AT514159B1 - Sanitary fitting with heat meter - Google Patents

Abstract

The invention relates to a terminal sanitary fitting, in particular for showers, baths, sinks, sinks, bidets, urinals and toilets, with at least one actuator, a hot water inlet, a cold water inlet, an outlet, at least one flow meter and at least one temperature sensor, the heat quantity limiting circuit unit for Limitation of the amount of heat emitted at a water extraction from the sanitary fitting comprises.

Description

Description [0001] The invention relates to a terminal sanitary fitting, in particular for showers, baths, sinks, sinks, bidets, urinals and WCs, with at least one actuating element, a hot water inlet, a cold water inlet, an outlet, at least one flow meter and at least one a temperature sensor, which comprises a heat-quantity-limiting circuit unit for limiting the amount of heat released from the sanitary fitting when a water is withdrawn.

Terminal sanitary fittings are faucets for removing water, especially for showers, tubs, sinks, sinks, bidets, urinals and toilets. They carry the risk that with prolonged non-use of such a fitting, for example, during the closing times or when not occupied, microorganisms such as bacteria, fungi or Amö¬ben, in the stagnant residual water of the valve or the supply line can multiply and lead zulebensrohrohlichen diseases in humans , According to a publication of the German Federal Environmental Agency, Legionella pneumophila alone in Germany cause between 20,000 and 32,000 diseases of pneumonia each year, up to 15% of cases fatal. An analysis of 40,000 samples taken throughout Germany in 2012 showed that 37% of the samples were able to detect Legionella spec. And 17% of the samples exceeded the statutory measures. Since Legionella pneumophila hardly multiply in the cold water, they are in contrast to Escherichia coli, enterococci and Pseudomonas aeruginosa not within the scope of the Austrian Drinking Water Ordinance and can thus be contained in the drinking water supplied by the drinking water supplier. At ideal water temperatures Legionella pneumophila approximately double every 2 to 3 hours; apart from this ideal temperature, the propagation proceeds more slowly; outside certain limits propagation is stopped or the microorganisms are killed.

Especially in the removal of hot water, the spout is already heated by the dispensed mixed water and the inflowing hot water to the ideal for Ver¬mehrung of Legionella pneumophila temperature of about 30 to about 40 ° C and then cools down depending on the room temperature , Legionella pneumophila multiply even at temperatures around 50 ° C and therefore especially in areas of Heißwasserinstallati¬on, in which a minimum temperature of 60 ° C is not maintained. This applies above all to sub-sections with cooling, stagnant hot water, the return of the circulation or plants that are operated for reasons of saving energy during business interruptions or even in continuous operation under the minimum temperature of about 60 ° C required for killing Legionella pneumophila.

The following diagram illustrates the propagation of Legionella pneumophil at a temperature in the range of about 30 to about 40 ° C. On the x-axis, the time is in hours, on the y-axis, the number of colony-forming units (CFU) per 100 milliliters as a size for the quantification of microorganisms shown.

Starting from an initial stock of 10 cfu Legionella pneumophila per 100 mlWird at a water temperature in the range of 30 to 40 ° C after about 9 hours the measure of 100 cfu per 100 ml achieved. With regular rinsing of, for example, every 3 hours, starting from an initial level of 10 cfu per 100 ml, a value of 22 cfu per 100 ml can not be exceeded and a safe distance of 100 cfu per 100 ml is ensured. A regular manual operation even when not in use is very complicated for the operator and hardly feasible outside the operating hours. Especially in hygienically sensitive areas, for example in operating theaters or in institutions for immunocompromised people, the effort for the regular manual operation and monitoring has a significant effect on the operating costs.

Especially in times of increased environmental awareness and the desire for a reduction in operating costs, energy efficiency is the focus of planners, installers, operators and residents of buildings, apartments and the like. An essential basis for optimizing energy efficiency is the collection of resources consumed over the life cycle of erection, operation, disassembly and disposal. The detection of the amount of heat consumed in the operation of buildings or flats is known inter alia from AT512141A1. A disadvantage of the existing solutions is that only the total amount of heat given off a group of valves, but not the amount of heat each einzel¬nen sanitary fitting itself is detected. However, precisely this is necessary to enforce targeted measures to reduce the amount of heat consumed the individual sampling points and also allow the operators of commercial facilities, such as Well¬nesseinrichtungen, a charge according to the amount of heat consumed.

End fittings with a sensor device for non-contact detection of an object, such as the hand of a user or a person who is in front of the faucet, and an electronic circuit unit for controlling the flow of the water discharge and a triggering device for the flowing water are among otherse AT404150B, AT412824B, DE19651132A1, DE10148675C1, EP2169123A1, EP0813636A1 and US5961095A. In addition, US2005150556A1 discloses a fitting which can be additionally manually operated.

From US2004254746A1 and AT506792B1 devices are known which automatically trigger a hygiene flush after a certain period of non-use and rinse out the stagnation water after a predetermined time irrespective of the risk of microbiological growth. A disadvantage of these systems is that they trigger flushing even when there is a risk of microbiological growth and thus unnecessarily waste water.

EP2500475A2 discloses a flushing system for automatic flushing of pipes. The flushing system comprises temperature sensors and electronic components for detecting, storing and evaluating data such as temperature, frequency of use and the like. After evaluation of the determined measured values, if necessary a purge of the line triggered up to the flushing system. A disadvantage of this system is that the lines from the flushing system to the terminal fittings and the terminal fittings themselves are not flushed and thus the microorganisms in these areas can multiply unhindered.

In GB2348945B it is described that in order to reduce the microbiological growth, in particular the multiplication of Legionella pneumophila, in hot water systems usually a temperature of the hot water of at least 60 ° C must be observed. The protection against scalding, especially in facilities for children and older people, by means of thermostatic valves, so that at the water delivery points a certain maximum temperature, for example in the range of 43 to 44 ° C, can not be exceeded. In order to kill the germs multiplying themselves in the thermostatic valves, the temperature limitation must be canceled by a service worker, which is very expensive for the operator.

In DE102004014126B3 a fitting is described, in which a bypass is provided with ei¬nem solenoid valve, via which the water can be passed bypassing the mixing device.

DE10156224C1 discloses a device for the thermal disinfection of a Sani¬tärarmatur. The device includes a solenoid valve which directs the hot water into the mixed water line, bypassing the mixer and the bleed valve.

A disadvantage of this device is that the thermal disinfection takes place exclusively with hot water, bypassing the mixing device and also at hot water temperatures above the set temperature for the thermal disinfection no cold water added and thus unnecessarily hot water is consumed.

A disadvantage of the solutions disclosed in DE102004014126B3 and DE10156224C1 is that the Legionella pneumophilus self-propagating in the mixing device can not be killed, since the rinsing water containing more than 60 ° C. does not destroy the Legionella pneumophila during thermal disinfection Mixing device itself, but flows through a bypass and thus bypasses the mixing device.

DE29622320U1 describes a fitting with mixing device. To reduce legionella growth, if necessary, rinse the lines with hot water.

A disadvantage of this fitting is that the hot water is not supplied at a thermal Desinfekti¬on on the hot water inlet, but on its own Warmwasserdesinfekti¬onsanschluss, thus the strand end of the hot water pipe to the hot water inlet of the valve, and the hot water pipe and the mixing chamber in the Arma¬tur not be rinsed itself and so the microorganisms in these areas can propagate unhindered.

EP2439174A1 discloses a flushing system for water pipes. The flushing system has facilities such as sensors, processors, memory and control software. Via radio or data line, the detected parameters and rinses carried out can be transmitted to an external processing device. A disadvantage of this system is that only the hot water line is flushed via a bypass directly into the outlet and possibly in the cold water line and in the fitting itself located microorganisms are not rinsed out and can propagate unhindered.

WO029078004A2 describes a device for hot water supply. At least one sensor transmits the temperature of the discharged hot water. The system can be programmed to dispense mixed water of a given temperature as hot water for terminal fittings. Anti-scalding closes the valve if the temperature of the mixed water delivered as hot water to the terminal fittings exceeds a certain threshold temperature. A disadvantage of this device is that the temperature of all connected terminal fittings is limited and even when needed by no terminal fitting mixed water can be discharged at a higher Tempe¬rature.

DE102009030534A1 describes a system with a central control device for the thermal disinfection of sanitary fittings. It allows a remote controlled triggering of a thermal disinfection and storage of the data. Upon actuation of an actuation device during the thermal disinfection, thermal disinfection is stopped to protect the user. All actuators and temperature sensors are wired via signal lines and all by-pass valves via control lines to the central controller. Disadvantages of this system are the high costs and on-site cabling expenses.

From W09529127A1 a water treatment device is known. After the thermal disinfection, the hot water is drained.

WO 02/006077396 A1 discloses an installation system in which, after a thermal disinfection, water is rinsed with a safe temperature for a predetermined time. A disadvantage of this system is that the temperature of the water remaining in the installation system is not taken into account.

[0022] DE 29720701U1 discloses thermostatically controlled mixing batteries for automatically controlled alternating showers, in which an electronic circuit with valves switches over between two waters of different temperature. A disadvantage of this solution is that for each of the required adjustable temperatures, a separate mixer is required.

US2005103693A1 discloses a non-terminal drinking water flushing unit for filling tanks of means of transport, such as aircraft, trains, buses, boats and ships with a temperature sensor for detecting the temperature in the interior of the drinking water flushing unit and a nozzle for filling tanks and not direct water removal by a user, for example, in showers, tubs, sinks, sinks, bidets, urinals and toilets. When a limit temperature in the interior of the drinking water rinsing unit is exceeded or a stagnation period is exceeded, a control unit triggers a valve and flushes the stagnation water from the drinking water rinsing unit through a stagnation flush outlet into a drain. A disadvantage of this solution is that the flushing out of stagnation water is carried out by an additional valve to which the conventional dispensing valve is coupled and that in the terminal sanitary fittings for direct Wasserentnah¬me stagnant by a user in the course of flushing the Stagnationswas¬sers from the drinking water flushing unit is not rinsed out of the terminal sanitary fittings and so the microorganisms in the terminal sanitary fittings can unhindered ver¬mehren. To monitor the correct coupling and / or the open position of the usual dispensing valve, a pressure switch is required. The additional valve and the pressure switch make the non-terminal drinking water flushing unit more expensive. To determine the stagnation time, the position of the door of the drinking water rinsing unit is monitored with a sensor. If the door is opened, this is rated as use and the electronic counter of the stagnation period is reset, although it is not ensured that water will be withdrawn each time the door is opened. In addition, the temperature of the interior of the drinking water rinsing unit increases much faster when exposed to heat than the temperature of the stagnation water, whereby the Stagnationsfreispülung tripped early and wasted water unnecessarily.

From DE102008039272A1 a method for determining the Ressourcenverbrau¬ches at a water tap is known. By means of flow meter, temperature sensor and microcontroller, the amount of heat is determined. A disadvantage of this method is that the resource-saving use is ensured only by intervention of the user or by means of additional components.

The object underlying the invention is to provide a terminal Sanitär¬armatur of the type mentioned above, which has a device that automatically limits the amount of heat emitted by controlling the discharge of water.

The object of the invention is achieved in a terminal sanitary fitting of ein¬gangs mentioned type in that the terminal sanitary fitting comprises a heat-quantity limiting circuit unit for limiting the amount of heat delivered at a water extraction from the entendändige plumbing fixture.

It is further provided that the terminal sanitary fitting comprises a heat meter, which detects the volume flow of the delivered mixed water with a flow meter or from the values of the flow meter in the inflowing cold and warm water. Furthermore, it can be provided that the terminal sanitary fitting comprises at least one temperature sensor and an electronic circuit unit and the elektroni¬sche circuit unit with a temperature sensor detects the temperature of the dispensed mixed water or from the values of the temperature sensor in the inflowing cold and hot water under consideration the mixing ratio of cold and hot water is determined.

In a further consequence it can be provided that the heat quantity limiting switching unit includes a heat meter and / or a water stop. In a particular embodiment, it can be provided that when a water is discharged from a spout of the sanitary fitting, the heat quantity limiting circuit unit automatically closes a valve for dispensing water depending on the amount of heat released by the terminal sanitary fitting with a water stop.

Further, it can be provided that the heat meter from the values for temperature and flow, taking into account a reference temperature, the amount of heat derabgegebenen mixed water calculated and stops automatically with the water stopper depending on the amount of heat by closing a valve, the water output of the final sanitary fitting.

Advantageously, it can be provided that the water stopper closes a valve after a maximum period of time, after delivering a maximum amount of water and / or after releasing a maximum amount of heat, thus stopping the discharge of water of the terminal sanitary fitting, and avoids a waste of water and energy.

