DE102021126028A1 - Process monitoring device - Google Patents

Abstract

Outflow monitoring device (1) with an electronic circuit unit (6), an overflow protection (19), an energy supply (11), at least one outflow sensor (3) and a communication unit (7), which is connected to at least one terminal sanitary fitting (2) with at least is electrically coupled to an electrically operated valve (12) controlled by an electronic circuit unit (18), in which the outflow sensor (3) for detecting the flow of liquid discharged from at least one of the terminal sanitary fittings (2) into the sewage system (15), the electronic circuit unit (6) for detecting a blockage of the drain (24), the overflow protection (19) for generating a status message (20) and the communication unit (7) for transmitting a status message (20) to at least one of the terminal sanitary fittings (2).

Description

The invention relates to a device for outflow monitoring with an electronic circuit unit, an overflow protection, an energy supply, at least one outflow sensor and a communication unit, which is electrically coupled to at least one terminal sanitary fitting with at least one electrically actuated valve controlled via an electronic circuit unit, in which the outflow sensor for detecting the flow of liquid discharged from at least one of the terminal sanitary fittings into the sewage system, the electronic circuit unit for detecting a blockage of the drain, the overflow protection for generating a status message and the communication unit for transmitting a status message to at least one of the terminal sanitary fittings.

House installations are supply engineering systems for the provision and distribution of water for human consumption in buildings and on properties. They consist of components, in particular fittings, pipes and systems for treating water, for example for heating it, which are located between the tapping points and the distribution network of the water supplier. The fittings for removing water for sanitary purposes or for rinsing, in particular for showers, tubs, washbasins, sinks, bidets, urinals, toilets and at the ends of the lines are referred to as terminal sanitary fittings.

Domestic installations harbor the risk that microorganisms, such as bacteria, fungi or amoebae, that are washed in or introduced retrogradely in the stagnant water from the water supply line during downtimes, for example outside of opening and/or seasonal times, during the holidays or when hotel rooms are not occupied, multiply. As a result of this contamination, the stagnant water no longer meets the requirements of the Drinking Water Ordinance and the use of the water poses a risk to human health.

Microorganisms reproduce exponentially through cell division and under ideal environmental conditions. Away from these ideal conditions, propagation is slower; beyond certain limits, propagation is stopped. Especially stagnant water with a temperature of approx. 25 to 40°C offers good living conditions for many microorganisms, above a limit value of approx. 60°C the pathogens are inactivated. Accordingly, the operation of circulating hot water systems, in which the hot water leaves the water heater with an outlet temperature of at least 60°C and the return flow of the circulation is returned to the water heater with at least 55°C, has also become established in the generally recognized rules of technology. In this way, the temperature in the hot water components of a domestic installation is always kept in a microbiologically non-critical range. In contrast to this, circulating cold water systems are to be classified as hygienically critical: the circulated cold water is continuously heated by the influence of the ambient temperature and the waste heat from the circulation pumps. As a result, without additional measures, such as active cooling, the temperature range of approx. 25 to 40°C, which is particularly dangerous for microbial growth, is reached. In contrast to circulating hot water systems, the thermally inactivating effect on the microorganisms at at least 60°C is completely absent in these systems.

The latest findings from practice show that components of a house installation that carry cold water are often more difficult to hygienically manage than those that carry hot water. Furthermore, in the case of renovation, thermal disinfection of the components of a house installation carrying cold water by rinsing with water temperatures of at least 65°C is usually not feasible. It is therefore particularly important for the cold water-carrying components of domestic installations that stagnant water that has lingered for too long is rinsed out and discarded.

From the EP2762646 and the DE102006021838 terminal sanitary fittings with a bypass for carrying out stagnation flushing are known, which are used to flush out the stagnant water from a terminal sanitary fitting, a house installation or parts thereof. The disadvantage of these fittings is that the bypass is arranged outside the sanitary fitting and the removal of water - for example by a user - is not recorded and thus harmless water is wasted, since the flushing through the bypass also takes place when water has just been removed or becomes.

