DE102013100078A1 - Sanitary fitting for e.g. washstand, has two generators that are designed as thermal generator, solar cell, photo diode, turbine, piezoelectric energy harvester, radio frequency energy harvester or sound energy harvester - Google Patents

Abstract

The sanitary fitting (1) has main portion that is operated in two operating modes and is provided with a sensor (10), an electronic circuit unit (12), a trip device (8) and two generators. The generators are designed as a thermal generator (13), a solar cell, a photo diode, a turbine, a piezoelectric energy harvester, a radio frequency energy harvester or a sound energy harvester.

Description

The invention relates to a sanitary fitting with at least two operating modes, an optoelectronic sensor, a power supply and method for energy-efficient, non-contact and automatic triggering of flowing through a sanitary fitting water, especially for washbasin and kitchen fittings, showers, bidets, urinals and toilets.

Fittings of the type mentioned usually include an optoelectronic sensor device for contactless detection of an object, such as the hand of a user or a person who is in front of the fitting, and an electronic circuit unit for controlling the flow of water discharge, a triggering device for the water flowing through and a Device for power supply and include at least two modes of operation, for example with user (water flows) and no user (water does not flow). Fittings of the type mentioned are from the AT404150B . AT412824B . DE19651132A1 . DE10148675C1 . EP2169123A1 . EP0813636A1 and the US5961095A known.

From the AT9069U1 It is known that a device for power supply is designed as a battery, as an accumulator, as a fuel cell or as a power supply. Battery, accumulator and fuel cell allow mounting and retrofitting even in places where no mains voltage is available. A disadvantage of these solutions is that batteries are exchanged according to their consumption, refueled fuel cells and rechargeable batteries must be recharged. Although a power supply reduces the maintenance, but requires more effort in the electrical installation; The standby consumption of the power supply also has a negative impact on energy costs.

Another step towards energy-efficient and self-sufficient systems is the use of water energy. In the US20110074157A1 . EP2173021A1 . EP1306962A1 and EP2293420A1 embodiments of hydroelectric generators for sanitary fittings are disclosed, these generators are driven by the water flowing through and thus provide electrical energy during flushing. The EP0675234A1 describes a method of generating electrical energy by having a generator coupled to a water turbine charge a storage capacitor during a purge. In the EP0433631A1 and DE3905759C1 A generator converts the flow energy of the water flow into electrical energy, the generator being connected to an accumulator. The DE 10 2009 051 090 A1 discloses a sanitary fitting with a generator, a bistable solenoid valve, a valve body and a magnetic head, in which manual actuation of the magnetic head, the bistable solenoid valve is opened by a permanent magnet and can be started manually with empty energy storage valve. The cited generators have due to the size of the disadvantage that they do not allow installation in commercial sanitary fittings, such as single lever mixer and thus require a complex, separate from the fitting device. A disadvantage is that the drive turbines of the hydroelectric generators usually generate disturbing noises when removing water and deliver the generators only during use power. If the valves are not used, the energy store, for example an accumulator, discharges.

In the DE4403180C1 there is disclosed means for converting pressure fluctuations into electrical energy prevailing in fluid systems. A disadvantage of the use in sanitary fittings of the type described above is that pressure fluctuations essentially occur only when opening or closing of valves and thus they do not provide sufficient power for continuous operation.

From the EP1170805A2 For example, a supply device is known in which a group of solar cells is integrated in a mirror located near a sanitary fitting. The ambient light is sufficient for self-sufficient supply of the sanitary installation. Disadvantage is that the solar cell device is mounted separately from the sanitary fitting and requires a mirror in the vicinity, which limits the use of commercial or public sanitary areas very much, because there are mounted on the wall mirror due to the risk of vandalism avoided. The EP1241301A2 and DE4004099A1 disclose electronically controlled faucets whose energy stores are connected to one or more solar cells. The attachment of the solar cells severely limits the shape of the faucet and causes significant additional costs in the manufacture of the valve. If plumbing fixtures with solar cells are not sufficiently supplied with light for a long period of time or if the illuminants emit a wavelength different from the absorption wavelength of the solar cells, the energy yield is low and the built-in rechargeable battery or rechargeable battery discharges in such a way that a reliable function does not occur given is.

