EP3708720B1 - Method for operating at least one building drinking water network - Google Patents

Description

The invention relates to a method for controlling a building drinking water network with sanitary fittings using an internet-based cloud server system according to claim 1 and a hygiene flushing system according to claim 16.

The hygiene requirements for the drinking water supply of buildings or building complexes have increased significantly in recent years. The reason for this is the realization that standing water in the building's drinking water network for a long period of time, which is also referred to as stagnant water, can lead to the undesirable formation of germs. In this context, legionella or similar germs pose a health risk. Consequently, the relevant building drinking water network has been flushed regularly, which is referred to here as "hygiene flushing". Depending on the rinsing strategy, the germs are rinsed out, decimated and/or killed so that the water is again impeccable from a hygiene point of view.

A known method of operating a building potable water network ( DE 93 13 983 U1 ) relates to the automatic flushing of the building's drinking water network through the automatic actuation of electrically controllable water outlet points. The sanitary fittings are coupled via a data bus system to a controller arranged in the relevant building, so that a flushing plan stored in the controller can be processed automatically. The bus system between the control and the sanitary fittings is structured via intermediate controls, which leads to a correspondingly complex control structure, particularly in the case of complex building drinking water networks. This also means that a building technology extension is always accompanied by a corresponding control technology challenge.

In addition, an appropriate design of the computing power of the controller is hardly possible with the known method, since the required Computing power changes constantly with changing hygiene requirements on the one hand and with changing building technology requirements on the other.

Finally, in the case of the known method, the building drinking water network works autonomously to the extent that information from outside, for example information from building drinking water networks to be operated in parallel, is not used in the implementation of hygiene flushing. With this lack of information, there is considerable optimization potential with regard to the quality of hygienic dishwashing.

The invention is based on the problem of designing and developing the known method for operating a building's drinking water network in such a way that the hygienic flushing is optimized with little outlay on control technology.

The above problem is solved with a method for operating at least one building drinking water network with the features of claim 1.

First of all, it is proposed that the building drinking water network is operated using an internet-based cloud server system. Such a cloud server system is a server system that is spatially independent of the building's drinking water network to be operated, since it communicates with the building's drinking water network via the Internet. The cloud server system preferably makes available the computing power that is required by the building's drinking water network. Furthermore, the cloud server system has access to information from external data sources via the Internet, on the basis of which hygienic flushing can be optimized according to various criteria. An example of this is weather information, which provides information on whether nucleation in the building drinking water network is weather-supported, which should result in increased hygienic flushing.

The building's drinking water network is equipped with sanitary fittings designed as water outlet points, each of which has an electrically controllable water outlet valve and a mobile radio-capable fitting control. So it is the sanitary fittings in each case possible to communicate via a cellular connection. This results in the structural advantage that an extension or reduction of the building's drinking water network is unproblematic in terms of control technology.

According to the proposal, communication objects in the form of hygiene flushing instructions are generated by the cloud server system according to a hygiene flushing strategy. For the generation of the hygiene flushing instructions according to the hygiene flushing strategy, all the above-mentioned information from external data sources is also available, so that the generation of the hygiene flushing instructions can be optimized and adapted to the current information.

The hygiene flushing instructions generated in this way are then transmitted to the respective faucet control via a mobile radio connection between a public mobile radio access point and the faucet control. What is interesting is the fact that a mobile phone connection is provided between a public mobile phone access point and the faucet control. The cellular access point is a gateway between the cellular network and the Internet. With regard to the mobile phone connection, a decentralized approach was chosen according to the proposal, in which each sanitary fitting sets up a mobile phone connection to the public mobile phone access point in question.

In the present case, the term "public" merely means that the mobile radio access point is also accessible to mobile radio subscribers who do not belong to the building's drinking water network.

The hygiene flushing instructions generated and transmitted by the cloud server system can be implemented by the respective faucet controller by activating the respective water outlet valve. This means that the proposed method is not limited to the method step of implementing the hygiene flushing instructions on the part of the valve controls. Initially, it is only a question of the feasibility of the hygiene flushing instructions on the part of the valve controls. Provision is only preferably made for the proposed method to include the method step of implementing the hygiene flushing instructions generated and transmitted by the cloud server system by controlling the respective water outlet valve.