Terminal sanitary fittings with a proximity sensor, an electronic circuit unit and an electrically operated valve are among others from AT404150 , AT514160 , DE19651132 , DE10148675 , EP2169123 , EP0813636 and the US5961095 known. From the DE102009030534 , US2004254746 and the AT506792 devices are known which automatically flush out the stagnant water when a maximum residence time is exceeded. The disadvantage of these solutions is that unattended stagnation flushing occurs at times when people are absent due to holidays, business interruptions or weekends, for example, blockages in the drain can lead to flooding.

Odor traps with a conductivity sensor for flushing are in the DE10111210 , DE2153344 , DE19755998 and AT412353 revealed. These odor traps are suitable for automatic flushing of urinals in particular. From the DE102020103121 a method for detecting an impending drain blockage is known. The disadvantage of this is that both the fluid flow of the inflow and that of the outflow must be monitored.

From the DE102013102567 , DE102018009511 and DE102020000841 flushing devices with a sensor are known which monitor the water level and thus prevent flooding. The disadvantage of these solutions is that the sensor has to be installed in the washbasin and it is not possible to remove water without dismantling the flushing device according to the invention.

Automatic shut-off valves for installation in the house installation are from the US2018/306617 , US2018/291594 and WO2020/083518 known. These systems monitor leaks in the domestic installation. A disadvantage of these solutions is that they do not detect blockages in the water outlet.

The object on which the invention is based is therefore to specify a device for outflow monitoring with an electronic circuit unit, an overflow protection, an energy supply, at least one outflow sensor and a communication unit, which is electrically connected to at least one terminal sanitary fitting with at least one electrically actuated valve controlled by an electronic circuit unit is coupled.

The object of the invention is achieved with a device for monitoring the outflow of the type mentioned at the outset in that the outflow sensor for detecting the flow of liquid discharged from at least one of the terminal sanitary fittings into the sewage system, the electronic circuit unit for detecting a blockage of the outflow, the overflow protection for generating a status message and the communication unit is designed to transmit a status report to at least one of the terminal sanitary fittings.

The device for monitoring the discharge is preferably designed in such a way that the communication unit is designed to transmit the status report generated by the overflow protection when a blockage of the discharge into the sewage system is detected.

The device for monitoring the flow can be designed in such a way that parts of the flow sensor, the electronic circuit unit, the overflow protection, the communication unit and/or the power supply are arranged in a common housing or in at least two housings. At least one component of the device for monitoring the discharge can also be arranged in or on the terminal sanitary fitting.

The energy supply can include at least one mains unit, a battery, an accumulator, a capacitor, an impeller, a thermal generator, a piezoelectric generator and/or a solar cell.

The outflow sensor can include at least one float sensor, conductivity sensor, inductive sensor, capacitive sensor, impeller sensor, infrared sensor, temperature sensor, sensor with image evaluation, flow sensor, flow sensor and/or ultrasonic sensor. It can be wired or wirelessly connected to the overflow protection. Alternatively, it can also be connected to the overflow protection in a wired or wireless manner via the communication unit and/or the electronic circuit unit.

The communication unit can have at least one RS-232 interface, USB interface, LAN interface, fiber optic interface, WLAN interface, Bluetooth interface, Thunderbolt interface, LoRa interface, mobile radio interface, radio interface in an ISM Band, ultrasonic interface, infrared interface and / or include at least one potential-free opening or closing contact. The device for process monitoring can also be coupled to at least one information technology device via the communication unit.

Provision can advantageously be made for circuit parts of the overflow protection, the communication unit, the energy supply, the outflow sensor, the electronic circuit unit of at least one terminal sanitary fitting and/or the connection to be designed as components of the electronic circuit unit of the outflow monitoring device and integrated into its assembly.

In a particular embodiment, at least part of the outflow sensor can be arranged in the direction of flow before or after the odor trap or in the odor trap.

The discharge monitoring device can have a connection that is designed to supply energy to the discharge monitoring device and/or to supply energy to the terminal sanitary fitting.