In the DE 10 2008 047 069 A1 discloses a fitting with a means for irradiating the liquid with UV light, which in a particularly advantageous embodiment by means of turbine Use of water energy or solar cell powered by the use of light energy. If this fitting is not adequately supplied with light for a prolonged period of time or if the light sources emit different wavelengths at an absorption wavelength of the solar cells, the energy yield is low in times without water flow even in this solution and the built-in rechargeable battery or rechargeable battery discharges in such a way that that a reliable function is not given.

Furthermore, it is known that a thermoelectric element generates a temperature gradient when an electrical voltage is applied. If such a thermoelectric element is inversely exposed to a temperature gradient, it operates as a thermogenerator, ie an electrical voltage can be tapped off. This expression is known as Seebeck effect. In the DE 10 2008 021 697 B4 a holder device for a thermogenerator is mentioned, wherein the thermogenerator is coupled to two lines of different temperature and a coupling device relative to a support device is displaceable. From the EP0312737A1 is an electrically controlled armature for cold and hot water with a Peltier arrangement known, one side of which is thermally coupled to the hot water and the other side with the cold water. In times without water flow, the temperature difference between the side thermally coupled with warm water side and the cold water thermally coupled side of the Peltier arrangement goes to zero Kelvin. From the thermogenerator no voltage can be tapped and it discharges the built-in battery or the rechargeable battery such that a reliable function is not given.

The EP0717332A1 discloses an electrical actuator for controlling the flow of a liquid medium. This actuator comprises a thermoelectric generator, an electronic voltage converter and a rechargeable battery.

From the EP1729195A1 For example, a heat exchange valve control attachment with a thermal generator as a power supply is known. The GB2216293A shows a radiator valve with a thermal generator, which is thermally coupled to the radiator. In both applications, the thermal generator uses the difference in temperature of a medium through which it flows to the ambient temperature as a temperature difference.

The DE20107112U1 discloses for process plants a device for supplying power to field devices with a thermoelectric converter.

The object underlying the invention is to provide a sanitary fitting of the type mentioned, which is designed to be energy-autonomous to a high degree by efficiently obtaining electrical energy for each of the at least two operating modes.

The object of the invention is achieved in a sanitary fitting of the type mentioned above in that the at least two generators for converting energy from at least two independent energy sources of different types are formed, being provided for each of the at least two operating modes of self-sufficient operation by at least one generator ,

In a further embodiment it can be provided that at least two generators are designed to convert energy from the same energy source.

In a particular embodiment of the invention it can be provided that at least one generator is designed as a thermogenerator, solar cell, photodiode, turbine, piezoelectric energy harvester, radio frequency energy harvester or sound energy harvester.

Advantageously, it can be provided in one embodiment that at least one of the generators is arranged in the sanitary fitting.

Furthermore, it can be provided that at least one of the generators is arranged outside the sanitary fitting.

In a particular embodiment it can be provided that at least one of the generators is arranged on a line for inflowing hot water, a line for inflowing cold water, a line for incoming mixed water or a circulation line.

In a further embodiment it can be provided that the sanitary fitting emits electrical energy to a connected consumer via a line or feeds it into an energy supply system.

In a further advantageous embodiment it can be provided that the thermal generator is designed to increase or decrease the temperature of the cold water, mixed water, hot water, return and / or the fitting housing of the sanitary fitting.

Furthermore, it can be provided that the thermal generator for heating the cold water, mixed water, hot water, return and / or the fitting housing of the sanitary fitting for performing a thermal disinfection is formed.

In a particular embodiment, it can be provided that the sanitary fitting for closing a triggering device for the water flow is formed with the energy provided by at least one generator in the sanitary fitting falls below a limit value of the power supply.

The invention will be explained in more detail with reference to embodiments according to the drawings, wherein

1a a sanitary fitting with cold and hot water connection with thermogenerator and energy storage;

1b a sanitary fitting with cold and hot water connection with thermogenerator in the valve body and energy storage;

2a a sanitary fitting with cold water connection with thermogenerator and energy storage;

2 B a sanitary fitting with mixed water connection with thermogenerator and energy storage;

3 a sanitary fitting for circulation pipes with thermogenerator without energy storage;

4 a sanitary fitting with several generators and a connection for a power supply;

5 a urinal or toilet flusher with thermogenerator and energy storage;

6 a thermogenerator;

7 a block diagram of a voltage converter for generating the required operating voltage from a thermal generator
represent.