In a further embodiment it can be provided that the terminal Sanitärarma¬tur includes a scalding protection, which prevents thermal disinfection or breaks off when a user actuates an actuator or enters the active area of a proximity sensor.

Advantageously, it can be provided that the terminal sanitary fitting um¬ includes a Preventive flushing unit for triggering a preventive Stagnationsfreis purge for flushing the Stagnationswassers immediately before the use of the terminal sanitary fitting.

In a particular embodiment, it can be provided that the terminal sanitary fitting comprises a control line or a radio module for triggering a disinfecting rinse.

In another embodiment, it may be provided that the terminal sanitary appliance comprises a control unit for controlling the temperature of the dispensed mixed water during a disinfecting rinse, which admixes cold water flowing in from the cold water inlet depending on the temperature of the inflowing warm water and thus the temperature of during a disinfecting rinse discharged mixing water to an independent of the position of the actuators setpoint for the disinfection rinse regulates.

In a particular embodiment of the invention can be provided that the terminal sanitary fitting comprises a cooling unit for rinsing with cold water after a thermal disinfection.

The invention will be explained in more detail on the basis of exemplary embodiments according to the drawings, wherein FIG. 1 shows a terminal sanitary fitting with an electronic circuit unit for

Control of the mixing ratio of hot and cold water; A terminal plumbing fitting with a proximity sensor and an electronic circuit unit for controlling the water temperature in the outlet; [0039] FIG. 3 shows a terminal sanitary fitting designed as a shower fitting with an electronic circuit unit for controlling the water temperature in the outlet and detecting the body temperature of the user; [0040] FIG. 3a shows a terminal sanitary fitting designed as a shower fitting with an electronic circuit unit; 4 shows the temperature profile in a hot water system during a thermal

Disinfection; FIG. 5a shows the temperature profile in the outlet of a conventional terminal sanitary fitting; FIG. [0043] FIG. 5b shows the temperature profile in the outlet of a terminal sanitary fitting with a

cooling unit; FIG. 5c shows the temperature profile in the outlet of a terminal sanitary fitting which rinses hot; FIG. FIG. 6 shows the temperature profile of the stagnation water, and [0047] FIG. 7 shows a non-terminal sanitary fitting designed as a mixing valve with an electronic circuit unit for controlling the water temperature. [0047] FIG.

Fig. 1 shows a terminal sanitary fitting 1, designed here as a washbasin fitting, which is mounted by way of example on a sink, not shown, serve with a Armaturen¬körper 2 and one of the usual water removal by a user 18 (Fig.3,3a) The top 9 of the fitting body 2 is mounted opposite the fitting body 2 about the vertical axis 11a rotatably mounted dash cover 11, which carries the actuation lever designed as a pivotable actuating member 12. The dashboard cover 11 includes a position sensor 11b which detects, on the one hand, a rotation of the dashboard cover 11 and, on the other hand, pivoting of the actuator 12 from the position 12a to the stop in the position 12c and the values as electrical signals to the electronic circuit unit mounted in the dashboard body 2 4 directs. On the underside of the Arma¬turenkörpers 2 are the connections for hot water WW and cold water KW, in whose openings each a backflow preventer is inserted. About the hot water hose 6 and the cold water hose 7, the terminal plumbing fixture 1 is connected to the not shown building side water installation. In the sanitary fitting 1, the designed as a mixing valve valve 30 is arranged. The valve 30 comprises the valve body 34, the hot water inlet 37 for inflowing hot water WW, the cold water inlet 39 for inflowing cold water KW and the mixing chamber 38 with the mixed water outlet 45 for the delivered mixed water MW, which flows via the outlet pipe 10 into the outlet 9. Furthermore, the valve 30 comprises the electric motor 31, which forms the actuator for the inflowing hot water WW with the adjusting bolt 32, which is vertically adjustable via the thread 33, wherein the stroke H1 between the stop 36 and the seal 35 is the volumetric flow of the hot air flowing through water WW in the direction of mixing chamber 38 determined. On the cold water side, the electric motor 44 forms the actuator for the inflowing cold water KW with the adjusting bolt 43 vertically adjustable via the thread 42, the stroke H2 between the stop 40 and the seal 41 determining the volume flow of the cold water KW flowing through in the direction of the mixing chamber 38 , In the illustrated position for the stroke H1 and the stroke H2 results in a mixing ratio for the delivered mixed water MW of about 30% hot water WW and70% cold water KW. The temperature sensor 22 in the region of the mixed water outlet 45 detects the temperature of the stationary and the flowing mixed water MW and passes this as an electrical signal to the circuit unit 4. The sanitary fitting 1 further comprises a Batte¬rie as energy supply 3 and a control line 23 for activating the Disinfektionsspü¬ the Sanitary fitting 1, in particular a thermal disinfection (see Figure 4).

The electronic circuit unit 4 is designed as a PID controller for the regulation of the temperature and the volume flow of the mixed water MW with the setpoint default derTemperatur by the position of the valve hood 11 and the setpoint specification of the volume flow through the position of the actuator 12th The electronic circuit unit 4 controls the valve 30 such that the actual temperature and the volume flow of the mixed water MW in the outlet 9 correspond to the respective desired values.

In position 12a of the actuating member 12, the electronic circuit unit 4 controls the valve 30 in such a way that the delivery of mixed water MW is interrupted and the sanitary appliance 1 is thus closed. To trigger the sanitary fitting 1, the user pivots the actuator 12 upwards from the position 12a. The position sensor 11 detects the pivoting movement and transmits it to the electronic circuit unit 4, which controls the valve 30 such that the sanitary fitting 1 emits the minimum volume flow of the mixed water MW from the outlet 9. If the actuator 12 is further pivoted upwards, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the mixed water MW delivered is increased and at the position 12c the maximum volume flow of mixed water MW is discharged from the outlet 9. When the actuating member 12 is pivoted downwards, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the mixed water MW discharged is reduced and in the position 12a the delivery of mixed water MW is interrupted and the sanitary fitting 1 is closed again.

If the actuator 12 is rotated clockwise to the left, so the Positi¬onssensor 11b passes the rotation of the dash panel 11 about the vertical axis 11a to the electronic circuit unit 4 and this controls the valve 30 such that the temperature of the dispensed Mixed water MW is raised and does not exceed a predetermined limit of example 38 ° C in the left stop 12. This prevents the scalding of a user with mixed water MW at too high a temperature. If the actuating member 12 is rotated counterclockwise to the right, the electronic circuit unit 4 controls the valve 30 in such a way that the temperature of the dispensed mixed water MW is lowered and in the right stop 12e it corresponds to that of the incoming cold water HP.

The electronic circuit unit 4 has a microcontroller control with a predetermined delay time, which delays the closing of the sanitary fitting 1 by a user. After expiration of the follow-up time controls the electronic circuit unit 4 with the valve 30, the flow of the mixed water MW such that the water jet 21 during a closing time of example one second continuously decays, the mixed water MWden the range from the mixing chamber 38 up to about stagnation level S in the outlet pipe 10 fills and there for the most part as Stagnationswasser 46 dwells until the next triggering in the sanitary fitting 1. By the continuous decay of the water jet 21 during the closing time, the emergence of pressure peaks in the sanitary fitting 1 is prevented by the closing process. The temperature of the stagnation water 46 corresponds to the time of closing the temperature of the mixed water MW delivered and gradually compensates for the temperature of the ambient air surrounding the valve, for example 24 ° C. If microorganisms have been introduced into the fitting with the inflowing cold water KW or the inflowing hot water, or if microorganisms penetrate through the jet regulator 8 and the outlet pipe 10 into the region of the stagnation water 46, they can multiply in the stagnation water 46, the propagation speed essentially being dependent on the temperature of the stagnation water 46 Stagnationswassers 46 and the nutrient supply in Stagnations¬wasser 46 is determined.

The follow-up time is given by way of example with a tenth of a second, so that the Sani¬tärarmatur 1, the delivery of mixed water MW quickly interrupts when the actuator 12 is brought into position 12a. Alternatively, the follow-up time is given by way of example with three seconds. Thus, a user who touches the sanitary fitting 1 to close, then clean the hands again, the valve 30 is controlled by the electronic Schalthtungseinheit 4 so that the temperature of the delivered mixed water MWund the resulting stagnation water 46 a The follow-up time and the closing time are defined in the program of the microcontroller control. In a particularly advantageous embodiment, at least the follow-up time or the closing time is adjustable with an adjusting controller or a remote control. The predefined value for the temperature of the forming stagnation water 46 is the temperature of the inflowing cold water KW. In another embodiment, the predetermined value for the temperature of the forming stagnation water 46 is included in the program of Mikrocontrol¬lersteuerung or aus¬geführt with an adjustable controller or a remote control adjustable. The adjustment knob is exemplified as a potentiometer, a slider, a wheel, a joystick, a DIP switch, a rotary switch or a tap changer.

In an alternative embodiment, the valve hood 11 of the sanitary fitting 1 is rigidly connected to the fitting body 2. With the actuator 12, the volume flow of the mixed water MW is adjusted by each position of the actuator 12, exemplarily per degree of angle a, corresponds to a certain volume flow. In position 12a of the actuator 12, the electronic circuit unit 4 controls the valve 30 so that the delivery of mixed water MW is interrupted and the sanitary fitting 1 is closed. To trigger the sanitary fitting 1, a user pivots the actuating member 12 starting from the position 12a upwards. The electronic circuit unit 4 controls the valve 30 such that the sanitary fitting 1 emits the minimum volume flow of the mixed water MW with a predetermined temperature of exemplarily 35 ° C from the outlet 9. If the actuating member 12 is pivoted further upwards, the electronic switching unit 4 controls the valve 30 in such a way that the volume flow of the delivered mixed water MW is increased and in position 12c delivers the maximum volume flow of mixed water MW from the outlet 9. If the actuator 12 is pivoted downward, the electronic circuit unit 4 controls the valve 30 so that the volume flow of the dispensed mixed water MW is reduced and in position 12a the delivery of mixed water MW is interrupted and thus the sanitary fitting 1 is closed again. The temperature is specified in the program of the microcontroller. In a particularly advantageous embodiment, the temperature is designed to be adjustable by means of an adjustment controller or a remote control.

In a further embodiment, the sanitary fitting 1 is also designed so that the valve cover 11 is rigidly connected to the fitting body 2. In position 12a of the actuator 12, the electronic circuit unit 4 controls the valve 30 so that the delivery of mixed water MW is interrupted and the sanitary fitting 1 is closed. To trigger the sanitary fitting 1, a user pivots the actuating member 12 starting from the position 12a upwards. The electronic circuit unit 4 controls the valve 30 such that the sanitary fitting 1 emits the minimum volume flow of the mixed water MW with a predetermined starting temperature of exemplarily 25 ° C from the outlet 9. If the actuator 12 is further pivoted upward, the electronic circuit unit 4 controls the valve 30 in such a way that the volume flow of the delivered mixed water MW is increased and in position 12c the maximum volume flow of mixed water MW is emitted from the outlet 9. When the actuator 12 is pivoted downwardly, the electronic circuit unit 4 controls the valve 30 so as to reduce the volume flow of the dispensed mixed water MW. In the microcontroller control contained in the electronic circuit unit 4 is a program schedule with times and temperatures, for example, 25 ° C for 20 seconds for wetting the hands before lathering followed by 60 seconds 38 ° C for cleaning the hands deposited. The electronic circuit unit 4 then controls the valve 30 such that for the stored times mixed water MW is discharged with the stored temperatures and closes after the program with the electronic valve 30, the sanitary fitting 1. The times and temperatures are specified in the program of microcontroller control. In a particularly advantageous embodiment, the times and / or temperatures are designed to be adjustable with at least one setting controller or a remote control.

In another embodiment, the sanitary fitting 1 is designed so that the Betäti¬gungsorgan 12 is rigidly connected to the dashboard cover 11. With the actuator 12, the temperature of the mixed water MW is adjusted by rotating the dash panel 11 about the vertical axis 11a. The flow meter 45a in the mixed water outlet 45 detects the flow of the effluent mixed water MW and passes the measured values as electrical

Signals to the electronic circuit unit 4, which determines the volume flow of the abgege¬benen mixed water MW in liters per minute. In the stop 12d of the actuator 12, the electronic circuit unit 4 controls the valve 30 so that the discharge of mixed water MW is interrupted and the sanitary fitting 1 is closed. When the actuating member 12 is rotated counterclockwise to the right, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the discharged mixed water MW reaches a predetermined value of, for example, 6 liters per minute and the temperature of the mixed water discharged from the outlet 9 MW corresponds to a predetermined minimum temperature of, for example, 25 ° C. When the actuator 12 is further rotated counterclockwise to the right, the electronic circuit unit 4 controls the valve 30 to increase the temperature of the mixed water MW discharged, and in the right stop 12, the temperature of the mixed water MW discharged from the outlet 9 becomes a predetermined limit, illustratively 38 ° C, does not exceed. This prevents scalding of the user with mixed water MW at too high a temperature. If the actuator 12 is rotated counterclockwise to the left, the electronic circuit unit 4 controls the valve 30derart that the temperature of the mixed water MW delivered is lowered and in the left stop 12d the delivery of mixed water MW interrupted and the sanitary fitting 1 is thus closed. The volume flow, the minimum temperature and the limit temperature are specified in the program of the microcontroller control. In a particularly advantageous embodiment, at least the volumetric flow, the minimum temperature or the limit temperature can be set with an adjustment controller or a remote control.