The proposed method combines a central control aspect, namely the control of all sanitary fittings by one and the same cloud server system, with a decentralized control aspect, namely the implementation of a mobile phone connection for each individual sanitary fitting.

The latter, decentralized control aspect, as already indicated above, ensures flexibility in the design of the building's drinking water network without any restrictions being expected in terms of control technology. This goes back to the idea that each sanitary fitting organizes communication with the mobile radio access point independently. Retrofitting an existing building drinking water network is also unproblematic.

Due to the Internet-based cloud server system, the first-mentioned, central control aspect enables use for all sanitary fittings that are operated by the cloud server system, so that hygienic flushing is optimized in a way that was previously only possible with great effort.

Finally, the central control aspect of the proposed method results in the additional advantages of a uniform software management for all sanitary fittings, a uniform error diagnosis for all sanitary fittings and an emergency function, such as the emergency shutdown of all sanitary fittings.

The preferred configurations according to claims 2 and 3 relate to structural aspects in particular for the case that the cloud server system operates at least two spatially separate building drinking water networks. Then, in a preferred variant of claim 2, operating information from one building's drinking water network can be used to operate another building's drinking water network. This shows an important advantage of the central cloud server system, namely the advantage of the availability of information, which is only possible with a central structure.

The further preferred embodiments according to claims 4 and 5 relate to details of the hygiene flushing instructions. Claim 4 makes it particularly clear that the hygiene flushing instructions can be direct instructions in the sense of a switching command, but also indirect instructions in the sense of specifying a time for the relevant hygiene flushing action.

The likewise preferred embodiments according to claims 6 and 7 relate to the possibility of bidirectional data transmission between the cloud server system and the faucet controls, in that the faucet controls each generate faucet communication objects and transmit them to the cloud server system via the respective mobile radio connection. In a particularly preferred embodiment according to claim 6, the dashboard communication objects represent status information and/or dashboard sensor information and/or user inputs. Other types of valve communication objects are conceivable.

With the above, bidirectional communication between the cloud server system and the faucet controls, a feedback from the faucet controls to the cloud server system can be established, which ranges from a simple confirmation of the implementation of a hygiene flushing instruction to a control-technical feedback.

In the particularly preferred embodiment according to claim 8, there is no need for any intermediate data processing between the cloud server system and the sanitary fittings. This means that there is no data processing of the communication objects that goes beyond measures for data transport. This corresponds to a consistent implementation of the central control aspect of the proposed procedure mentioned above.

A preferred option for the transmission of user communication objects is the subject of claim 9. Here it is proposed that an internet-based user terminal is provided for this purpose, which communicates with the cloud server system via an internet connection. This enables the user to access the cloud server system regardless of where they are. This is associated with a particularly high level of user comfort.

The further preferred configurations according to claims 10 to 13 relate to the generation of a hygiene flushing plan from hygiene flushing actions using the cloud server system (claim 10). The basis for this is the hygiene flushing strategy, which can be selected differently depending on the building's drinking water network and in particular depending on various environmental conditions such as the ambient temperature.

A particularly simple optimization of the hygiene flushing plan is the subject of claim 14, in which the hygiene flushing plan is optimized according to a predetermined optimization criterion, preferably according to the optimization criterion of the state of hygiene, the water consumption or the energy consumption. This optimization of the hygiene flushing plan is also particularly easy to implement with the central control aspect of the proposed method.

A further increase in user comfort can be achieved according to claim 15 in that status information relating to the building drinking water network to be operated is generated by the cloud server system and is output here and preferably via the above user terminal. This means that the user is informed about the current status of the building's drinking water network, regardless of where he is.

According to a further teaching, which is of independent importance, a hygiene control system for carrying out the proposed method is claimed as such.

According to the further teaching, the fact that the hygiene control system has the above cloud server system, which is set up to carry out the proposed method, is essential. A building potable water network above as such is not attributable to the hygiene control system. To all Statements on the proposed method according to the first-mentioned teaching may be referred to.