• 1 eine auf einer endständigen Sanitärarmatur montierte Vorrichtung zur Ablaufüberwachung mit einem Ultraschallsensor und einer Kommunikationseinheit mit einem potenzialfreien Schaltkontakt;
• 2 eine Vorrichtung zur Ablaufüberwachung mit einem vor dem Geruchsverschluss angeordneten Leitfähigkeitssensor und einer Kommunikationseinheit mit einer USB-Schnittstelle;
• 3 eine Vorrichtung zur Ablaufüberwachung mit zwei Leitfähigkeitssensoren und einer Kommunikationseinheit mit einer Bluetooth-Schnittstelle und
• 4 eine Vorrichtung zur Ablaufüberwachung mit einer als Flügelrad ausgeführten Turbine und einer Kommunikationseinheit mit einer Infrarot-Schnittstelle

darstellt.The invention is explained in more detail using exemplary embodiments according to the drawings, in which

• 1 a discharge monitoring device mounted on a terminal sanitary fitting with an ultrasonic sensor and a communication unit with a potential-free switch contact;
• 2 a device for outflow monitoring with a conductivity sensor arranged in front of the odor trap and a communication unit with a USB interface;
• 3 a device for process monitoring with two conductivity sensors and a communication unit with a Bluetooth interface and
• 4 a device for process monitoring with a turbine designed as an impeller and a communication unit with an infrared interface

represents.

1 shows the terminal sanitary fitting 2 mounted on the washbasin 16 with the electronic circuit unit 18, the electrically actuated valve 12 and the device for monitoring the flow 1 with the electronic circuit unit 6, the overflow protection 19 and the flow sensor 3, which as an ultrasonic sensor with the two ultrasonic transducers 5a and 5b for detecting the liquid level 21 in the washbasin 16. The power supply 11 designed as a plug-in power supply is connected to the connection 10 and supplies both the device for monitoring the flow 1 and the terminal sanitary fitting 2 with electrical energy. The device for process monitoring 1 also has the communication unit 7 with a potential-free closing contact, which is coupled to the sanitary fitting 2 at the end via the cable 8 . The drain of the sink 16 is connected to the sewage system 15 via the odor trap 9 . The electronic circuit unit 6 uses the liquid level 21 in the washbasin 16 detected by the outflow sensor 3 to periodically monitor the outflow of the liquid discharged from the terminal sanitary fitting 2, for example water, into the sewage system 15. The overflow protection 19 generates the status message 20, if from the electronic circuit unit 6 a blockage of the drain 24 from the washbasin 16 into the sewage system 15 is detected. The communication unit 7 transmits the status message 20 by closing the potential-free closing contact to the terminal sanitary fitting 2. The electronic circuit unit 18 of the terminal sanitary fitting 2 periodically checks the dwell time of the stagnant water in the terminal sanitary fitting 2 and opens with the electrically actuated valve 12 if the maximum stagnation time is exceeded the water flow for rinsing out the stagnant water in the course of stagnation free rinsing only if according to the status message 20 there is no blockage of the drain 24 . After the end of the stagnation flushing period, the electronic circuit unit 18 of the terminal sanitary fitting 2 closes the water flow with the electrically actuated valve 12 . The maximum stagnation time and the stagnation flushing duration are stored as fixed parameters in the electronic circuit unit 18 of the terminal sanitary fitting 2 or are designed to be adjustable. The electronic circuit unit 6, the flow sensor 3, the overflow protection 19 and the communication unit 7 are arranged in a common housing and are connected via unspecified cables.

In a further embodiment of the invention, the electronic circuit unit 18 of the terminal sanitary fitting 2 interrupts a stagnation flushing process that has already started by closing the electrically actuated valve 12 prematurely if the device for monitoring the flow 1 transmits the status message 20 that the flow 24 is blocked .

In an alternative embodiment of the invention, the communication unit 7 has a potential-free opening contact. A break in the cable 8 is thus also signaled as a status message 20 and thus as a blockage of the drain 24 .