In an alternative embodiment of the sanitary fitting 1, the electronic circuit unit 4 has a microcontroller control with a predetermined Nachlaufmen¬ge that delays the closing of the valve. Instead of the flow meter 45a, the flow meter 37a in the hot water inlet 37 detects the flow of the inflowing hot water WW and the flow meter 39a in the cold water inlet 39 the flow of the cold water KW flowing in. The flow meters 37a and 39a transmit the measured values as electrical signals to the electronic circuit unit 4. The electronic circuit unit 4 calculates from the sum of the measured values of the flow meters 37a and 39a the volumetric flow of the mixed water MW delivered in liters per minute. When a user brings the actuator 12 into position 12d when closing, the electronic circuit unit 4 controls the valve 30 so that only incoming cold water KW flows out of the mixed water outlet 45, determines the follow-up quantity and closes the sanitary fitting 1 with the valve 30, when the predetermined amount of trailing has risen for purging by the jet regulator 8. By flushing with cold water KW all with the inflowing hot water WW from the building-side hot water installation not shown in the sanitary fitting 1 flushed microorganisms are flushed out through the mixed water outlet 45, the outlet pipe 10 and the jet regulator 8. The follow-up amount of exemplarily 100 ml is specified in the program of the microcontroller control. In a particularly advantageous embodiment, the follow-up quantity is adjustable with an adjustment controller or a remote control.

In an alternative embodiment, the valve cover 11 of the sanitary fitting 1 is rigidly connected to the fitting body 2. With the actuator 12 of the Volumen¬strom and the temperature of the mixed water MW are adjusted by each position of the Actu¬ gungsorgans 12, for example, per degree of angle a, a certain volume flow of a certain temperature of the delivered mixed water MW corresponds. In the position 12ades of actuator 12 controls the electronic circuit unit 4, the valve 30 such that the delivery of mixed water MW interrupted and the sanitary fitting 1 is so geschlos¬sen. To trigger the sanitary fitting 1, a user pivots the actuator 12 from the position 12a upwards. The electronic circuit unit 4 then controls the valve 30 such that the sanitary fitting 1 delivers the minimum volume flow of the mixed water MW with the temperature of the inflowing cold water KW from the outlet 9. If the actuating member 12 is pivoted further upwards, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the dispensed

Mixed water MW is increased and in position 12b the maximum volume flow of the mixed water MW with the temperature of the incoming cold water KW from the outlet 9 outputs. When the actuator 12 is further pivoted upwardly beyond the position 12b, the electronic circuit unit 4 controls the valve 30 so that the volume flow remains unchanged but the temperature of the mixed water MW discharged is increased and at the position 12c the temperature of the mixed water MW discharged from the outlet 9 does not exceed a predetermined limit of, for example, 38 ° C. This prevents the brewing of a user with mixed water MW with too high a temperature. When the actuator 12 is between positions 12c and 12b and the actuator 12 is pivoted downwardly, the electronic circuit unit 4 controls the valve 30 to reduce the temperature of the dispensed mixed water MW and, in the position 12b, the sanitary fitting 1 only mixing water MW with the temperature of zuströ¬menden cold water KW gives off. If the actuator 12 is pivoted further down, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the mixed water MW delivered is reduced and the delivery of mixed water MW interrupts in the position 12a and the sanitary fitting 1 is closed again. The limit value for the mixed water temperature is specified in the program of the microcontroller control. In a particularly advantageous embodiment, the limit value is adjustable with a setting controller or a remote control.

In a similar embodiment, the sanitary fitting 1 is designed so that the Betäti¬gungsorgan 12 is rigidly connected to the dashboard cover 11. With the actuator 12, the volume flow and the temperature of the mixed water MW are adjusted by rotating the armature hood 11 about the vertical axis 11a. In the position 12d of the Betätigungsor¬gans 12, the electronic circuit unit 4 controls the valve 30 such that the dispensing of mixed water MW interrupted and the sanitary fitting 1 is closed. To trigger the sanitary fitting 1, a user rotates the actuator 12 from the position 12d counterclockwise to the right. The electronic circuit unit 4 then controls the valve 30 in such a way that the sanitary fitting 1 delivers the minimum volume flow of the mixed water MW with the temperature of the incoming cold water KW out of the outlet 9. If the actuating member 12 is rotated further to the right, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the delivered mixed water MW is increased and in position 12b 'the maximum volume flow of the mixed water MW with the temperature of the incoming cold water KW from the Spout 9 delivers. If the actuator 12 is rotated further to the right via the position 12b ', the electronic circuit unit 4 controls the valve 30 so that the volume flow remains unchanged, but the temperature of the mixed water MW delivered is increased and in position 12e the temperature of the Outlet 9 delivered mixed water MW does not exceed a predetermined limit of example 38 ° C. This prevents the scalding of a user with mixed water MW at too high a temperature. When the actuator 12 is between positions 12e and 12b 'and the actuator 12 is rotated counterclockwise to the left, the electronic circuit unit 4 controls the valve 30 to reduce the temperature of the mixed water MW discharged and in position 12b' the sanitary fitting 1 only mixed water MW with the temperature of zuströ¬menden cold water KW gives off. If the actuating member 12 is further rotated to the left, the electronic circuit unit 4 controls the valve 30 such that the volume flow of the dispensed mixed water MW is reduced and the dispensing of mixed water MW interrupts in the position 12d and the sanitary fitting 1 is closed again. The limit value for the mixing water temperature is specified in the program of the microcontroller control. In a particularly advantageous embodiment, the limit value is designed to be adjustable by means of an adjustment controller or a remote control.

In a particular embodiment, the sanitary fitting 1 has a stagnation flushing unit 4g, which determines the need for a stagnation-free flushing 56a, b (FIG. 6) and generates electrical control signals for the demand-triggered triggering of a stagnation release flush. The stagnation rinsing unit 4g is exemplified as a microelectronic assembly on a circuit board with a connection for the temperature sensor 22 and beispiel¬haft arranged in the fitting body 2, coupled via not shown signal lines with the electronic circuit unit 4 and stores the closing time as the time at which the electronic Circuit unit 4 by controlling the valve 30 interrupts the delivery of mixed water MW and thus closes the sanitary fitting 1.

The stagnation rinsing unit 4g calculates periodically, by way of example every second, the stagnation time as the time which has elapsed since the closing time and which lingers the stagnation water 46 in the sanitary fitting 1. During the periodic calculation of the stagnation time, the stagnation rinsing unit 4g detects with the temperature sensor 22 the temperature of the rinsing mixed water MW in the area of the mixed water outlet 45, which corresponds for the most part to the temperature of the stagnation water 46, determined from a temperature difference of the table stored in the program memory resting mixed water MW of the ideal for the multiplication of microorganisms temperature of spielsweise 30 ° C, the risk for the proliferation of possibly stagnation water 46 befindli microorganisms and integrates this risk as value R (Figure 6) from the closing time , If the value R (FIG. 6) exceeds a predetermined limit value RG (FIG. 6), then the stagnation purging unit 4g activates a stagnation purging56a, b (FIG. 6) independently of the position of the actuating member 12 as required via the electronic circuit unit 4 ), so that mixed water MW and possibly contained therein Mikroorganis¬men displaced by the mixed water outlet 45 since the closing time in the sanitary fitting 1aushalt stagnation water 46 through the outlet pipe 10 in the usual Wasserentnahme by a user serving spout 9 and by the jet regulator 8 exits the sanitary fitting 1. If the entire volume of water in the sanitary fitting 1 exchanged, the electronic circuit unit 4 closes the valve 30 and the Stagnationsspü¬leinheit 4g stores the new closing time. The limit value RG (FIG. 6) and the water volume of the sanitary fitting 1 are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value RG (FIG. 6) is made adjustable by means of an adjustment controller or a remote control.

In an alternative embodiment of the terminal sanitary fitting 1, not only the stagnation water 46 from the sanitary fitting 1, but also the water stagnant in the hot water hose 6, in the cold water hose 7 and in parts of the building-side water installation, not shown, is exchanged. If the value R (FIG. 6) exceeds a predefined limit value, the stagnation flushing unit 4g triggers a stagnation-free flushing 56a, b (FIG. 6) via the electronic circuit unit 4 independently of the position of the actuating member 12, so that it flows through the hot water hose 6 Mendes hot water WW and the cold water hose 7 incoming cold water KW is discharged through the mixed water outlet 45 and since the closing time in Warmwas¬serschlauch 6, the cold water hose 7 and the sanitary fitting 1 lingering stagnation water 46 displaced by the outlet pipe 10 into the outlet 9 and through the jet regulator 8ausaustritt the sanitary fitting 1. After expiration of the predetermined Stagnationsspüldauer example of 10 seconds, the electronic circuit unit 4 closes the valve 30. The Stagnationsspüldauer is specified as a parameter contained in the electronic circuit unit 4 contained microcontroller. In a particularly advantageous embodiment, the Stagnationsspüldauer is executed with a Einstellregler or a remote control adjustable.

In an alternative embodiment, the electronic circuit unit 4 during the Stagnationsfreispülung 56a, b (Figure 6) continuously determines the amount of the delivered mixed water MW and compares them with the predetermined Stagnationsspülmenge of beispiel¬haft a liter. If the stagnation flushing quantity is reached, the electronic circuit unit 4 closes the valve 30. The stagnation flushing quantity is predetermined as a parameter of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the degree of stagnation flushing is carried out with an adjustable controller or a remote control.

In another embodiment of the terminal sanitary fitting 1 controls the elekt¬ronic circuit unit 4 during the Stagnationsfreispülung 56a, b (Figure 6), the valve 30derart that the flow of the inflowing hot water WW and the inflowing cold water KW approximately equal are big. This ensures that both the hot water hose 6 and the water stagnated in the cold water hose 7 are flushed out through the sanitary fitting 1. In a further embodiment, by readjustment of the valve 30, the electronic circuit unit 4 limits the temperature of the dispensed mixed water MW to a predetermined maximum temperature and thus prevents possible scalding if a user inserts the stagnation rinse 56a, b (FIG effluent water jet 21 attacks. The maximum temperature of, for example, 37 ° C. is predetermined as a parameter of the microcontroller control included in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum temperature is designed to be adjustable with an adjusting controller or a remote control.

In an alternative embodiment of the terminal sanitary fitting 1, the electronic circuit unit 4 controls the valve 30 during the stagnation rinse 56a, b (FIG. 6) such that the volume flow of the mixed water MW delivered during the stagnation rinse 56a, b (FIG is limited to a maximum value. The maximum value of one liter per minute is below the volume flow of 6 liters per minute when triggered by a user. The limitation of the volume flow limits the impact force of the water jet 21 and thus also largely prevents the occurrence of flow noise that is perceived as disturbing by the user during normal use periods, especially during nocturnal rest periods. The maximum value of the volume flow is predetermined as a parameter of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum value of the Vo¬lumenstroms is made adjustable with an adjustment or a remote control or is determined by the electronic circuit unit 4 from the maximum volume flow when triggered by a user using mathematical formulas or a table of values.