Fig. 1

in einer schematischen Darstellung zwei Gebäude-Trinkwassernetzwerke, die nach einem vorschlagsgemäßen Verfahren von einem internetbasierten Cloud-Serversystem betrieben werden und

Fig. 2

ein vorschlagsgemäßes Verfahren zum Betreiben der in Fig. 1 dargestellten Gebäude-Trinkwassernetzwerke in einem Ablaufdiagram.

The invention is explained in more detail below with reference to a drawing that merely shows an exemplary embodiment. In the drawing shows

1

in a schematic representation of two building drinking water networks, which are operated by an internet-based cloud server system according to a proposed method and

2

a proposed method for operating the in 1 illustrated building drinking water networks in a flow chart.

The proposed method is used to operate at least one building drinking water network, here the operation of a first building drinking water network 1 and the operation of a second building drinking water network 2. In principle, the proposed method for operating a plurality of building drinking water networks 1, 2 can be provided. All statements relating to the two building drinking water networks 1, 2 shown apply accordingly to all other building drinking water networks 1, 2 that may be provided.

The first building drinking water network 1 is equipped with sanitary fittings 3-6, while the second building drinking water network 2 is equipped with only a single sanitary fitting 7, shown as an example. The proposed method is explained below primarily on the basis of the first building drinking water network 1, which is not to be understood as limiting.

The sanitary fittings 3-7 can be any sanitary fitting that has a water outlet valve for letting out drinking water. This includes, for example, washbasin fittings, shower facilities, toilets, urinals, or the like. Correspondingly, this does not include all types of shut-off valves that do not allow water to escape.

1 shows that an internet-based cloud server system 8 is provided, which represents the central control aspect of the proposed solution, as will be shown.

The sanitary fittings 3-7 each have an electrically controllable water outlet valve 3a-7a and a mobile radio-capable fitting control 3b-7b. "Electrically controllable" means here in general that the sanitary fittings 3-7 designed as water outlet points are set up to be opened and closed electrically by a corresponding control by the fitting control 3b-7b in order to allow or block the discharge of drinking water.

In the present case, the term “internet-based” in connection with the cloud server system 8 means that the cloud server system 8 is set up to communicate via an internet connection.

According to the proposed method, as in 2 shown, generated by the cloud server system 8 communication objects in the form of hygiene flushing instructions 9 according to a hygiene flushing strategy 10 (method step A in 2 ). The hygiene flushing strategy 10 depends on various influencing factors, as will be explained below.

The generated hygiene flushing instructions 9 are transmitted to the respective fitting control 3b-7b via a mobile radio connection 3c-7c between a public mobile radio access point 11 and the fitting control 3b-7b (method step B in 2 ). Finally, it is the case that the hygiene flushing instructions 9 received can be implemented, preferably implemented, by the fitting control 3b-7b by activating the water outlet valve 3a-7a (method step C in 2 ).

In order to implement the mobile radio connections 3c-7c, the fitting controls 3b-7b are preferably equipped with an LTE module (Long Term Evolution mobile radio standard), in particular with a narrowband LTE module. Other possibilities for realizing the mobile radio connections 3c-7c are conceivable.

It can be shown in accordance with 1 see that by means of the cloud server system 8 at least two spatially separate building drinking water networks 1, 2 are operated. It is preferably the case that the cloud server system 8 generates operating information during the operation of a first building's drinking water network 1 , which is used by the cloud server system 8 for operating a second building's drinking water network 2 . In the simplest case, this means that the cloud server system 8 uses the hygienic flushing strategy 10 of the first building's drinking water network to operate the second building's drinking water network 2 . As mentioned above, this shows the advantage of the central control approach of the proposed solution.

In a preferred embodiment, the building drinking water network 1, 2 to be operated is assigned to a building 12, 13 or a building complex. Here, and preferably, the building drinking water networks 1, 2 to be operated are each assigned to a building 12, 13 or a building complex. The building complex can be defined arbitrarily and is not limited to adjacent buildings. In this respect, the term "building complex" is to be understood broadly. In particular, a building complex can accordingly extend over internationally distributed buildings.

In principle, individual building drinking water networks 1, 2 and/or individual sanitary fittings 3-7 can be combined into logical groups in the cloud server system 8, which are each controlled uniformly with regard to predetermined group rules. For example, provision can be made for all sanitary fittings 3-7 in a logical group to be flushed in uniform flushing cycles. This can be provided in addition to the hygiene flushing, which is triggered locally, for example due to locally high ambient temperatures.