1a shows a sanitary fitting, as a washbasin faucet 1 executed and on a sink 4 is mounted. The washbasin faucet 1 includes a valve body 3 with swivel spout 2 , a lead 5 for incoming hot water WW, a pipe 6 for incoming cold water KW, a mounting ring 9 for attaching the basin mixer 1 at the sink 4 , an adjustment device 7 for adjusting the mixing ratio of the hot water WW and the cold water KW, a triggering device 8th , here a solenoid valve, to deliver mixed water to the outlet 2 , an optoelectronic sensor 10 , an energy store 11 , an electronic circuit unit 12 and a thermogenerator 13 , The two lines 5 and 6 are in the range of the thermogenerator 13 made of good heat conducting material, preferably brass or copper. The thermogenerator 13 is in a housing 14 that the line 5 for incoming hot water WW and the pipe 6 for incoming cold water KW encloses, outside the fitting housing 3 arranged and includes a thermogenerator chip 15 with connected voltage transformer 22 ( 7 ), the warmer side 16 of the thermogenerator chip 15 over the good heat-conducting intermediate piece 18a with the line 5 for inflowing hot water WW and the colder side 17 over the good heat-conducting intermediate piece 18b with the line 6 for incoming cold water KW is coupled. From the temperature difference between the warmer side 16 and the colder side 17 of the thermogenerator chip 15 generates the thermogenerator 13 one of the temperature difference approximately proportional voltage U _TG ( 7 ), by means of the voltage converter 22 ( 7 ) is up-converted and over the line 19 the energy store 11 fed. The energy storage 11 is designed as a rechargeable battery, wherein in an alternative embodiment of the energy storage 11 as a capacitor with a capacity of at least 5 Millifarad is trained.

The optoelectronic sensor device 10 detects the approach of an object, such as a person or a user's hand, opens over the electronic circuit unit 12 the triggering device 8th to discharge water from the outlet 2 and enters the user mode of operation as soon as the object is within a predetermined response range of the opto-electronic sensor device 10 located and closes the triggering device 8th and enters the no-user operating mode as soon as the object leaves the response area. By activating the triggering device 8th in user mode, the energy consumption is higher than in non-user mode.

The washbasin faucet 1 works in the operating mode with user through the energy production of the thermal generator 13 essentially energy self-sufficient.

Furthermore includes the washbasin faucet 1 an energy supply 44 in the form of a power supply, a battery, a rechargeable battery or a fuel cell. The energy supply 44 is provided to the energy storage 11 charge in case of failure of the hot water supply and to ensure the function of non-contact water delivery.

In an alternative embodiment, the electronic circuit unit uses 12 the Peltier effect of the thermogenerator 13 and increased by applying the voltage from the power supply 44 or from the energy store 11 over the line 19 to the thermogenerator 13 the temperature difference between hot water WW and cold water KW.

1b indicates in continuation 1a a washbasin faucet 1 in which the thermogenerator 13 in the valve body 3 is arranged. The housing 14 is with the valve body 3 thermally coupled.

The energy supply 44 is designed as a battery with a rated voltage U _N of 9V. The electronic circuit unit 12 monitors the voltage of the power supply 44 and closes the triggering device 8th as soon as the voltage of the power supply 44 falls below the limit U _G of 6V.

2a shows in training too 1a a washbasin faucet 1 over a line 6 for incoming cold water KW has.

The housing 14 of the thermogenerator 13 encloses the line 6 of the incoming cold water KW. The thermogenerator chip 15 is with the colder side 17 over the heat-conducting intermediate piece 18b with the line 6 and with the warmer side 16 over the heat-conducting intermediate piece 18a with the housing 14 thermally coupled. The administration 6 is opposite the housing preferably made of metal 14 through the thermally insulating intermediate piece 21 for a heat transfer to the housing 14 largely decoupled. The housing 14 thus has the temperature of the ambient air (U), usually about 20 ° C. This temperature affects the warmer side 16 of the thermogenerator chip 15 , The colder side 17 takes the temperature of the cold water, here about 12 ° C, to. The thermogenerator 13 feeds with the temperature difference in the thermogenerator chip 15 converted and provided electrical energy the energy storage 11 ,

2 B shows in training too 1a a washbasin faucet 1 over a line 20 for incoming mixed water MW has.

The housing 14 of the thermogenerator 13 encloses the line 20 of the incoming mixed water MW. The thermogenerator chip 15 is with the warmer side 16 over the heat-conducting intermediate piece 18a with the line 20 and with the colder side 17 over the heat-conducting intermediate piece 18b with the housing 14 thermally coupled. The administration 20 is opposite the case 14 through the thermally insulating intermediate piece 21 for a heat transfer to the housing 14 largely decoupled. The housing 14 thus has the temperature of the ambient air (U), usually about 20 ° C. This temperature affects the colder side 17 of the thermogenerator chip 15 , The warmer side 16 takes the temperature of the mixed water, here about 35 ° C, to. The thermogenerator 13 feeds with the temperature difference in the thermogenerator chip 15 converted and provided electrical energy the energy storage 11 ,