In a particular embodiment, at least one component of the device for monitoring the discharge 1 is arranged in or on the sanitary fitting 2 at the end.

In different embodiments, the energy supply 11 comprises at least one power pack, a battery, an accumulator, a capacitor, an impeller, a thermal generator, a piezoelectric generator and/or a solar cell.

2 1 shows a further embodiment of a device for monitoring the discharge 1, the discharge sensor 3 of which is arranged in front of the odor trap 9 and is designed as a conductivity sensor with the electrodes 4a and 4b. The electrodes 4a and 4b are electrically isolated from each other and only by one from the sink 16 in the Wastewater drainage 15 effluent, electrically conductive liquid such as water, conductively connected. The flow sensor 3 periodically applies two clocked square-wave signals in the frequency range of preferably 1 to 100 kilohertz with the same amplitude and frequency or period to the electrodes 4a and 4b, the square-wave signal at the electrode 4b being phase-shifted by 180° with respect to the square-wave signal at the electrode 4a, detects the current flowing between electrodes 4a and 4b and uses it to determine the electrical conductance 3' of the liquid flowing out via electrodes 4a and 4b. The advantage of this type of control is that the signals are easy to generate, the mean potential difference formed between the electrodes 4a and 4b during a period is approximately 0 and the high frequency largely prevents corrosion of the electrodes 4a and 4b. The communication unit 7 has a USB interface that is coupled to the terminal sanitary fitting 2 via the cable 8 . As in 1 the power supply 11 is designed as a plug-in power supply unit and supplies both the terminal sanitary fitting 2 and the device for monitoring the drain 1. The electronic circuit unit 6 periodically monitors the draining of the liquid from the washbasin 16 into the sewage system 15 based on the conductance detected by the drain sensor 3. The overflow protection 19 generates the status message 20 with the information as to whether or not there is a blockage of the drain 24 from the washbasin 16 into the sewage system 15, which is transmitted by the communication device 7 to the terminal sanitary fitting 2 coupled via the USB interface. In exactly the opposite transmission direction, the information on the valve status 22 is transmitted from the electronic circuit unit 18 of the terminal sanitary fitting 2 via the communication device 7 to the overflow protection device 19 and the electronic circuit unit 6 as a basis for determining whether the outflow sensor 3 indicates that an outflow from the terminal sanitary fitting 2 is being discharged Liquid is to be detected.

At time t ₁ the terminal sanitary fitting 2 opens the electrically actuated valve 12 and transmits the valve status 22 to the device for monitoring the outflow 1. The outflow sensor 3 first detects the outflow from the washbasin 16 at the increase in the conductance 3', which is caused by the blockage of the outflow 24 returns to 0 at time t ₂ . The overflow protection 19 then generates the status message 20 and transmits it to the terminal sanitary fitting 2, whereupon the electronic circuit unit 18 contained in it closes the electrically actuated valve 12. At time t ₃ the blockage of the drain 24 is released and the liquid remaining in the washbasin 16 flows through the drain of the washbasin 16 and the odor trap 9 into the sewage system 15, the drain sensor 3 detects an increase in the conductance 3`, the overflow protection 19 generates the Status message 20 and transmits this in turn to the terminal sanitary fitting 2. At time t ₄ , the terminal sanitary fitting 2 opens the electrically actuated valve 12 again. When the drain 24 is blocked at time t ₅ , the overflow protection 19 generates the status message 20 and the terminal sanitary fitting 2 closes the electrically actuated valve 12 with the electronic circuit unit 18.

In a particularly advantageous embodiment, the outflow sensor 3 calculates an averaged reference value during the periodic measurement of the electric current flowing between the electrodes 4a and 4b and tracks it. This compensates for influences on the measured value caused by deposits on the electrodes 4a and 4b, for example due to the entry of dirty liquids from the washbasin 16 or the sewage system 15.