The communication between the cloud server system 8 and the valve controls 3b-7b runs in sections based on the Internet and in sections based on mobile communications. 1 shows that the cloud server system 8 communicates with the cellular access point 11 via an Internet connection 14, while the cellular access point 11 communicates with the faucet controls 3b-7b as above addressed communicated via the cellular connections 3c-7c. What is interesting here is the combination of the central control aspect with the decentralized control aspect mentioned above.

The hygiene flushing instructions 9 each relate to the implementation of at least one hygiene flushing action, which can involve, for example, draining drinking water at a hygiene flushing time over a hygiene flushing duration. Accordingly, the hygiene flushing instructions 9 each include at least one hygiene flushing parameter describing the hygiene flushing action to be implemented. In particular, it is preferably the case that the at least one hygiene flushing parameter is a hygiene flushing time relating to the hygiene flushing action, a hygiene flushing duration or the like relating to the hygiene flushing action. is. It must be taken into account here that the hygiene flushing time can also describe the immediate actuation of the relevant water outlet valve 3a-7a. Then the hygiene flushing instructions 9 are nothing more than switching commands for the water outlet valve 3a-7a.

In addition to the hygiene flushing instructions 9, the cloud server system 8 preferably also transmits further cloud communication objects via the respective mobile radio connection 3c-7c to the respective fitting control 3b-7b. This includes, for example, a configuration data set, via which the respective fitting control 3b-7b can be brought into a predetermined operating mode. Such operating modes can be, for example, a comfort mode, an energy-saving mode, a water-saving mode or the like.

In principle, the configuration data record can comprise only a single configuration parameter or else a plurality of configuration parameters.

Depending on the application, numerous other cloud communication objects are conceivable, which can include instructions of all kinds. For example, a cloud communication object can represent an emergency stop instruction, upon receipt of which the faucet controls 3b-7b close the water outlet valve 3a-7a.

As explained above, bidirectional communication is preferably provided between the cloud server system 8 and the fitting controls 3b-7b. It is preferably the case that the fitting controls 3b-7b generate fitting communication objects and transmit them to the cloud server system 8 via the respective mobile radio connection 3c-7c. Such dashboard communication objects can represent, for example, status information and/or dashboard sensor information and/or user inputs. The status information can relate, for example, to a connection status to the mobile radio access point 11, the battery level of a supply battery for the fitting control 3b-7b, or confirmation of the completion of a rinsing action.

To generate the fitting sensor information, at least some of the sanitary fittings 3-7 have at least one sensor 15, which is shown as an example on the sanitary fitting 5. The sensor 15, which is designed here and preferably as a temperature sensor, generates fitting sensor information which is transmitted to the cloud server system 8 as a fitting communication object via the mobile radio connection 3c-7c.

The representation according to 1 shows that the cloud communication objects and/or the fitting communication objects are transmitted between the cloud server system 8 and the sanitary fittings 3-7 without any intermediate data processing. In the Internet connection 14 and in the mobile radio connections 3c-7c as well as in the mobile access point 11, which is merely a gateway, no data processing takes place that goes beyond measures for data transport, so that the relevant control hardware can be dispensed with.

In order to be able to communicate with the user, user communication objects are preferably provided, which are transmitted between an Internet-based user terminal 16, 17 and the cloud server system 8 via an Internet connection 18. The user communication objects are preferably implemented in the form of user input from a user and/or user output to the user via the user terminal 16, 17. 1 shows an example of a first user terminal 16 in the form of a personal computer and a second user terminal 17 in the form of a handheld device, here a smartphone. The Internet connection of the user terminals 16, 17 is advantageous here, so that communication is possible with the cloud server system 8 via the Internet connection 18 regardless of where the user is located.

The above generation of the hygiene flushing instructions is preferably based on the generation of a hygiene flushing plan which is composed of hygiene flushing actions for the individual sanitary fittings 3-7. The hygienic flushing plan is generated according to the hygienic flushing strategy 10. According to the hygiene flushing plan, the hygiene flushing actions are triggered based on time and/or events.