In a further embodiment, the electronic Schaltungsein¬ unit 4 comprises a real-time clock 4h, which is exemplified as a microelectronic assembly on a printed circuit board and connected via signal lines, not shown, with the electronic Schaltungs¬ unit 4 and the Stagnationsspüleinheit 4g. In the memory of the real time clock 4h, a table with time windows and maximum volume flows for the stagnation purging system 56a, b (FIG. 6) is filed for each day of the week. By way of example, the table is designed so that the maximum values during the rest periods during the day at 1 liter per minute, and thus under the volume flow of 6 liters per minute when triggered by a user and outside the rest periods during the day at 9 liters per minute and thus above the flow rate of 6 liters per minute when triggered by a user and at night at 0 liters per minute and thus a nightly Stagnationsfreispülung 56a, b (Figure 6) is completely prevented. The stagnation purging unit 4g forwards the command for triggering the stagnation purging 56a, b (FIG. 6) to the real-time clock 4h. This determines the appropriate time window and transmits the elekt¬ronischen circuit unit 4 the stored in the table maximum value for the volume flow. The electronic circuit unit 4 then controls the valve 30 in such a way that the volumetric flow of the mixed-water MW discharged during the stagnation-free flushing 56a, b (FIG. 6) is limited to this maximum value. As a result, the emergence of flow noise is largely avoided or completely prevented during the breaks. Outside the breaks, a higher flow rate of the water is achieved by the higher volume flow and thus the rinsing effect possibly on the walls of Warmwas¬serschlauches 6, the cold water hose 7, the water-bearing parts of the sanitary fitting 1oder not shown building-side water installation stuck microorganisms. In a particularly advantageous embodiment, the values stored in the table are designed to be adjustable with an adjusting dial or a remote control and / or the stagnation flushing unit 4g and / or the real-time clock 4h together with their components and connections as microelectronic subassemblies on the printed circuit board of the electronic circuit unit 4integriert.

In a further embodiment of the sanitary fitting 1, the power supply 3 is designed as a power supply with the connecting line 5 for connection to the building-side Netz¬versorgung.

In a particularly advantageous embodiment of the sanitary fitting 1, the Energiever¬ supply 3 is designed as a generator, the turbine energy from the sanitary fitting 1durchströmenden water as a thermal energy from the temperature difference between the incoming hot water WW and the incoming cold water KW, between demzuströmenden Hot water WW and the ambient air surrounding the valve or / and ambient air surrounding the fitting, as solar cell or photodiode energy from the Umge¬bungshelligkeit acting on the sanitary fitting 1, as Radiofrequency Energy Harvester energy from the electromagnetic fitting on the sanitary fitting 1 Waves, as a sound energy harvester energy from the ambient noise acting on the sanitary fitting 1 and / or as a piezoelectric EnergyHarvester energy from pressure fluctuations of the hot water WW and / or the KaltwassersKW into electrical energy umw andelt.

As a result, the sanitary fitting 1 is operated energy self-sufficient.

In an alternative embodiment of the terminal sanitary fitting 1, the microcontroller included in the electronic circuit unit 4 stores the time of triggering as timing at which it releases the discharge of mixed water MW by driving the valve 30 and closes the valve 30 regardless of the position of the actuator 12 a maximum runtime and thereby prevents flooding of the Waschbe¬ckens. The maximum transit time is predetermined as a parameter of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum transit time is adjustable with an adjustment controller or a remote control.

In a further embodiment of the sanitary fitting 1, the microcontroller contained in the elektroni¬schen circuit unit 4 stores the time of triggering as the time at which it releases the delivery of mixed water MW by controlling the valve 30 integrated over the runtime, the volume flow of the mixed water delivered MW to determine the amount delivered, regardless of the position of the Actu¬ gungsorgans 12 closes the valve 30 after delivery of a maximum amount, thereby preventing Überzufuten the washbasin. The maximum amount is specified as a parameter of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum amount is designed to be adjustable by means of an adjustment controller or a remote control.

2 shows a continuation of Fig. 1, a terminal plumbing fixture 1a, which is beispiel¬haft mounted on a sink, not shown, with a temperature sensor 25 for detecting the temperature of the incoming hot water WW, a temperature sensor 26 for detecting the temperature of the incoming Cold water KW, a temperature sensor 27 for detecting the temperature of the stagnation water 46 in the region of StagnationsniveausS and a temperature sensor 28 for detecting the temperature of the fitting body 2. The measured values of the temperature sensors 25,26,27,28 are passed as electrical signals to the elektroni¬sche circuit unit 4 which detects the temperature readings of the temperature sensors 25, 26, 27, 28. Further, the sanitary fitting 1a includes a proximity sensor 29 having the response area 29a. The response range 29a is designed such that an object, for example a user's hand, is secured in the area below the outlet 9 and in front of it. The proximity sensor 29 is connected to the electronic circuit unit 4, which triggers the sanitary fitting 1a and opens the valve 30 in the presence of a hand in the response area 29a regardless of the Stel¬lung of the actuator 12. The electronic circuit unit 4 controls, via the valve 30, the temperature and the volumetric flow of the mixed water MW during use, which ends as soon as a user removes the hand from the response area 29a.

In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 has a microcontroller control with a predetermined timed volumetric flow and temperature profile, which is executed by the microcontroller control when a user puts his hand in the response region 29a of the proximity sensor 29. Das Profile includes times, flows and temperatures, illustratively 1 liter per minute 34 ° C for 20 seconds to wet hands before soaping followed by a 30 second pause for soapy followed by 5 minutes 6 liters per minute 38 ° C for thorough cleaning the hands. The electronic circuit unit 4 thereupon controls the valve 30 in such a way that mixed water MW with the stored volume flows and temperatures is released for the times stored and closes the sanitary fitting 1a after the program has elapsed with the electronic valve 30. The volumetric flows, times and temperatures are specified in the program of the microcontroller control. In a particularly advantageous embodiment, the volume flows, times and / or temperatures are designed to be adjustable with at least one setting controller or a remote control.

In a similar embodiment of the sanitary fitting 1a, the electronic circuit unit 4 has a microcontroller control with a predetermined volume flow and temperature profile, which is processed by the microcontroller control when a user puts his hand in the response region 29a of the proximity sensor 29. Das Profile includes amounts, flows and temperatures, for example 1/4 liter at 1 liter per minute 34 ° C for wetting hands before lathering followed by 10 liters at 6 liters per minute 38 ° C for thorough cleaning of the hands. The electronic circuit unit 4 inte¬griert over the runtime the volume flow of the mixed water MW dispensed to determine the amount delivered and controls the valve 30 so that the deposited amounts of mixing water MW are discharged with the stored volumetric flows and temperatures and closes after the program with the electronic valve 30 the sanitary fitting1a. The volume flows, quantities and temperatures are specified in the program of Mikrocontrollersteu¬erung. In a particularly advantageous embodiment, the volume flows, quantities and / or temperatures with at least one adjustment or remote control are adjustable.

In a particular embodiment of the sanitary fitting 1a, the electronic circuit unit 4 has a microcontroller control with a predetermined delay time which delays the closing of the sanitary fitting 1a after the removal of the hand from the response region 29a of the proximity sensor 29. After expiration of the follow-up time of, for example, one second, the electronic circuit unit 4 with the valve 30 controls the flow of the mixed water MW such that the water jet 21 continuously decays. The follow-up time is specified in the program of the microcontroller control. In a particularly advantageous embodiment, the follow-up time is adjustable with an adjustment knob or a remote control.

In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 has a microcontroller control with a predetermined amount of delay, which delays the closing of the sanitary fitting 1a after the removal of the hand from the Ansprechbereich29a of the proximity sensor 29. After removing the hand from the Ansprech¬ range 29a integrates the electronic circuit unit 4 over the run the Volumen¬strom of the delivered mixed water MW to determine the amount delivered and closes with the valve 30, the sanitary fitting 1a, when the predetermined follow-up amount of mixed water mixed MW through the Jet regulator 8 has leaked. The follow-up amount of, for example, 100 ml is specified in the program of the microcontroller control. In a particularly advantageous embodiment, the follow-up amount is executed adjustable with a Einstellregler or a remote control.

In an alternative embodiment of the sanitary fitting 1a stores the electronic

Circuit unit 4, the time of opening of the valve 30 and closes the valve 30 after a maximum delay, even if there is still an object in the response region 29a of the proximity sensor 29 and thereby prevents flooding of the sink when an object is turned off in the response area 29a. The maximum transit time is predetermined as a parameter of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum transit time is adjustable with an adjustment knob or a remote control.

In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 stores the time of opening of the valve 30, integrates the volume flow of the dispensed mixed water MW over the running time to determine the amount dispensed and closes the valve 30 after delivering a maximum amount, even if there is still an object in the response area 29a of the proximity sensor 29 and thereby prevents overflow of the washbasin when an object in the response area 29a is turned off. The maximum quantity is predetermined as a parameter of the microcontroller controller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the Maxi¬malmenge with an adjustment or a remote control is made adjustable.

In a particular embodiment of the sanitary fitting 1a, the electronic circuit unit 4 triggers the sanitary fitting 1a by approaching an object in the Ansprechbereich29a of the proximity sensor 29 or by actuation of the actuator 12, opens the valve 30 and closes the valve 30 again after removing the Object from the An¬sprechbereich 29a, the actuation of the actuator 12, the expiry of the maximum runtime or the delivery of the maximum amount of mixed water MW.

In an alternative embodiment, the sanitary fitting 1a has a stagnation flushing unit 4g with connections for the temperature sensors 22, 25, 26, 27, 28. The stagnation purging unit 4g detects the temperature of the cold water KW during the periodic calculation of the stagnation time, for example every minute, with the temperature sensor 26. If the temperature of the cold water KW exceeds a limiting value of, for example, 25 ° C., the stagnation flushing unit 4g calls for cold water flushing as required and the electronic switching unit 4 controls the valve 30 such that only incoming cold water KW is discharged through the mixed water outlet 45 and without being triggered a user stagnated in the course of a Stagnationsfreispülung 56a, b (Figure 6) since the closing time stagnated water through the outlet pipe 10 into the outlet 9 and exits through the jet regulator 8 from the sanitary fitting 1a. If the temperature of the cold water KW falls below the limit value and remains below it for a predetermined observation time of, for example, 30 seconds, the electronic circuit unit 4 closes the valve 30 and terminates the stagnation purging 56a, b (FIG. 6). The limit value for the temperature of the cold water KW and the observation time are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the observation time can be set with a setting controller or a remote control. In a further embodiment of the sanitary fitting 1, the electronic circuit unit 4 closes the valve 30 after a maximum running time has elapsed or a maximum amount has been released. The maximum running time or the maximum amount are specified as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum runtime or the maximum amount are adjustable with an adjustment knob or a remote control.

In another embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g detects the temperature of the cold water KW during the periodic calculation of the stagnation time, by way of example four times per second, with the temperature sensor 26. If the temperature of the cold water KW exceeds a limiting value of, for example, 25 ° C., the stagnation flushing unit 4g requests cold water flushing on demand and the electronic circuit unit 4 controls the valve 30 in such a way that exclusively incoming cold water KW is discharged through the mixed water outlet 45 and without triggering by a user in the course of a stagnation rinsing 56a, b (FIG. 6), the water stagnant since the closing time has been displaced through the outlet pipe 10 into the outlet 9 and exits the sanitary fitting 1a through the jet regulator 8. If the temperature of the cold water KW falls below the limit value minus a hysteresis of, for example, 3 ° C., the electronic circuit unit 4 closes the valve 30 and thus terminates the stagnation purging 56a, b (FIG. 6). The limit value for the temperature of the cold water KW and the hysteresis are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the hysteresis are designed to be adjustable with a setting controller or a remote control. In a further design of the sanitary fitting 1a, the electronic circuit unit 4 closes the valve 30 after a maximum running time or delivery of a maximum amount. The maximum running time or the maximum amount are predetermined as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum running time or the maximum amount are adjustable with an adjusting dial or a remote control.

In a further embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g detects the temperature of the hot water WW during the periodic calculation of the stagnation time with the temperature sensor 25. If the temperature of the hot water WW drops below a threshold value of, for example, 55 ° C, the stagnation flushing unit 4g requests demand-controlled hot water flushing and the electronic circuit unit 4 controls the valve 30 so that only inflowing warm water WW is discharged through the mixed water outlet 45 and without triggering by a user in the course of a Stagnationfreispü¬lung 56a, b (Figure 6) the stagnant since the closing time water displaced by the outlet pipe 10 in the outlet 9 and exits through the jet regulator 8 from the sanitary fitting 1a. If the temperature of the hot water WW rises above the limit value and remains above it for a given observation time of, for example, 10 seconds, then the electronic circuit unit 4 closes the valve 30 and terminates the stagnation purging 56a, b (FIG. 6). The limit value for the temperature of the hot water WW and the observation time are pre-defined as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the observation time are designed to be adjustable with an adjustment controller or a remote control. In a refinement of the sanitary fitting 1a beyond this, the electronic circuit unit 4 closes the valve 30 after the expiration of a maximum operating time or delivery of a maximum quantity. The maximum running time or the maximum amount are predetermined as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum running time or the maximum amount are designed to be adjustable by means of a setting controller or a remote control.

