set so that its beam cone 21 points in the direction where the user's hands normally move during the operation of the dryer 58 .

In the apparatus of FIG. 15, a motion detector 10 is attached to the soap dispenser 59th In this case too, the motion detector 10 is arranged on the underside of the housing of the soap dispenser 59 and it is set so that its beam cone 21 points in the direction where the hands of the user normally move during the operation of the soap dispenser 58 .

Referring to FIG. 16 and 17 motion detectors are attached to a towel dispenser 60th Fig. 16 shows the dispenser 60 by hand towel 61 in a front view. The motion detectors 18 and 19 are arranged left and right of the towel rail 61 in the lower region of the housing of the dispenser 60 . The motion detectors 18 and 19 are directed so that their beam cones 33 and 34 are divergent. Fig. 17 shows the towel dispenser 60 in a side view. In addition to the aforementioned motion detectors 18 and 19 , the first motion detector 10 is also used, which is embedded in the floor 53 , as has already been described before.

Claims (7)

1. Non-contact operated sanitary device with at least one fitting through which water can be supplied to the device, and with an arrangement for controlling the working of this device, characterized in that the device has at least one radar motion detector, which cher to control the Operation of the facility is determined. 2. Sanitary device according to claim 1, characterized in that the radar motion detector is arranged in one place where it is protected from water. 3. Sanitary device according to claim 2, characterized in that the radar motion detector in front of a plate-like member is switched, which protects it from the effects of water and which is made of a material that is permeable to microwaves is, this material being opaque or opaque can be. 4. Sanitary device according to claim 1, characterized in that at least two radar motion detectors are provided that these are in the effective range of the device and that  these detectors to control more than one function of the one direction are determined. 5. Sanitary device according to claim 1, characterized in that there is a rotating body in the valve, which by the medium flowing through the valve is drivable that the Rotating body Kopop with a generator of electrical energy pelt, and that the rotating body is advantageously a turbine wheel is. 6. Sanitary device according to claim 5, characterized in that the output of the generator to an energy storage source is connected and that the control arrangement of the device device is connected to this energy storage source. 7. Sanitary device according to claim 5, characterized in that the output of the generator on a circuit arrangement connected, which is the amount of speed of the rotating body and thus also evaluate the size of the water flow rate can, and that the output of this evaluation circuit for Monitoring the operation of the valve is used.