In a particularly preferred embodiment, the hygiene flushing plan is generated according to the hygiene flushing strategy as a function of local status information 19 relating to the status of the building's drinking water network 1, 2 to be operated, here and preferably of fittings sensor information.

The proposed use of a cloud server system is particularly advantageous if the cloud server system 8 receives global environmental information 20, here and preferably weather information relating to the spatial territory of the building drinking water network 1, 2 to be operated and/or water status information from the water works , The hygiene flushing plan being generated according to the hygiene flushing strategy as a function of the global environmental information 20 .

A further optimization of the hygiene flushing can be achieved in that history information is generated by the cloud server system 8 from the time profile of the local status information 19 and/or the global environmental information 20 and/or the user inputs, with the hygiene flushing plan depending on the hygiene flushing strategy generated from the history information. In this way, the operating history of the relevant building drinking water network 1, 2 can be included in the generation of the hygiene flushing instructions by means of the cloud server system 8.

In a further preferred embodiment, the hygiene flushing plan is optimized by the cloud server system 8 according to a predetermined optimization criterion.

A control loop can be implemented here whose reference variable corresponds to the optimization criterion. The optimization criterion can, for example, relate to the state of hygiene, the water consumption, the energy consumption or the like of the building's drinking water network 1, 2 to be operated.

An important part of the proposed method is efficient information for the user about the status of the building drinking water networks 1, 2 to be operated. Accordingly, it is here and preferably provided that the cloud server system 8 receives status information relating to the building drinking water network 1 to be operated , 2 is generated. In a particularly preferred embodiment, the status information relates to the state of hygiene, the water consumption, the energy consumption or the like of the building drinking water network 1, 2 to be operated.

Finally, it should also be pointed out that the proposed method is not limited to the communication between the cloud server system 8 and the fitting controls 3b-7b. Rather, provision can also be made for the cloud server system 8 to communicate with other systems, such as a heating system, an air conditioning system, a ventilation system or the like, in order to further optimize hygienic flushing. In particular, if the heating system provides temperature control for the drinking water to be let out for hygiene rinsing, appropriate coordination between the rinsing actions and the temperature of the drinking water, in particular coordination between the cloud server system 8 and the heating system, is required.

Claims (16)