In another embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g detects the temperature of the hot water WW during the periodic calculation of the stagnation time with the temperature sensor 25. If the temperature of the hot water WW drops below a threshold value of, for example, 55 ° C, the stagnation flushing unit 4g requests demand-controlled hot water flushing and the electronic circuit unit 4 controls the valve 30 so that only inflowing warm water WW is discharged through the mixed water outlet 45 and without triggering by a user in the course of a Stagnationfreispü¬lung 56a, b (Figure 6) the stagnant since the closing time water displaced by the outlet pipe 10 in the outlet 9 and exits through the jet regulator 8 from the sanitary fitting 1a. If the temperature of the hot water WW rises above the threshold plus a hysteresis of, for example, 3 ° C, the electronic circuit unit 4 closes the valve 30 and then terminates the stagnation purging 56a, b (Figure 6). The limit value for the temperature of the hot water WW and the hysteresis are specified as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the hysteresis can be set with a setting controller or a remote control. In a further embodiment of the sanitary fitting, the electronic circuit unit 4 closes the valve 30 after a maximum running time has elapsed or after a maximum amount has been dispensed. The maximum runtime or the maximum amount are as

Parameter of the microcontroller contained in the electronic circuit unit 4 preset. In a particularly advantageous embodiment, the maximum runtime or the maximum amount are adjustable with an adjustment knob or a remote control.

In an alternative embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g detects the temperature of the fitting body 2 during the periodic calculation of the stagnation time with the temperature sensor 28. If the temperature of the fitting body 2 exceeds a limit of, for example, 24 ° C, the stagnation flushing unit 4g calls for a cold water flushing on demand and the electronic circuit unit 4 controls the valve 30 in such a way that in the course of a stagnation purging 56a, b (FIG. 6) exclusively incoming cold water KW is discharged through the mixed water outlet 45 and exits the sanitary fitting 1a through the jet regulator 8. If the temperature of the fitting body 2 falls below the limit value and remains below it for a predetermined observation time of, for example, 30 seconds, then the electronic circuit unit 4 closes the valve 30 and terminates the stagnation purging 56a, b (FIG. 6). The limit value for the temperature of the fitting body 2 and the observation time are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the observation time can be set with an adjustment controller or a remote control. In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 closes the valve 30 at the end of a maximum running time or after delivery of a maximum amount. The maximum running time or the maximum amount are set as parameters of the microcontroller included in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum running time or the maximum amount can be set with a setting controller or a remote control.

In another embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g detects the temperature of the fitting body 2 during the periodic calculation of the stagnation time with the temperature sensor 28. If the temperature of the fitting body 2 exceeds a limit of, for example, 24 ° C, the stagnation flushing unit 4g calls for a cold water flushing on demand and the electronic circuit unit 4 controls the valve 30 in such a way that in the course of a stagnation purging 56a, b (FIG. 6) exclusively incoming cold water KW is discharged through the mixed water outlet 45 and exits the sanitary fitting 1a through the jet regulator 8.

When the temperature of the fitting body 2 falls below the threshold minus a hysteresis of, for example, 1 ° C, the electronic circuit unit 4 closes the valve 30 and thus terminates the stagnation purging 56a, b (Fig. 6). The limit value for the temperature of the fitting body 2 and the hysteresis are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the hysteresis are designed to be adjustable by means of an adjustment controller or a remote control. In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 closes the valve 30 after a maximum run time or after a maximum amount has been dispensed. The maximum running time or the maximum amount are set as parameters of the microcontroller included in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum running time or the maximum amount can be set with a setting controller or a remote control.

In an alternative embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g determines the temperature of the stagnation water 46 during the periodic calculation of the stagnation time from the values of at least one of the temperature sensors 22, 27, 28. The temperature of the stagnation water 46 exceeds this a limiting value of, for example, 24 ° C., the stagnation flushing unit 4g stimulates a cold water flushing as required and the electronic circuit unit 4 controls the valve 30 in such a way that exclusively cold water KW flowing in as part of a stagnation freewheeling 56 a, b (FIG is discharged through the Mischwasserabgang45 and exits through the jet regulator 8 from the sanitary fitting 1a. Is that sinking?

Temperature of the stagnation water 46 below the limit and it remains for a predetermined observation time of example 30 seconds below, the electronic circuit unit 4 closes the valve 30 and terminates the Stagnationsfreispülung 56a, b (Figure 6). The limit value for the temperature of the stagnant water 46 and the observation time are set as parameters of the microcontroller controller included in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the observation time can be set with an adjustment controller or a remote control. In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 closes the valve 30 at the end of a maximum running time or after delivery of a maximum amount. The maximum running time or the maximum amount are predetermined as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum runtime or the maximum amount are made adjustable with an adjusting dial or a remote control.

In another embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g determines the temperature of the stagnant water 46 from the values of at least one of the temperature sensors 22, 27, 28 during the periodic calculation of the stagnation time. If the temperature of the stagnation water 46 exceeds a limit of, for example, 24 ° C, the stagnation rinsing unit 4g requests cold water scavenging as required and the electronic circuit unit 4 controls the valve 30 so that only cold water HC flowing in through a blended water outlet 45 is discharged in the course of a stagnation rinse56a, b (FIG. 6) and exits the sanitary fitting 1a through the jet regulator 8 , When the temperature of the stagnant water 46 drops below the threshold minus a hysteresis of 1 ° C at a time, the electronic circuit unit 4 closes the valve 30, thus completing the stagnation purging 56a, b (Fig. 6). The limit value for the temperature of the stagnation washer 46 and the hysteresis are specified as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the limit value and / or the hysteresis are designed to be adjustable with an adjustment controller or a remote control. In a further embodiment of the sanitary appliance 1a, the electronic circuit unit 4 closes the valve 30 after a maximum running time or after delivery of a maximum amount. The maximum transit time or the maximum amount are specified as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the maximum runtime or the maximum amount are executed with an adjustable controller or a remote control adjustable.

In a further embodiment of the sanitary fitting 1a, the stagnation flushing unit 4g determines the temperature of the water stagnant in the sanitary fitting 1a in the periodic calculation of the stagnation time from the values of the temperature sensors 22, 25, 26, 27, 28. In the program memory Tables or formulas are provided which describe the functional relationship between the recorded temperatures and the temperatures which are ideal for the multiplication of microorganisms and the resulting risks for the multiplication of any microorganisms present in the stagnation water 46. When calculating the stagnation time, the stagnation purging unit 4g continuously forms the weighted mean of the risks. If the value R (FIG. 6) exceeds the integrated weighted mean value of the risks since the valve 30 has been closed, a predetermined limit value RG (FIG. 6), the station flushing unit 4g requests a purging as required and controls the electronic circuit unit 4 the valve 30 such that in the course of Stagnationsfreispülung 56a, b (Figure 6) exclusively inflowing hot water WW is discharged through the mixed water outlet 45 and the stagnated since the closing time in the sanitary fitting 1a and in the hot water hose 6 through the outlet pipe 10 into the outlet 9 displaced and exits the sanitary fitting 1a through the jet regulator 8. When the sanitary fitting 1a is triggered by a user, the electronic circuit unit 4 breaks off the stagnation purging 56a, b (FIG. 6) and regulates the position of the valve 30 to the setpoint values for temperature and volumetric flow of the mixed water MW, thereby preventing scalding of a user. After rinsing out the hot water hose 6, the electronic circuit unit 4 controls the valve 30 so that only inflowing cold water KW is discharged through the Mischwas¬serabgang 45, the stagnated since the closing time in the sanitary fitting 1a and 7 in the cold water hose water through the outlet pipe 10 in the outlet. 9 displaced, the fitting body 2 cools and exits without triggering by a user through the Strahlreg¬ler 8 from the sanitary fitting 1a. If the sanitary fitting 1a is released by a user, the electronic circuit unit 4 breaks the stagnation purging 56a, b (FIG. 6) and regulates the position of the valve 30 to the setpoint specifications for the temperature and volume flow of the mixed water MW. If the temperature of the fitting body 2 detected by the temperature sensor 28 is approximately cooled to the temperature of the cold water KW detected by the temperature sensor 26, the electronic circuit unit 4 closes the valve 30. The limit value RG (FIG. 6) is used as a parameter in the electronic circuit unit 4 specified microcontroller specified. In a particularly advantageous embodiment, the limit value RG (FIG. 6) is designed to be adjustable by means of an adjustment controller or a remote control.

In a particular embodiment of the sanitary fitting 1a, the microcontroller control contained in the electronic circuit unit 4 stores at least one of the operating parameters, such as setpoint values for temperature and volumetric flow, actual values of the temperature sensors 22, 25, 26, 27, 28, and for documentation purposes Flow meter 37a, 39a, 45a the timing of the triggering and closing of the valve 30 on a storage medium 48. The Spei¬chermedium 48 is exemplified by the internal memory of the microcontroller contained in the electronic circuit unit 4, a USB stick or a memory card.

In a further embodiment of the sanitary fitting 1a, the control line 23 is designed as a bus for transmitting operating parameters, such as setpoint values for temperature and volume flow, actual values of the temperature sensors 22, 25, 26, 27, 28 and the flow meters 37 a, 39 a, 45 a and the times of Triggering and closing, from the electronic circuit unit 4 to an unillustrated control system. In a particularly advantageous embodiment, the bus line for remote control of the sanitary fitting 1a is formed by transmitting corresponding signals and / or commands from the not-shown control system to the electronic circuit unit 4. In an alternative embodiment, the sanitary appliance 1a contains the radio module 24 for the wireless triggering of a disinfecting rinse and / or for the wireless transmission of operating parameters, such as setpoint values for temperature and volume flow, actual values of the temperature sensors 22, 25, 26, 27, 28 and the flow meter 37a, 39a, 45a and the times of triggering and closing by means of electromagnetic waves, by way of example in an ISM band or in the infrared range or by means of sound waves, for example in the ultrasonic range.

In a further embodiment of the sanitary fitting 1a, the electronic circuit unit 4 compares the sum of the measured values of the flow meters 37a and 39a with the measured value of the flow meter 45a and, in the event of deviations via the control line 23 or the radio module 24, transmits a fault message to an unillustrated control system.

The proximity sensor 29 is embodied by way of example as an infrared sensor, ambient light sensor, capacitive sensor, radar sensor, temperature sensor, ultrasonic sensor or camera with image evaluation.

In a further embodiment of the sanitary fitting 1a, the valve 30 is formed as a solenoid valve or proportional valve.

3 shows, in continuation to FIG. 1, a terminal sanitary fitting 1b, which is designed as a flush-mounted shower fitting. The fitting body 2 is a Unterputz- box with front panel, which is flush with the tile wall 19. An operating device 47 is arranged in the flush-mounted box, which comprises in the front cover an actuating element 12 designed as a +/- button for adjusting the temperature of the water jet 21 flowing out of the outlet 9. The outlet 9 here is a shower head with a water jet 21 forming jet regulator 8 for the delivered mixed water MW. In the actuator 12, the actuator 12f is indicated as + / " Button for adjusting the volume flow of the mixed water discharged MW as well as the actuator 12 g, which is designed as a start / stop button for the triggering of the water jet 21. By actuating the start / stop button, the user 18 triggers the sanitary fitting 1b and the electronic circuit unit 4 opens the valve 30. After pressing the start / stop button again by the user 18, the electronic circuit unit 4 closes the valve 30.

In a further embodiment of the sanitary fitting 1b, the electronic circuit unit 4 closes the valve 30 as soon as the user 18 leaves the detection area 29a, which essentially comprises the spatial area in which the user 18 is staying during the use of the sanitary fitting 1b ,

In another embodiment of the sanitary fitting 1b, the electronic switching unit 4 opens the valve 30 as soon as the user 18 enters the detection area 29a of the proximity sensor 29.

The sanitary fitting 1b further includes a temperature sensor 20 connected to the electronic circuit unit 4, which detects the temperature of the body or a body part of the user 18 in front of the sanitary fitting 1b. In a particular embodiment, the temperature sensor 20 is disposed in the actuator 47. When the user 18 actuates one of the keys of the actuators 12, 12f, 12g, the temperature sensor 20 simultaneously detects the temperature of the user's hand 18.

The temperature sensor 20 is exemplified as a PTC PTC thermistor, NTC hot conductor, Thermo¬element, Pt100, Pt1000, pyrometer, passive infrared sensor, thermopile or thermal imaging camera performed image evaluation.

When triggered, the electronic circuit unit 4 controls the position of the valve 30 such that the temperature of the dispensed mixed water MW substantially corresponds to the temperature of the user 18 detected by the temperature sensor 20. As a result, insbeson¬dere ensured in public showers that the water jet 21, regardless of the setting by the previous user 18 has a ange¬nehme for the current user 18 temperature.