3 shows in training too 1a a washbasin faucet 1 that a thermogenerator 13 includes, whose housing 14 encloses three lines, the line 5 for incoming hot water WW, the pipe 6 for incoming cold water KW and the circulation line 23 through which not through the spout 2 discharged hot water WW through the circulation pump 46 as return Z in the hot water tank 47 the building-side hot water system 45 is returned. The thermogenerator 13 includes two thermo generator chips 15a . 15b , The warmer side 16a of the thermogenerator chip 15a is over the heat-conducting intermediate piece 18a with the line 5 for inflowing hot water WW and the colder side 17a of the thermogenerator chip 15a is over the heat-conducting intermediate piece 18b with the line 6 thermally coupled for incoming cold water water KW. The warmer side 16b of the thermogenerator chip 15b is over the heat-conducting intermediate piece 18c with the circulation pipe 23 and the colder side 17b of the thermogenerator chip 15b is over the heat-conducting intermediate piece 18b with the line 6 thermally coupled for incoming cold water water KW. The thermoelectric voltages U _TG (several tens of millivolts) 7 ) of the thermogenerator chip 15a and the thermogenerator chip 15b are connected in series. From the thermal voltage U _TG ( 7 ) of the thermogenerator chip 15b the valve is in the operating mode without user and in the operating mode with user from the temperature difference from the incoming cold water KW and the circulation line 23 provided. The higher energy requirement in user mode is due to the additional thermo voltage U _TG ( 7 ) of the thermogenerator chip 15a from the temperature difference from the incoming cold water KW and from the incoming hot water WW covered. The sum of the two thermoelectric voltages forms the input voltage source for the downstream voltage converter 22 ( 7 ), whose output 24 ( 7 ) over the line 23 the electronic circuit unit 12 with the output voltage U _out ( 7 ), which is approximately at 3.3 volts. As the circulation pipe 23 constantly warm water leads, converts the thermogenerator 15b constantly the temperature difference between the temperature of the circulation line 23 and the line 6 for incoming cold water water KW into electrical energy for the washbasin faucet 1 around. This works thus completely self-sufficient even if there is no use for a long period of time. This is a washbasin faucet 1 according to this design without energy storage 11 executed.

4 shows in training too 1a a washbasin faucet 1 with several different sources of energy, the electrical energy storage 11 Food. At the upper deck surface is a solar cell 25 with a transparent shatterproof glass surface flush with the valve body 3 arranged. The solar cell 25 is a generator and converts light energy into electric current from the energy source of the incident light to feed the energy storage device 11 over the line 30 around.

The optoelectronic sensor device 10 sends short light pulses to detect an object 28 in the infrared range in the form of pulse packets 27 for a duration t _p of a few milliseconds. The photodiode 26 , here a PIN diode, receives the light diffusely reflected on the object and evaluates its level and waveform. The impulse packages 27 are emitted repetitively with a period T of about 100 milliseconds. During the period 29 the photodiode acts 26 as a generator and converts the energy source light light energy into electricity for feeding the energy storage 11 around.

The energy source of the thermogenerator 13 is temperature difference. The thermogenerator 13 provides electrical energy from the temperature difference of the line 5 for incoming hot water WW and the pipe 6 for incoming cold water KW.

In the line 5 for incoming hot water WW and in the pipe 6 for incoming cold water KW is ever a turbine 33 mounted as a generator, which from the energy source kinetic energy of the water flowing through during a water discharge of the basin mixer 1 kinetic energy into electrical energy to power the energy storage 11 over the line 31 transforms.

The washbasin faucet 1 also includes a Radio Frequency (RF) Energy Harvester 35 for energy production from different electromagnetic energy sources in the high frequency range (HF), like the radio signal (KW, FM), the terrestrial digital television DVB-T, WLAN or portable radio nets. The RF Energy Harvester 35 includes an RF voltage converter, an antenna and feeds the electrical energy storage in generator mode 11 , The RF Energy Harvester 35 is with an antenna connection 32 provided for an external antenna. The antenna connection 32 is in the valve body 3 arranged.