In a further refinement, the device for process monitoring 1 is also coupled via the communication unit 7 with the USB interface to at least one information technology device 17 - for example a computer, tablet or building control system - which visualises, processes and/or stores the process fault messages.

In different configurations, the communication unit 7 includes at least one RS-232 interface, USB interface, LAN interface, fiber optic interface, WLAN interface, Bluetooth interface, Thunderbolt interface, LoRa interface, mobile radio interface, radio interface in an ISM band, ultrasonic interface, infrared interface and/or at least one potential-free opening or closing contact.

3 shows an over 2 Going further embodiment of a device for flow monitoring 1, the flow sensor 3 is executed from a first flow sensor 3a and a further flow sensor 3b. Outflow sensor 3 has the electrodes 4a, 4b and 4c, the first outflow sensor 3a being formed by a conductivity measurement of the pair of electrodes 4a and 4b and the further outflow sensor 3b being formed by a conductivity measurement of the pair of electrodes 4a and 4c. The conductance measurement of the first outflow sensor 3a and the further outflow sensor 3b takes place as in 2 described. The electrodes 4a and 4b are arranged in front of the odor trap 9 that when the water drains from the sink 16 into the sewage system 15, a conductive compound connection between electrode 4a and electrode 4b is established. In contrast to this, the electrode 4c is arranged after the odor trap 9 in such a way that a conductive connection between the electrodes 4a and 4c is only established in the event of a backwater from the sewage system 15. Both the overflow protection 19 according to 2 as well as the overflow protection 19 after 3 are able to detect a blockage of the drain 24 from the washbasin 16 into the sewage system 15. Advantageously according to the design 3 is that a detection of a backlog from the sewage system 15 is possible regardless of the position of the electrically operated valve 12, while the overflow protection 19 after 2 can detect a backwater in the sewage system 15 only when the electrically operated valve 12 is closed. The communication unit 7 is designed with a Bluetooth interface. In the 3 The illustrated device for process monitoring 1 also includes the energy supply 11 designed as an accumulator with the connection 10 for charging the accumulator with a charger, for example, and is designed as an independent device that is only coupled to the terminal sanitary fitting 2 via Bluetooth.

In a further refinement, the device for process monitoring 1 is also coupled via the communication unit 7 with the Bluetooth interface to at least one information technology device 17 - for example a computer, tablet or smartphone - which visualises, processes and/or stores the process error messages.

In a particularly advantageous embodiment, circuit parts of the overflow protection 19, the communication unit 7, the power supply 11, the drain sensor 3, the electronic circuit unit 18 of at least one terminal sanitary fitting 2 and/or the connection 10 are designed as components of the electronic circuit unit 6 and integrated into the assembly of the electronic circuit unit 6 integrated.

In different embodiments, at least one of the electrodes 4a, 4b and 4c is arranged before, in or after the odor trap 9. At least part of the outflow sensor 3 is therefore arranged in the direction of flow before or after the odor trap 9 or in the odor trap 9 . Alternatively, the outflow sensor 3 has additional electrodes that are not shown.

4 shows a further embodiment of a device for outflow monitoring 1, the outflow sensor 3 of which is designed as an impeller wheel which converts the kinetic energy of the liquid draining from the washbasin 16 into the sewage system 15 into electrical pulse packets 23 and via the cable 8 and the connection 10 of the electronic circuit unit 6 and the battery designed as a power supply 11 feeds. The energy supply 11 uses part of the energy contained in the electrical pulse packets 23 to charge the accumulator. The electronic circuit unit 6 periodically monitors the electrical pulse packets 23 generated by the outflow sensor 3 and thus a blockage of the outflow 24 from the washbasin 16 into the sewage system 15. The overflow protection 19 generates the status message 20. The communication unit 7 is designed with an infrared interface and is coded the status message 20 in the infrared signal packet 14. The terminal sanitary fitting 2 has, in addition to the electronic circuit unit 18, the infrared sensor 13. If this detects the hands of a user, for example, the electronic circuit unit 18 of the terminal sanitary fitting 2 with the electrically actuated valve 12 automatically opens the water flow and closes the water flow automatically with the electrically actuated valve 12 after the end of hand washing or the expiry of a maximum running time. With the infrared sensor 13, the electronic circuit unit 18 of the terminal sanitary fitting 2 also detects the infrared signal packet 14 emitted by the communication unit 7 and reflected by the washbasin 16, decodes the status message 20 and stops the water flow if the drain 24 is blocked. Exactly in the opposite direction of transmission, the information is transmitted from the terminal sanitary fitting 2 to the discharge monitoring device 1.