In a sanitary fitting 1b designed in addition, the electronic circuit unit 4 applies a value ΔΤ to the setpoint value for the temperature of the delivered mixed water MW derived from the temperature-derived desired value detected by the temperature sensor 20. As a result, in particular when detecting the temperature of a body part, for example the hand of the user 18, the circumstance can be compensated for that the temperature of the hand is usually lower than the body temperature. The value .DELTA.Τ for the application is predetermined as a parameter of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, the value .DELTA.Τ for the application of an adjustment or a remote control is adjustable. By way of example, the setting controller is designed such that at least one desired value is determined from gestures of the user 18, which are detected by at least one of the actuators 12, 12f, 12g and / or the proximity sensor 29 and evaluated by the microcontroller contained in the electronic circuit unit 4 Memory of the Mikrocontrollersteu¬erung is stored.

In a further refinement, the sanitary fitting 1b has the display 49 for displaying temperatures. If there is no user 18 in the response area 29a, the display 49 is switched off. If the user 18 enters the detection area 29a, the electronic circuit unit 4 determines the setpoint temperature from the measured value of the temperature sensor 20 and displays it flashing on the display 49. As soon as the user 18 activates the plumbing fixture 1b by actuating the start / stop button, the electronic circuit unit 4 opens the valve 30 and regulates the temperature of the mixed water MW discharged to correspond to the setpoint temperature. Since it is not ensured at the time of release that the temperatures of the adjacent hot water WW and the adjacent cold water KW

Mixing to the setpoint temperature is possible, the electronic circuit unit 4 displays the setpoint temperature of the mixed water MW as long as it blinks until the actual temperature detected by the temperature sensor 22 has approximately reached the setpoint temperature. Subsequently, the display 49 permanently shows the actual temperature of the mixed water MW. If the user 18 changes the setpoint value by actuating the +/- key of the actuating member 12, the electronic circuit unit 4 once again flashes the setpoint temperature of the mixing water MW on the display 49 until the actual temperature has approximately reached the setpoint temperature.

In a further refinement, the electronic circuit unit 4 displays the volume flow of the water jet 21 on the display 49.

In an alternative embodiment, the electronic circuit unit 4 visualizes on the display 49 a Stagnationsfreispülung 56a, b (Figure 6) and / or a Desinfektionsspülung.Die visualization is an example text message, in graphical form, with a blinking or glowing lamp or by changing at least one font attribute min¬destens a display value, for example, the font, font color or font size.

In further embodiments, the actuators 12,12f are marked with other inscriptions and / or pictograms, for example "warm / cold", "hot / cold", or in red and blue color for the buttons for setting the temperature and "more / less", "more / less" or a small and a large drop for the keys for setting the volume flow.

In a particularly advantageous embodiment, the proximity sensor 29 comprises a receiver for electromagnetic waves and determines the position of the user 18 from the Doppler shifts caused by movements of the user 18 and / or from the changes in the field strength of the electromagnetic field surrounding the sanitary fitting 1b.

In another embodiment, the sanitary fitting 1b has at least one further response region 29b. When the user 18 approaches the sanitary fitting 1b, he first traverses the response region 29b and then enters the response region 29a, which essentially comprises the spatial region in which the user 18 stays during the use of the sanitary fitting 1b. The response area 29b is sometime outside the range in which the user 18 is staying during the use of the sanitary fitting 1b. In a particularly advantageous embodiment, both the response region 29a and the response region 29b are monitored by the proximity sensor 29. Alternatively, the response range 29b is monitored by at least one further proximity sensor (not shown here).

In another embodiment, the electronic circuit unit 4 detects the occurrence of the response area 29b and activates the display 49 before the user 18 enters the actual area of use of the sanitary fitting 1b. In a particular embodiment, the electronic circuit unit 4 subsequently opens the valve 30 as soon as the user 18 enters the detection area 29a.

In another embodiment, the sanitary fitting 1b has a Preventiv¬spüleinheit 4f.

The preventive rinse unit 4f is embodied by way of example as a microelectronic assembly on a printed circuit board and coupled to the electronic circuit unit 4 via signal lines (not shown). If the user 18 enters the response area 29b outside the area in which the user 18 is staying during the use of the sanitary fitting 1b, the preventive flushing unit 4f automatically controls the valve 30 via the electronic circuit unit 4 such that in stagnant, particularly sensitive areas the stagnation water 46 (FIG. 1, 2) and the microorganisms possibly present therein are flushed out in the course of the preventive stagnation rinse 56c (FIG. 6) and close immediately before use from the terminal sanitary appliance 1b through the outlet 9 serving for the usual water extraction by a user 18 the valve 30, when the user 18 enters the An¬-speaking area 29 a, the entire volume of water in the sanitary fitting 1 b is replaced and / or after the lapse of the predetermined duration of the preventive Stagnationsfreispülung. The water volume of the plumbing fixture 1b is set as a parameter of that in the preventative flushing unit 4f. The stagnation purging duration is predetermined as a parameter in the preventive purging unit 4f or is made adjustable by means of an adjusting regulator or a remote control.

In a further embodiment, the preventive purging unit 4f continuously determines the quantity of the mixed water MW which has been discharged during the preventive stagnation rinse 56c (FIG. 6) and compares it with the predetermined degree of stagnation rinse of, for example, one liter. When the stagnation purge amount is reached, the preventive purge unit 4f closes the valve 30 via the electronic circuit unit 4. The stagnation purge amount is set as a parameter of the preventive purge unit 4f. In a particularly advantageous embodiment, the amount of stagnant rinsing is adjustable with an adjusting dial or a remote control.

In a particularly advantageous embodiment, the preventive rinsing unit 4f, including its components and connections, is integrated as a microelectronic subassembly on the printed circuit board of the electronic circuit unit 4.

In an alternative embodiment, the sanitary fitting 1b is designed in a surface-mounted version. The fitting body 2 is a shower panel with front panel, which is mounted on the tile wall 19. The hot water hose 6 and the cold water hose 7 are connected via unillustrated angle transition pieces to the building-side water installation, not shown.

3a shows the terminal sanitary fitting 1d as a further embodiment of the terminal sanitary fitting 1b (FIG. 3) with an electronic circuit unit 4, with a heat quantity limiting circuit unit 4e comprising the heat quantity meter 4a and the water stopper 4c, a control unit 4b and a cooling unit 4d. The heat meter 4a is exemplified as a microelectronic assembly on a printed circuit board and equipped with terminals for the temperature sensors 22,25,26,27,28, the flow meter 37a, 39a, 45a, the radio module 24 and the control line 23. Via unillustrated signal lines, the heat quantity counter 4a is coupled to the electronic circuit unit 4. The heat quantity counter 4a periodically, by way of example every millisecond, determines from the value of the flow meter 45a or the sum of the values of the flow meters 37a and 39a the amount of the mixed water MW delivered, with the temperature sensor 22 or the temperature sensors 25 and 26 taking into account the strokes H1 (FIG. 2) between the stop 36 (Fig.1,2) and the seal 35 (Fig.1,2) and H2 (Fig.1,2) between the stop 40 (Fig.1,2) and the seal 41 (Fig.1 , 2) the temperature of the dispensed mixed water MWund calculates therefrom the amount of heat of the mixed water MW delivered in megajoules, wherein the reference temperature for the mixed water MW, the temperature of the cold water KW, stored in the program memory of the microcontroller control, one via the Steuerlei¬ 23 transmitted or with In a particular embodiment, the electronic circuit unit 4 stores the amount and / or the amount of heat of the dispensed one n mixed water MW on a Speichermedi¬um 48, this represents on the display 49 and / or transmits them via the control line 23 or the radio module 24 to a not shown control system.

In another embodiment, the electronic circuit unit 4 comprises a water stopper 4c. The water stopper 4c is exemplified as a microelectronic assembly on a printed circuit board and connected via signal lines, not shown, with the heat meter 4a and the electronic circuit unit 4. The water stopper 4C detects and stores the time of triggering as the time at which the electronic circuit unit 4 releases the delivery of mixed water MW by activating the valve 30, integrates the heat quantity of the delivered mixed water MW over the runtime and closes the valve 30 after a maximum running time, after delivery of a maximum amount of water or after delivery of a maximum amount of heat, although the user 18 none of

Actuators 12 (Fig. 1,2,3,3a, 7), 12f (Fig.3), 12g (Fig.3) operated or is in Ansprechbe¬reich 29a of the proximity sensor 29, and thus prevents wasting Was¬ water and / or energy. Together with the heat quantity counter 4a, the water stopper 4c forms the heat quantity limiting circuit unit 4e and is embodied by way of example as a heat quantity limiter. The maximum transit time, the maximum amount of water and / or the maximum amount of heat are predetermined as parameters of the microcontroller contained in the electronic circuit unit 4. In a particularly advantageous embodiment, at least one of these values can be set with an adjustment controller or a remote control.

In a particular embodiment, the heat quantity limiting circuit unit 4e is designed as a compact assembly on a single circuit board consisting of the electronic components and connections of the heat quantity counter 4a and the water stopper 4c.

In a further refinement, the water stopper 4c automatically terminates a disinfectant flush with the valve 30 after a maximum transit time or after delivery of a maximum amount of water or maximum heat, even if neither by a wired signal on the control line 23 nor by a wireless signal Radio module 24 was received a command to stop the disinfection rinse.

In a particular embodiment, the microcontroller for the documentation contained in the electronic circuit unit 4 stores at least one of the drive parameters, such as setpoint values for temperature and volumetric flow, actual values of the temperature sensors 22, 25, 26, 27, 28, Flow meter 37a, 39a, 45a and the temperature sensor 20, the amount of heat of the delivered mixed water MW, the timing of the triggering and closing of the valve 30, the execution, triggering, terminating and / or canceling a disinfectant flush and the times of detecting a user 18 and the operating gens at least one actuator 12 (Fig.1,2,3,3a, 7), 12f (Fig.3), 12g (Fig.3) on a storage medium 48, displays them on the display 49 and / or transmits them over the Steuer¬erleitung 23 or the radio module 24 to a not shown control system.

In a further embodiment, the electronic circuit unit 4 comprises a Regelein¬heit integrated into the terminal sanitary fitting 1 (Fig. 1), 1 a (Figure 2), 1 b (Figure 3), 1 d (Figure 3a) 4b. The control unit 4b is exemplified as a microelectronic assembly on a printed circuit board and with connections for the temperature sensor 22,25,26,27,28, the flow meter 37a, 39a, 45a, the radio module 24, the control line 23 and the valve 30 ausgestat¬tet. Via signal lines, not shown, the control unit 4b is coupled to the electronic Schalthtungseinheit 4. By receiving a wired signal on the control line 23 or receiving a wireless signal with the radio module 24, a disinfecting rinse is activated and the control unit 4b controls the valve 30 such that the temperature of the mixed water MW discharged through the mixed water outlet 45 is equal to the position of the actuators 12 (FIG. 1, 2, 3, 3, 7), 12f (FIG. 3), 12g (FIG. 3) corresponds to independent set point 17 (FIG. 4) for the disinfecting rinse, depending on the temperature of the hot water flowing through the hot water inlet 37 WW from the cold water inlet 39zuströmendes cold water KW is added. The desired value 17 (FIG. 4) is predefined as a parameter of the microcontroller control contained in the electronic circuit unit 4 or designed to be adjustable by means of an adjustment controller or remote control.

In a particular embodiment, the electronic circuit unit 4 comprises a cooling unit 4d, which is exemplified as a microelectronic assembly on a printed circuit board and equipped with terminals for the temperature sensors 22,25,26,27,28. If the signal lines are not shown, the cooling unit 4d is connected to the electronic circuit unit 4. The cooling unit 4d controls after completion of a disinfection rinse the valve 30 such that only inflowing cold water KW is discharged through the Mischwas¬serabgang 45 and from the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Fig. 7), 1d (Fig. 3a) and cools the temperature of the fitting body 2 and closes the valve 30 after a maximum running time or after delivery of a maximum amount of water or if at least one of the temperature sensors 22,25,26,27 , 28 detected temperatures below a limit. The maximum transit time, the maximum amount of water and / or limit values of the temperatures are predetermined as parameters of the microcontroller control contained in the electronic circuit unit 4. In a particularly advantageous embodiment, at least one of these values is designed to be adjustable by means of an adjustment controller or a remote control.

In a particularly advantageous embodiment, the heat quantity meter 4a, the control unit 4b, the water stopper 4c, the cooling unit 4d and / or the heat quantity limiting circuit unit 4e, including their components and connections, are integrated as microelectronic subassemblies on the printed circuit board of the electronic circuit unit 4 ,

4 shows the temperature profile in a hot water system. Characteristic 14 shows the temperature before the thermal disinfection, which starts at time t1.