In the line 5 for incoming hot water WW and the pipe 6 for incoming cold water KW is in the area in front of the triggering device 8th one piezoelectric energy harvester each 34 mounted on the piezoelectric transducer by means of a membrane, the water pressure of the line 5 and the line 6 acts. The opening and closing of manual or electro-hydraulically actuated water flow actuators, such as single-lever mixers or solenoid valves, creates pressure surges in the supply line and in the water supply line, causing pressure spikes in the range of 2 MPa (20 bar). The piezoelectric energy harvester 34 converts vibrations, such as those caused by pressure surges in water supply lines, into an electrical voltage and therefore works as a generator that uses the kinetic energy source to store energy 11 fed. The piezoelectric energy harvester 34 includes a piezoelectric transducer, an electronic signal processing and a voltage converter whose output with the energy storage 11 connected is.

In an alternative embodiment, the piezoelectric energy harvester 34 the washbasin faucet 1 executed with an electrodynamic converter.

Furthermore, on the line 6 for incoming cold water KW a sound energy harvester 50 appropriate to the source of energy sound (ambient noise and from the wire 6 coupled sound) converts sound energy into electrical energy. The sound energy harvester 50 includes an electromechanical generator and a voltage converter whose output is via the line 31 with the energy storage 11 connected is.

In a particularly advantageous embodiment, the electronic circuit unit converts 12 with the voltage converter 48 The excess, not required by the valve energy in a voltage of 230 V / 50 Hz and gives them over the line 49 to a connected consumer or feeds it via the line 49 into an energy supply system.

5 indicates in continuation 2a an initially mentioned sanitary fitting, here as a sanitary wall 37 mounted surface-mounted dishwasher 36 for the contactless triggering of a rinsing process, preferably for urinal and toilet bowls is formed. The thermogenerator 13 is under the valve body 3 attached, encloses with the housing 14 the flush pipe 38 and converts the temperature difference between the temperature of the purge tube 38 and the temperature of the opposite of the flushing pipe 38 thermally insulated housing 14 in an electrical voltage, which is the energy store 11 fed.

In a further embodiment, the flushing flusher includes 36 an energy supply 44 ,

6 shows the execution of a Thermogerator chip 15 . 15a . 15b the two on the inside with electrically conductive contact tracks 39 printed carrier boards 40a and 40b comprising a p- and n-doped semiconductor layer 41 with structured surface. By the contact and the different heat capacity within the semiconductor layer 41 stands by the Seebeck effect at a temperature difference between the warmer side 16 . 16a . 16b and the colder side 17 . 17a . 17b an electrical voltage U _TG on the order of a few tens of millivolts available at the connecting lines 42 is tapped.

7 shows the exemplary embodiment of a voltage converter 22 , the voltage U _TG of the thermogenerator chip connected to the input 15 . 15a . 15b to a voltage U _{out of} the order of typically 2.5 to 6 volts at the output. The secondary winding of the step-up transformer TR forms with the capacitor C3 a resonant circuit which forms with the MOSFET SW and the feedback-connected primary winding of the transformer TR an oscillator whose amplitude is approximately proportional to the voltage U _TG , in the integrated circuit 43 is rectified and as one at the output 24 load-dependent stabilized voltage U _out occurs.

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

• AT 404150 B [0002]
• AT 412824 B [0002]
• DE 19651132 A1 [0002]
• DE 10148675 C1 [0002]
• EP 2169123 A1 [0002]
• EP 0813636 A1 [0002]
• US 5961095 A [0002]
• AT 9069 U1 [0003]
• US 20110074157 A1 [0004]
• EP 2173021 A1 [0004]
• EP 1306962 A1 [0004]
• EP 2293420 A1 [0004]
• EP 0675234 A1 [0004]
• EP 0433631 A1 [0004]
• DE 3905759 C1 [0004]
• DE 102009051090 A1 [0004]
• DE 4403180 C1 [0005]
• EP 1170805 A2 [0006]
• EP 1241301 A2 [0006]
• DE 4004099 A1 [0006]
• DE 102008047069 A1 [0007]
• DE 102008021697 B4 [0008]
• EP 0312737 A1 [0008]
• EP 0717332 A1 [0009]
• EP 1729195 A1 [0010]
• GB 2216293A [0010]
• DE 20107112 U1 [0011]

Claims (10)