The electronic circuit unit 18, the infrared sensor 13 and the electrically operated valve 12 are arranged within the sanitary fitting 2 at the end.

In alternative configurations, parts of the outflow sensor 3, the electronic circuit unit 6, the overflow protection 19, the communication unit 7 and/or the energy supply 11 are arranged in a common housing or in at least two housings. In particular embodiments, parts of the electronic circuit unit 6, the overflow protection 19, the communication unit 7, the energy supply 11 and/or the outflow sensor 3 are coupled via cables.

In different embodiments, the outflow sensor 3 comprises at least one float sensor, conductivity sensor, inductive sensor, capacitive sensor, impeller sensor, infrared sensor, temperature sensor, sensor with image output evaluation, flow sensor, flow sensor and/or ultrasonic sensor. In further embodiments, the outflow sensor 3 is connected to the overflow protection 19 by wire or wirelessly. In other embodiments, the outflow sensor 3 is connected to the overflow protection 19 by wire or wirelessly via the communication unit 7 and/or the electronic circuit unit 6 .

In further embodiments, the connection 10 is designed to supply energy to the flow monitor 1 and/or to supply energy to the sanitary fitting at the end. In a special embodiment, the terminal sanitary fitting 2 is also coupled to the energy supply 11 via the connection 10 . This supplies not only the device for monitoring the flow 1, but also the terminal sanitary fitting 2.

In further embodiments, at least the electronic circuit unit 18, the infrared sensor 13 or the electrically actuated valve 12 are arranged outside the sanitary fitting 2 at the end.

In a particularly advantageous embodiment, the electronic circuit unit 18 closes the electrically actuated valve 12 even while the hands of a user are being detected by the infrared sensor 13, for example, if the device for monitoring the flow 1 signals a blockage of the flow 24.

reference list

1

Device for process monitoring ( 1-4 )

2

Terminal plumbing fixture ( 1-4 )

3

drain sensor ( 1-4 )

3'

conductance ( 2 ) [of the outflow sensor 3 in normalized representation]

3a

First drain sensor ( 3 )

3b

Additional drain sensor ( 3 )

4a

electrode ( 2 , 3 )

4b

electrode ( 2 , 3 )

4c

electrode ( 3 )

5a

Ultrasound Transducer ( 1 )

5b

Ultrasound Transducer ( 1 )

6

Electronic circuit unit ( 1-4 ) [of the process monitoring device 1]

7

communication unit ( 1-4 )

8th

Cable ( 1-2 , 4 )

9

odor trap ( 1-3 )

10

Connection ( 1-4 )

11

Power supply ( 1-4 )

12

Electrically operated valve ( 1-4 )

13

infrared sensor ( 4 )

14

infrared signal package ( 4 )

15

sewage system ( 1-4 )

16

Bathroom sink ( 1-4 )

17

Information technology device ( 2 , 3 )

18

Electronic circuit unit ( 1-4 ) [of the terminal sanitary fitting 2]

19

overflow protection ( 1-4 )

20

status message ( 1-2 , 4 )

21

liquid level ( 1 )

22

valve status ( 2 , 4 )

23

electrical impulse packet ( 4 )

24

blockage of expiry ( 1-2 , 4 )