Characteristic 16 shows the temperature profile during a thermal disinfection when using a sanitary fitting whose valve for thermal disinfection is bypassed with a By¬pass. For thermal disinfection, only water from the hot water system is used, the temperature of which decreases continuously from the beginning of the thermal disinfection at time t1 and, at time t2, falls below the setpoint value 17 for thermal disinfection of 70 ° C. by way of example.

Characteristic 15 shows the temperature profile during a thermal disinfection when using a sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a).

By receiving a wired signal on the control line 23 (Fig.1,2,3,3a, 7), for example, the change of the electrical level 13, or receiving a wireless signal with the radio module 24 (Fig.2,3,3a ), by way of example of a particular coded sequence of instructions, at time t1 the disinfecting flush for performing a thermal disinfection is activated and the electronic circuit unit 4 (Figs. 1,2,3,3a, 7) controls the valve 30 (Figs. 1,2,3,3a , 7) in such a way that the temperature of the mixed water MW (FIGS. 1, 2, 3, 3 a, 7) discharged through the mixed water outlet 45 (FIGS. 1, 2, 3, 3 a, 7) is equal to the desired value 17 for the thermal disinfection on, depending on the temperature of the hot water WW (Fig. 1,2,3,3a, 7) flowing in through the hot water inlet 37 (Figs. 1,2,2,3,3a, 7) from the cold water inlet 39 (Fig .1,2,3,3a, 7) inflowing cold water KW (Fig.1,2,3,3a, 7) is added. The temperature of the mixed water MW (FIGS. 1, 2, 3, 3, 7, 7) flowing out of the mixed water outlet 45 (FIGS. 1, 2, 3, 3 a, 7) remains constant, and the characteristic curve 15 decreases in comparison with characteristic curve 16 more slowly. At the time t3 of falling below the setpoint value 17, the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7) generates the fault message 55 on the control line 23 (FIGS. 1, 2, 3, 3 a, 7), by way of example Turn level 13 to 0V twice. The time t3 is on the Zeit¬achse after t2 and so can be disinfected with the same storage volume in the hot water system for a long time than with sanitary fittings with bypass. In an alternative embodiment, the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7) transmits the fault message 55 via the radio module 24 (FIGS. 2, 3, 3 a).

In a further embodiment of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Figure 3a), the electronic circuit unit 4 (Fig. 1,2,3,3a, 7) upon receipt of a wire-bound signal on the control line 23 (Figures 1, 2, 3, 3a, 7), exemplifying the change in the electrical level 13, or receiving a wireless signal with the radio module 24 (Fig. 2,3,3a), by way of example of a particular coded sequence of instructions, the valve 30 (Figs. 1,2,3,3a, 7) to the position in which the delivery of incoming cold water KW (Figs , 3,3a, 7) is prevented, only inflowing hot water WW (Fig.1,2,3,3a, 7) through the Mischwasserabgang45 (Fig.1,2,3,3a, 7) flows out and the temperature of the mixed water MW (Fig.1,2,3,3a, 7) reaches the set point 17 for thermal disinfection as soon as possible. Subsequently, the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7) controls the valve 30 (FIGS. 1, 2, 3, 3 a, 7) so that the temperature of the water flowing through the mixed water outlet 45 (FIGS. 1, 2, 3, 3a, 7) delivered MW (Fig.1,2,3,3a, 7) corresponds to the setpoint value 17 for the thermal disinfection, wherein in

Dependence on the temperature of the hot water WW flowing through the hot water inlet 37 (FIGS. 1, 2, 3, 3 a, 7) (FIGS. 1, 2, 3, 3 a, 7) from the cold water inlet 39 (FIGS , 3,3a, 7) inflowing cold water KW (Fig.1,2,3,3a, 7) is added.

In a particular embodiment of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Figure 3a) prevents the electronic circuit unit 4 (Fig 1, 2, 3, 3a, 7) start the disinfecting rinse when a user 18 (Fig.3.3a) is in the response area 29a (Fig.2,3,3a) or 29b (Fig.3).

During a disinfecting rinse, a user 18 (FIGS. 3, 3a) actuates at least one of the actuators 12 (FIGS. 1, 2, 3, 3 a, 7), 12 f (FIG. 3), 12 g (FIG. 3 a) ) of the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) or enters the proximity region 29a (Fig.2, 3, 3a) or 29b (FIG. 3), the electronic circuit unit 4 (FIGS. 1, 2, 3, 3a, 7) then activates the brewing protection 57 (FIG. 5c) and closes the valve 30 (FIGS. 3a, 7).

In an alternative embodiment of the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) activates the electronic circuit unit 4 (Fig 1,2,3,3a, 7) the scalding protection 57 (Fig. 5c), closes the flow of hot water WW (Figs. 1,2,3,3a, 7) to the outlet 9 (Figs , 3, 3a, 7) and, with the valve 30 (FIGS. 1, 2, 3, 3 a, 7), supplies the supply of cold water KW (FIGS. 1, 2, 3, 3 a, 7) to the outlet 9 (FIG. 1,2,3,3a, 7) to the maximum possible volumetric flow when, during a disinfecting rinse, a user 18 (FIG. 3 a) has at least one of the actuators 12 (FIGS. 1, 2, 3, 3 a, 7), 12 f 3), 12g (Figure 3) of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Figure 3a) operated or into the proximity area 29a (Fig. 2,3,3a) or 29b (Fig. 3), the valve 30 (Figs. 1,2,3,3a, 7) fully penetrates and closes as soon as the temperature detected by the temperature sensor 28 (Fig. 2,3,3a) detected temperature of the fitting body 2 (Fig.1,2,3,3a, 7) below the predetermined safe limit temperature. The safe limit temperature of, for example, 37 ° C. is predetermined as a parameter of the microcontroller control contained in the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7). In a particularly advantageous embodiment, the limit temperature is adjusted in an adjustable manner with an adjusting regulator or a remote control.

In a further embodiment of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Figure 3a) activates the electronic circuit unit 4 (Fig .1,2,3,3a, 7) the scalding protection 57 (Fig.5c), closes the flow of hot water WW (Fig.1,2,3,3a, 7) to the outlet 9 (Fig.1,2 , 3,3a, 7) and with the valve 30 (Fig.1,2,3,3a, 7), the supply of cold water KW (Fig.1,2,3,3a, 7) to the outlet 9 (Fig. 1,2,3,3a, 7) to the maximum possible volumetric flow when, during a disinfecting rinse, a user 18 (FIG. 3 a) has at least one of the actuators 12 (FIGS. 1, 2, 3, 3 a, 7), 12 f 3), 12g (Figure 3) of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Figure 3a) operated or into the proximity area 29a (Figs. 2,3,3a) or 29b (Fig. 3), the valve 30 (Figs. 1,2,3,3a, 7) fully enters and closes as soon as at least one of the temperature sensors 22 (Fig. 1,2,3,3a, 7) and 27 (Fig.2, 3, 3a) detected temperatures below the predetermined safe limit temperature. The safe limit temperature of, for example, 37 ° C. is specified as a parameter of the microcontroller control contained in the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7). In a particularly advantageous embodiment, the limit temperature can be set with an adjusting controller or a remote control.

5a shows the temperature profile 50 of the water in the outlet of a conventional sanitary fitting, which is embodied by way of example as a single-lever mixer and comprises a mechanical Kar¬tuschenventil with an actuator for adjusting the temperature and the volume flow of the outflowing water. At time t4, the use of the Sani¬tärarmatur by lifting the actuator starts. In the outlet, according to the position of the actuator, a water temperature 51 of about 38 ° C, starting from the room temperature 52 of about 20 ° C, is established. At the time t5, the use ends by closing the actuator and the water temperature of the stagnant water 46 (Fig.1,2) cools down to the level of the room temperature 52 in the outflow until the time t6. The temperature 53 of the cold water KW (Fig.1,2,3,3a, 7) is about 10 ° C.

FIG. 5 b shows the temperature profile 50 a of the water in the outlet 9 (FIGS. 1, 2, 3, 3 a, 7) of the sanitary fitting 1 (FIG. 1), 1 a (FIG. 2), 1 b (FIG. 3), 1c (Figure 7), 1d (Figure 3a) when used from time t4 to t5. At the time t4, the use of the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) starts by operating at least one of the actuators 12 (Fig. Fig.1,2,3,3a, 7) 12f (Figure 3), 12g (Fig.3). In the outlet 9 (Fig.1,2,3,3a, 7), corresponding to the position of the actuator 12 (Fig.1,2,3,3a, 7), a water temperature 51 of about 38 ° C, starting from the room temperature 52 of about 20 ° C. At the time t5 ends the use. After use, the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) flushes cold water KW (Fig.1,2, 3,3a, 7) with the temperature 53 from about 10 ° C until the time t7 nach.Anschließend the temperature of the stagnant water 46 (Fig.1,2) in the outlet 9 (Fig.1,2,3,3a, 7th ) up to room temperature 52 at time t8.

5c shows the temperature profile 50b of the water in the outlet 9 (FIGS. 1, 2, 3, 3 a, 7) of the sanitary fitting 1 (FIG. 1), 1 a (FIG. 2), 1 b (FIG. 3), [00133] FIG. 1c (Figure 7), 1d (Figure 3a) when used from time t4 to t5. At the time t4, the use of the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) starts by operating at least one of the actuators 12 (Fig. Fig.1,2,3,3a, 7) 12f (Figure 3), 12g (Fig.3). In the outlet 9 (Figs. 1, 2, 3, 3a, 7), a water temperature 51 of about 38 ° C, starting from the room temperature 52, of approximately, is set in accordance with the position of the actuator 12 (Figs. 1,2,3,3a, 7) 20 ° C. At the time t5 ends the use. After use, the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) flushes warm water WW (Fig.1,2, 3,3a, 7) with the temperature 54 of about 70 ° C and thus kills the cold water KW (Fig.1,2,3,3a, 7) or hot water WW (Fig.1,2,3,3a , 7) microorganisms soaked in or penetrated by the aerator 8 (Figs. 1,2,3,3a). At time t9, a user 18 (Fig.3,3a) actuates at least one of the actuators 12 (Figs. 1,2,3,3a, 7), 12f (Fig. 3), 12g (Fig. 3) of the sanitary fitting 1 (Fig 1), 1a (Fig. 2), 1b (Fig. 3), 1c (Fig. 7), 1d (Fig. 3a), or enters the approximation area 29a (Fig. 2,3,3a) or 29b (Fig. 3). The electronic circuit unit 4 (Fig. 1,2,3,3a, 7) then activates the scalding protection 57, closes with the valve 30 (Fig.1,2,3,3a, 7), the flow of hot water WW (Fig.1 , 2,3,3a, 7) to the outlet 9 (Fig.1,2,3,3a, 7) and provides with the valve 30 (Fig.1,2,3,3a, 7) the supply of cold water KW (Fig .1,2,3,3a, 7) with the temperature 53 of about 10 ° C to the outlet 9 (Fig.1,2,3,3a, 7) to the maximum possible volume flow up to the time t10 a , At time t10, the discharge of water ends and the temperature of the residual water in outlet 9 (FIGS. 1, 2, 3, 3 a, 7) rises to room temperature 52 until time t 11.

6 shows the temperature profile of the stagnation water 46 (FIG. 1, 2) of the sanitary appliance 1 (FIG. 1), 1 a (FIG. 2), 1 b (FIG. 3), 1 c (FIG. , 1d (3a). After use, the temperature of the stagnant water 46 (FIG. 1, 2) corresponds to the temperature of the discharged mixed-water MW (FIGS. 1, 2, 3, 3 a, 7) of, for example, 38 ° C. Characteristic 46a shows the course of the temperature of the Stagnationswassers 46 (Figure 1,2) of the sanitary fitting 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Figure 7), 1d (Fig. 3a), which cools to the ambient temperature of 24 ° C. The stagnation rinsing unit 4g (FIG. 1, 2) constantly, here by way of example, determines with a microcontroller from the deviation of the temperature of the stagnation water 46 (FIG. 1, 2) from the ideal temperature for the multiplication of microorganisms, for example 30 ° C. the multiplication possibly in stagnation water 46 (Fig.1,2) located microorganisms. Characteristic curve 46a 'indicates the progression of the value R for the risk of the multiplication of microorganisms which has accumulated since the closing of the valve 30 (FIGS. 1, 2, 3, 3 a, 7), which depends on the temperature of the stagnation water 46 (FIG .1,2) increases. At time t12, the value R exceeds the predetermined limit value RG, in this case the value 30, which is predetermined as a parameter in the microcontroller control contained in the electronic circuit unit 4 (FIGS. 1, 2, 3, 3a, 7) or which is adjustable by means of an adjustment controller or a remote control , The stagnation rinsing unit 4g (FIG. 1, 2) requests rinsing, and the electronic circuit unit 4 (FIGS. 1, 2, 3, 3 a, 7) controls the valve 30 (FIGS. 1, 2, 3, 3 a, 7 ) such that the stagnation water 46 (FIG. 1, 2) in the direction of the stagnation purging 56 a through the outlet pipe 10 (FIGS. 1, 2, 3, 3 a, 7), the outlet 9 (FIGS. 1,2,3,3a, FIG. 7) and the jet regulator 8 (FIGS. 1, 2, 3, 3 a) from the sanitary fitting 1 (FIG. 1), 1 a (FIG. 2), 1 b (FIG. 3), 1 c (FIG. 7), 1 d (FIG. Fig.3a) is rinsed out.