Sanitary fitting ( 1 . 36 ) with at least two operating modes, at least one sensor ( 10 ), at least one electronic circuit unit ( 12 ), at least one triggering device ( 8th ) and at least two generators ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) characterized in that at least one generator as a thermal generator ( 13 ), Solar cell ( 25 ), Photodiode ( 26 ), Turbine ( 33 ), piezoelectric energy harvester ( 34 ), Radiofrequency (RF) Energy Harvester ( 35 ) or Sound Energy Harvester ( 50 ) is trained. Sanitary fitting ( 1 . 36 ) according to claim 1, characterized in that at least one generator as a thermal generator ( 13 ) and at least one generator as a solar cell ( 25 ) or at least one generator as a thermogenerator ( 13 ) and at least one generator as a photodiode ( 26 ) or at least one generator as a thermogenerator ( 13 ) and at least one generator as a turbine ( 33 ) or at least one generator as a thermogenerator ( 13 ) and at least one generator as a piezoelectric energy harvester ( 34 ) or at least one generator as a thermogenerator ( 13 ) and at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) or at least one generator as a thermogenerator ( 13 ) and at least one generator as a sound energy harvester ( 50 ) or at least one generator as a solar cell ( 25 ) and at least one generator as a photodiode ( 26 ) or at least one generator as a solar cell ( 25 ) and at least one generator as a turbine ( 33 ) or at least one generator as a solar cell ( 25 ) and at least one generator as a piezoelectric energy harvester ( 34 ) or at least one generator as a solar cell ( 25 ) and at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) or at least one generator as a solar cell ( 25 ) and at least one generator as a sound energy harvester ( 50 ) or at least one generator as a photodiode ( 26 ) and at least one generator as a turbine ( 33 ) or at least one generator as a photodiode ( 26 ) and at least one generator as a piezoelectric energy harvester ( 34 ) or at least one generator as a photodiode ( 26 ) and at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) or at least one generator as a photodiode ( 26 ) and at least one generator as a sound energy harvester ( 50 ) or at least one generator as a turbine ( 33 ) and at least one generator as a piezoelectric energy harvester ( 34 ) or at least one generator as a turbine ( 33 ) and at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) or at least one generator as a turbine ( 33 ) and at least one generator as a sound energy harvester ( 50 ) or at least one generator as a piezoelectric energy harvester ( 34 ) and at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) or at least one generator as a piezoelectric energy harvester ( 34 ) and at least one generator as a sound energy harvester ( 50 ) or at least one generator as a Radio Frequency (RF) Energy Harvester ( 35 ) and at least one generator as a sound energy harvester ( 50 ) is trained. Sanitary fitting ( 1 . 36 ) according to claim 1 or 2, characterized in that at least two generators as a thermal generator ( 13 ), Solar cell ( 25 ), Photodiode ( 26 ), Turbine ( 33 ), piezoelectric energy harvester ( 34 ), Radiofrequency (RF) Energy Harvester ( 35 ) or Sound Energy Harvester ( 50 ) are formed. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 3, characterized in that at least one of the generators ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) in the sanitary fitting ( 1 . 36 ) is arranged. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 4, characterized in that at least one of the generators ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) outside the sanitary fitting ( 1 . 36 ) is arranged. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 5, characterized in that at least one of the generators ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) on the line for incoming hot water ( 5 ), the line for incoming cold water ( 6 ), the line for incoming mixed water ( 20 ) or the circulation line ( 23 ) is arranged. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 6, characterized in that the electronic circuit unit ( 12 ) with the voltage converter ( 48 ) Energy from at least one of the generators ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) or the energy storage ( 11 ) into a voltage and over the line ( 49 ) feeds into a power supply system. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 7, characterized in that the electronic circuit unit ( 12 ) by applying a voltage to the thermogenerator ( 13 ) the temperature of the cold water (KW), mixed water (MW), hot water (WW), the return (Z) and / or the valve body ( 3 ) raises or lowers. Sanitary fitting ( 1 . 36 ) according to claim 8, characterized in that the electronic circuit unit ( 12 ) by applying a voltage to the thermogenerator ( 13 ) the temperature of the cold water (KW), mixed water (MW), hot water (WW), the return (Z) and / or the valve body ( 3 ) and thermally disinfected. Sanitary fitting ( 1 . 36 ) according to one of claims 1 to 9, characterized in that the electronic circuit unit ( 12 ) falls below a limit value (U _G ) of the energy supply ( 44 ) the triggering device ( 8th ) with that of at least one generator ( 13 . 25 . 26 . 33 . 34 . 35 . 50 ) provides energy.

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