QUOTES INCLUDED IN DESCRIPTION

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

Patent Literature Cited

• EP 2762646 [0006]
• DE 102006021838 [0006]
• AT404150 [0007]
• AT514160 [0007]
• DE 19651132 [0007]
• DE 10148675 [0007]
• EP 2169123 [0007]
• EP 0813636 [0007]
• US5961095 [0007]
• DE 102009030534 [0007]
• US2004254746 [0007]
• AT506792 [0007]
• DE 10111210 [0008]
• DE 2153344 [0008]
• DE 19755998 [0008]
• AT412353 [0008]
• DE 102020103121 [0008]
• DE 102013102567 [0009]
• DE 102018009511 [0009]
• DE 102020000841 [0009]
• US2018306617 [0010]
• US2018291594 [0010]
• WO 2020083518 [0010]

Claims (10)

Device for outflow monitoring (1) with an electronic circuit unit (6), an overflow protection (19), an energy supply (11), at least one outflow sensor (3) and a communication unit (7) electrically coupled to at least one terminal sanitary fitting (2) with at least an electrically actuated valve (12) controlled by an electronic circuit unit (18), characterized in that a) the outflow sensor (3) is designed to detect the flow of liquid discharged from at least one of the terminal sanitary fittings (2) into the sewage system (15); b) the electronic circuit unit (6) is designed to detect a blockage of the drain (24); c) the overflow protection (19) is designed to generate a status message (20) and d) the communication unit (7) is designed to transmit a status message (20) to at least one of the terminal sanitary fittings (2). Device for process monitoring (1) after claim 1 characterized in that the communication unit (7) is designed to transmit the status message (20) generated by the overflow protection (19) when a blockage of the drain (24) into the sewage system (15) is detected. Device for process monitoring (1) after claim 1 or 2 characterized in that parts of the flow sensor (3), the electronic circuit unit (6), the overflow protection (19), the communication unit (7) and/or the power supply (11) are arranged in a common housing or in at least two housings. Device for process monitoring (1) according to one of Claims 1 until 3 characterized in that at least one component of the device for monitoring the discharge (1) is arranged in or on the terminal sanitary fitting (2). Device for process monitoring (1) according to one of Claims 1 until 4 characterized in that the energy supply (11) comprises at least one power pack, a battery, an accumulator, a capacitor, an impeller, a thermal generator, a piezoelectric generator and/or a solar cell. Device for process monitoring (1) according to one of Claims 1 until 5 characterized in that the flow sensor (3) a) includes at least one float sensor, conductivity sensor, inductive sensor, capacitive sensor, impeller sensor, infrared sensor, temperature sensor, sensor with image evaluation, flow sensor, flow sensor and/or ultrasonic sensor and/or b) wired or wireless with is connected to the overflow protection (19) and/or c) is connected to the overflow protection (19) by wire or wirelessly via the communication unit (7) and/or the electronic circuit unit (6). Device for process monitoring (1) according to one of Claims 1 until 6 characterized in that a) the communication unit (7) has at least one RS-232 interface, USB interface, LAN interface, glass fiber interface, WLAN interface, Bluetooth interface, Thunderbolt interface, LoRa interface, mobile radio interface , Radio interface in an ISM band, ultrasonic interface, infrared interface and/or at least one potential-free opening or closing contact and/or b) the device for process monitoring (1) via the communication unit (7) with at least one device information technology (17) is coupled. Device for process monitoring (1) according to one of Claims 1 until 7 characterized in that circuit parts of the overflow protection (19), the communication unit (7), the energy supply (11), the outflow sensor (3), the electronic circuit unit (18) of at least one terminal sanitary fitting (2) and/or the connection (10) designed as components of the electronic circuit unit (6) and integrated into the assembly of the electronic circuit unit (6). Device for process monitoring (1) according to one of Claims 1 until 8th with an odor trap (9), characterized in that at least part of the outflow sensor (3) is arranged in the direction of flow before or after the odor trap (9) or in the odor trap (9). Device for process monitoring (1) according to one of Claims 1 until 9 with a connection (10), characterized in that a) the connection (10) is designed to supply energy to the device for monitoring the discharge (1) and/or b) the connection (10) is designed to supply energy to the terminal sanitary fitting (2).

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