1. Method for operating at least one building drinking water network (1, 2) with sanitary fittings (3-7) by means of an Internet-based cloud server system (8), wherein the sanitary fittings (3-7) are designed as water outlet points and respectively have an electrically activatable water outlet valve (3a-7a) and a mobile-enabled fitting controller (3b-7b), wherein communication objects in the form of hygiene flushing instructions (9) are generated by the cloud server system (8) in accordance with a hygiene flushing strategy (10), wherein the generated hygiene flushing instructions (9) are transmitted to the respective fitting controller (3b-7b) via a cellular connection (3c-7c) between a public wireless access point (11) and the fitting controller (3b-7b) and wherein the received hygiene flushing instructions (9) can be implemented, in particular are implemented, by the fitting controller (3b-7b) by an activation of the water outlet valve (3a-7a).
2. Method according to Claim 1, characterized in that at least two building drinking water networks (1, 2) that are spatially separate from one another are operated by means of the cloud server system (8), preferably in that, during the operation of one building drinking water network (1), the cloud server system (8) generates operational information that is used by the cloud server system (8) for the operation of a second building drinking water network (2), more preferably in that the hygiene flushing strategy (10) of the first building drinking water network (1) is used by the cloud server system (8) as a basis for the operation of the second building drinking water network (2).
3. Method according to one of the preceding claims, characterized in that the building drinking water network (1, 2) to be operated is assigned to a building (12, 13) or a building complex or in that the building drinking water networks (1, 2) to be operated are respectively assigned to a building (12, 13) or a building complex.
4. Method according to one of the preceding claims, characterized in that the hygiene flushing instructions (9) respectively concern the implementation of at least one hygiene flushing action, preferably in that the hygiene flushing instructions (9) respectively comprise at least one hygiene flushing parameter describing the hygiene flushing action to be implemented, more preferably in that the at least one hygiene flushing parameter is a hygiene flushing time concerning the hygiene flushing action, a hygiene flushing duration concerning the hygiene flushing action or the like.
5. Method according to one of the preceding claims, characterized in that, apart from the hygiene flushing instructions (9), further cloud communication objects, preferably a configuration data set, are transmitted by the cloud server system (8) via the respective cellular connection (3c-7c) to the respective fitting controller (3b-7b).
6. Method according to one of the preceding claims, characterized in that fitting communication objects are generated by the fitting controllers (3b-7b) and are transmitted via the respective cellular connection (3c-7c) to the cloud server system (8), preferably in that the fitting communication objects represent fitting status information and/or fitting sensor information and/or user inputs.
7. Method according to one of the preceding claims, characterized in that at least some of the sanitary fittings (3, 7) have at least one sensor (15), which generates an item of fitting sensor information, and in that the item of fitting sensor information is transmitted as a fitting communication object via the cellular connection (3c-7c) to the cloud server system (8) .
8. Method according to one of the preceding claims, characterized in that the cloud communication objects and/or the fitting communication objects are transmitted between the cloud server system (8) and the sanitary fittings (3-7) without interim data processing.
9. Method according to one of the preceding claims, characterized in that user communication objects are transmitted between an Internet-based user terminal (16, 17) and the cloud server system (8) via an Internet connection (18), preferably in that user communication objects in the form of user inputs of a user and/or user outputs are transferred to the user via the user terminal (16, 17), preferably in that the user terminal (16, 17) is a personal computer, a handheld device, in particular a smartphone, or the like.
10. Method according to one of the preceding claims, characterized in that a hygiene flushing plan comprising hygiene flushing actions is generated by the cloud server system (8) from the hygiene flushing strategy (10) and in that, in accordance with the hygiene flushing plan, the hygiene flushing actions are initiated in a timebased and/or an event-based manner.
11. Method according to Claim 10, characterized in that the hygiene flushing plan is generated in accordance with the hygiene flushing strategy (10) in dependence on local status information (19) concerning the status of the building drinking water network (1, 2) to be operated, in particular on fitting sensor information.
12. Method according to Claim 10 or 11, characterized in that global environmental information (20), in particular weather information concerning the spatial territory of the building drinking water network (1, 2) to be operated and/or water status information on the waterworks side is received by the cloud server system (8) and in that the hygiene flushing plan is generated in accordance with the hygiene flushing strategy (10) in dependence on the global environmental information (20).
13. Method according to one of Claims 10 to 12, characterized in that an item of historical information is generated by the cloud server system (8) from the progression over time of the local status information (19) and/or the global environmental information (20) and/or the user inputs and in that the hygiene flushing plan is generated in accordance with the hygiene flushing strategy (10) in dependence on the historical information.
14. Method according to one of Claims 10 to 13, characterized in that the hygiene flushing plan is optimized by the cloud server system (8) in accordance with a predetermined optimization criterion, preferably in that the optimization criterion concerns the hygiene status, the water consumption, the energy consumption, or the like of the building drinking water network (1, 2) to be operated.
15. Method according to one of the preceding claims, characterized in that an item of status information concerning the building drinking water network (1, 2) to be operated is generated by the cloud server system (8), preferably in that the item of status information concerns the hygiene status, the water consumption, the energy consumption, or the like of the building drinking water network (1, 2) to be operated.
16. Hygiene flushing system for carrying out a method according to one of the preceding claims, with an Internet-based cloud server system (8) for operating at least one building drinking water network (1, 2), which has sanitary fittings (3, 7), wherein the sanitary fittings (3, 7) are designed as water outlet points and respectively have an electrically activated water outlet valve (3a-7a) and a mobile-enabled fitting controller (3b-7b), wherein the cloud server system (8) is designed to generate communication objects in the form of hygiene flushing instructions (9) in accordance with a hygiene flushing strategy (10), wherein the generated hygiene flushing instructions (9) can be transmitted to the respective fitting controller (3b-7b) via a cellular connection (3c-7c) between a public wireless access point (11) and the fitting controller (3b-7b) and wherein the received hygiene flushing instructions (9) can be implemented by the fitting controller (3b-7b) by an activation of the water outlet valve (3a-7a).

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