Characteristic 46b shows the course of the temperature of the Stagnationswassers 46 (Figure 1,2) of the sanitary fitting 1 (Fig. 1), 1 a (Figure 2), 1 b (Figure 3), 1 c (Fig. 7), 1 d (FIG. 3 a) at an ambient temperature of 18 ° C. and characteristic curve 46 b 'shows the value R for the risk integrated into the valve since the valve 30 has been closed (FIGS. 1, 2, 3, 3 a, 7) Propagation of any microorganisms present in the stagnant water46 (Figure 1, 2) which, due to the less favorable temperature profile compared to characteristic curve 46 for the microorganisms, increases more slowly than the characteristic curve 46a '. At time t13, the value R exceeds the predetermined limit value RG, the station rinsing unit 4g (FIG. 1, 2) requests rinsing, and the electronic circuit unit 4 (FIGS. 1, 2, 3, 3a, 7) controls the valve 30 (FIG. 1, 2, 3, 3 a, 7) such that the stagnation water 46 (FIG. 1, 2) in the course of the stagnation rinse 56 b passes through the outlet pipe 10 (FIGS. 1, 2, 3, 3 a, 7), the outlet 9 (Fig.1,2,3,3a, 7) and the jet regulator 8 (Fig.1,2,3,3a) from the sanitary fitting 1 (Fig.1), 1a (Fig.2), 1b (Fig.3 ), 1c (Fig.7), 1d (Fig.3a) is rinsed out.

The time t13 of Stagnationsfreispülung 56b at an ambient temperature of 18 ° C is just over 5 hours after use by about 70 minutes after the time t12 stagnation rinse 56a at an ambient temperature of 24 ° C.

In a particularly advantageous embodiment of the invention, the sanitary appliance 1b (FIG. 3) has a preventive rinsing unit 4f (FIG. 3). The electronic circuit unit 4 (Fig. 3) signals the preventative flushing unit 4f (Fig. 3) when the user 18 (Fig.3,3a) enters the response area 29b (Fig. 3) outside the area where the user 18 (Fig .3,3a) stops during the use of the sanitary fitting 1b (Figure 3) occurs. The preventative flushing unit 4f (FIG. 3) then compares the value R with the predetermined limit value RGp and, at the time t14, controls the valve 30 (FIG. 3) via the electronic circuit unit 4 (FIG. 3) such that the stagnation water 46 (FIG , 2) in the course of the preventive Stagnationsfreispülung 56c is flushed out of the sanitary fitting 1b (Figure 3), if the value R has exceeded the limit RGP. The limit value RGP is below the limit value RG, by way of example at 15, and is predefined as a parameter in the microcontroller controller contained in the electronic circuit unit 4 (FIG. 3) or can be adjusted with an adjustment controller or a remote control. The preventive Stagnationsfreispülung 56c is used in hygienic particularly sensitive areas for flushing out the stagnant water 46 (Figure 1,2) and any microorganisms therein from the sanitary fitting 1b (Figure 3) immediately before their use, even if the value R is the limit RG does not yet exceed. The preventive flushing unit 4f (FIG. 3) closes the valve 30 (FIG. 3) via the electronic circuit unit 4 (FIG. 3) when the user 18 (FIG. 3, 3a) enters the response area 29a (FIG. 3,3a), after expiration of a certain maximum run time and / or after delivery of a certain maximum amount of water or heat. The determined maximum running time, the determined maximum amount of water and / or the determined maximum amount of heat are predetermined as parameters in the preventative flushing unit 4f (FIG. 3) or adjusted with an adjusting knob or a remote control.

FIG. 7, in contrast to FIG. 1, shows a non-terminal sanitary fitting 1c, which is designed as a flush-mounted mixer. The non-terminal sanitary fitting 1c is not for direct water removal by a user 18 (Figure 3,3a), for example, showers, tubs, sinks, sinks, bidets, urinals and toilets, but for Versor¬gung a not shown terminal sanitary fitting with directly from the Mischwasserab¬gang 45 ausströmendem or temporarily stored in a tank, not shown Mischwasser MW and comprises a fitting body 2, designed as a dial Betä¬ tigungsorgan 12, a valve 30 with the hot water inlet 37 for incoming hot water DHW, the cold water inlet 39 for incoming cold water KW, the Mischwasserabgang45 with the outflow mixed water flow meter 45a, an electronic circuit unit 4, a power supply 3, and a disinfecting purge activation control line 23. The outlet pipe 10 is designed for example as a screw, plug or Pressan¬schluss. In the position 12d of the actuating member 12, the electronic circuit unit 4 controls the valve 30 such that only incoming cold water KW flows through the mixed water outlet 45 into the outlet pipe 10.

Turning a user, the actuator 12, starting from the position 12d counterclockwise to the right, the electronic circuit unit 4 then controls the valve 30 such that the temperature of the mixed water MW discharged is increased and in the position 12e only inflowing hot water WW through the Mischwasserab¬ passage 45 flows into the outlet pipe 10. If the actuating member 12 is rotated clockwise to the left starting from the position 12e, the electronic circuit unit 4 controls the valve 30 in such a way that the temperature of the mixed water MW delivered is reduced, and cold water KW flowing in position 12d only through the mixed water outlet 45 flows into the outlet pipe 10. The electronic circuit unit 4 determines perio¬disch example every millisecond, from the value of the flow meter 45a the amount of effluent mixed water MW, with the temperature sensor 22, the temperature of ausströ¬menden mixed water MW, calculated from the amount of heat from the sanitary fitting 1can not shown terminal fitting mixed water MW delivered in megajoules, wherein the reference temperature for the mixed water MW, the temperature of the cold water KWherherzogen wird and transmits these via the control line 23 to a Notdeseseiteiteiteit.

In particular embodiments, the sanitary fittings 1 (Fig.1), 1a (Fig.2), 1b (Fig.3), 1c (Fig.7), 1d (Fig.3a) comprise a heat meter 4a (Fig.3a a control unit 4b (FIG. 3a), a water stopper 4c (FIG. 3a), a cooling unit 4d (FIG. 3a), a heat quantity limiting circuit unit 4e (FIG. 3a), a preventive flushing unit 4f (FIG. a stagnation rinsing unit 4g (FIG. 1, 2), a real-time clock 4h (FIG. 1), a scalding protection 57c (FIG. 5), at least one of the temperature sensors 22 (FIGS. 1, 2, 3, 3a, 7) ), 25 (Fig. 2,3,3a), 26 (Fig. 2,3,3a), 27 (Fig. 2,3,3a), 28 (Fig. 2,3,3a), a proximity sensor 29 (Figs. 2, 3, 3 a), and a response region 29 a (FIG. 2, 3, 3 a) and at least one further response region 29 b (FIG. 3) outside the use region of a user 18 (FIG For clarity, only inFig.2, Figure 3 and / or Figure 3a shown and in particularly advantageous embodiments of all sanitary fittings 1 (Figure 1), 1a (Figure 2), 1b (Figure 3), 1c (Fig ), 1d (Fig.3a) enthal can be. The preventative rinsing unit 4f (FIG. 3), the stagnation rinsing unit 4g (FIG. 1, 2), the real-time clock 4h (FIG. 1), the valve 30 (FIGS. 1, 2, 3, 3a, 7) and at least one of the temperature sensors 22 (Fig.1,2,3,3a, 7), 25 (Fig.2,3,3a), 26 (Fig.2,3,3a), 27 (Fig.2,3,3a), 28 (Fig .2,3,3a) can in particular Ausgestal¬tungen directly in the fitting body 2 (Fig.1,2,3,3a, 7) of all sanitary fittings 1 (Fig.1), 1a (Fig.2), 1b (Fig. 3), 1c (Fig.7), 1d (Fig.3a) may be arranged. In the sanitary fittings 1 (Fig. 1) and 1a (Fig. 2), the response area 29a (Fig. 2) is essentially the area in which, during the use of the sanitary fittings 1 (Fig.1) and 1a (Fig.2) the hands of the user 18 (Fig.3,3a) are located, the at least one further response area 29b (Figure 3) substantially the area in front of or next to the not shown washbasin, the user 18 (Fig.3,3a) durch¬schreitet when he comes to the sink.

Claims (10)

1. Terminal sanitary fitting (1,1a, 1b, 1d) with at least one actuator (12,12f, 12g), a hot water inlet (37), a cold water inlet (39), an outlet (9) and with a. a flow meter (45a) in the mixed water outlet (45) or / and a flow meter (37a) in the hot water inlet (37) and a flow meter (39a) in the cold water inlet (39) and b. a temperature sensor (22) in the mixed water outlet (45) and / or a temperature sensor (25) in the hot water inlet (37) and a temperature sensor (26) in Kaltwas¬sereingang (39) characterized in that the terminal sanitary fitting (1,1 a , 1 b, 1 d) comprises a heat-quantity-limiting circuit unit (4e) for limiting the amount of heat released in the event of removal of water from the sanitary fitting (1, 1 a, 1 b, 1 d). 2. Terminal sanitary fitting (1,1 a, 1 b, 1 d) according to claim 1, characterized in that the terminal sanitary fitting (1,1 a, 1 b, 1 d) comprises a scalding protection (57). 3. Terminal sanitary fitting (1,1a, 1b, 1d) according to claim 1 or 2, characterized gekennzeich¬net that the terminal sanitary fitting (1,1 a, 1 b, 1 d) a preventive flushing unit (4f) for triggering a preventive Stagnationsfreispülung ( 56c) for flushing out the stagnation water (46) immediately before the use of the terminal sanitary fitting (1,1a, 1b, 1d). 4. Terminal sanitary fitting (1,1 a, 1 b, 1 d) according to one of claims 1 to 3, characterized in that the terminal sanitary fitting (1,1 a, 1 b, 1 d) a control line (23) or a radio module (24) for triggering a disinfecting rinse. 5. Terminal sanitary fitting (1,1 a, 1 b, 1 d) according to one of claims 1 to 4, characterized in that the terminal sanitary fitting (1,1 a, 1 b, 1 d) a control unit (4 b) for controlling the temperature of the mixed water (MW) in a disinfecting rinse. 6. Terminal sanitary fitting (1,1 a, 1 b, 1 d) according to one of claims 1 to 5, characterized in that the terminal sanitary fitting (1,1a, 1b, 1d) a cooling unit (4d) for rinsing with cold water (KW ) after disinfecting rinse. 7. Terminal sanitary fitting (1,1a, 1b, 1d) according to one of claims 1 to 6, characterized in that the terminal sanitary fitting (1,1 a, 1 b, 1 d) is a storage medium (48) for storing the setpoint values for temperature and flow rate of the water flowing through, at least one of the actual values of the measuring means for temperature (22,25,26,27,28,20) and flow rate (37a, 39a, 45a) and / or the times of opening and closing of the Valve (30) and / or the times of detecting a user (18) and / or the actuation of at least one actuating member (12,12f, 12g). 8. Terminal sanitary fitting (1,1a, 1b, 1d) according to one of claims 1 to 7, characterized in that in the heat quantity limiting circuit unit (4e) a heat meter (4a) and / or a water stopper (4c) is arranged. 9. A method for controlling a terminal sanitary fitting (1,1a, 1b, 1d) according to one of claims 1 to 8, characterized in that the heat quantity-limiting Schalthtungseinheit (4e) in dependence of the terminal of the sanitary fitting (1,1a, 1b, 1d) with a water stopper (4c) automatically closes a valve (30) for the delivery of water to the sanitary fitting (1,1 a, 1 b, 1 d). 10. A method for controlling a terminal sanitary fitting (1,1a, 1b, 1d) according to any one of claims 5 to 8, characterized in that the control unit (4b) the temperature of the delivered mixed water (MW) with the valve (30) during a disinfection regulates flushing to one of the position of the actuators (12,12f, 12g) independent setpoint (17) for the disinfecting rinse. For this 8 sheets of drawings