DE102010032712B3 - Building automation system configuration method for controlling e.g. illumination devices within residential- or commercial building, involves transmitting confirmation about switch-on state of actuators to building automation system - Google Patents

Abstract

The method involves selecting actuators (12a-12d) on a mobile terminal (20) e.g. mobile telephone, and logically assigning manual activated sensors (10a-10d) to the selected actuators. Switch-on state of the selected actuators is automatically detected by a sensor of a mobile detection device (22). The mobile detection device is connected with a building automation system (11). Confirmation about the switch-on state of the selected actuators is transmitted to the building automation system over the mobile detection device.

Description

The invention relates to a method for configuring a building automation system and also to a building automation system.

Building automation systems are used to control a variety of operations within a residential or commercial building. In a building automation system, a large number of sensors and actuators are networked with one another. A controller can be used to program and control the interaction of the sensors and actuators.

The configuration and programming of a building automation system is very expensive. First of all, it is necessary to find out the physical address at which each actuator is wired to the building automation system or its controller. Furthermore, the respective sensors must be assigned to the correct actuators. Once this is done, programming of various application scenarios or profiles can begin. This is done by a specially trained technician using a suitable software and is therefore associated with a relatively large effort.

DE 102 02 714 A1 describes a method for assigning operating addresses in a control system for a plurality of actuators. These are connected via a bus system with a central commander. Each actuator is assigned an operating axis after delivery of an identification signal. When arranged in several areas actuators only those located in each selected area actuators are invited to submit an identification signal. As a result, the finding of the identifying actuator and thus the operation of the system is simplified.

DE 11 2007 001 804 T5 describes a building automation system using mobile terminals for its configuration.

The object of the invention is to provide a simplified method for configuring a building automation system.

The object is achieved by the features of claims 1-7.

In the method according to the invention is based on a building automation system in which a plurality of sensors and actuators are networked together. The sensors may, for example, be switches, temperature, brightness or other sensors, timers, etc. The actuators can be electrical drives, components of a heating or air conditioning system, lighting devices, etc.

• – Anwählen eines bestimmten Aktors durch einen Benutzer auf einem mobilen Endgerät
• – Übermitteln einer Information über den durch den Benutzer angewählten Aktor vom mobilen Endgerät zum Gebäudeautomationssystem
• – automatisches sequentielles Ein- und Ausschalten verschiedener nicht konfigurierter Aktoren
• – Bestätigen des Einschaltzustandes des angewählten Aktors durch den Benutzer am mobilen Endgerät oder durch eine mobile Detektionsvorrichtung, sobald dieser automatisch eingeschaltet wurde
• – Übermitteln der Bestätigung über den Einschaltzustand vom mobilen Endgerät oder der mobilen Detektionsvorrichtung an das Gebäudeautomationssystem
• – Speichern der physikalischen Adresse, an der der betreffende Aktor verdrahtet ist.

In the method according to the invention, the configuration of the actuators initially comprises the following method steps:

• - Selecting a specific actuator by a user on a mobile device
• - Transferring information about the selected by the user actuator from the mobile device to the building automation system
• - automatic sequential switching on and off of various non-configured actuators
• - Confirming the on state of the selected actuator by the user on the mobile device or by a mobile detection device, as soon as it has been turned on automatically
• - Transmitting the confirmation of the on-state of the mobile terminal or the mobile detection device to the building automation system
• - Saving the physical address to which the relevant actuator is wired.

• – Anwählen eines Aktors durch den Benutzer auf dem mobilen Endgerät
• – Übermitteln einer Information über den angewählten Aktor vom mobilen Endgerät zum Gebäudeautomationssystem
• – manuelles Aktivieren des Sensors, der zu dem angewählten Aktor gehört, durch den Benutzer
• – logisches Zuordnen des manuell aktivierten Sensors zu dem angewählten Aktor.

According to the invention, configuring the sensors further comprises carrying out the following method steps:

• - Selecting an actuator by the user on the mobile device
• - Transmission of information about the selected actuator from the mobile terminal to the building automation system
• - Manual activation of the sensor belonging to the selected actuator, by the user
• - Logically assigning the manually activated sensor to the selected actuator.

Thus, according to the invention, a simplified configuration of the building automation system is possible for which no special knowledge is required. It would even be possible that the configuration or programming of the building automation system is not performed by a technician but by the customer himself. When setting up the system by a technician, it is only necessary that all sensors and actuators be powered, i. H. be connected to the phase and the neutral and that they are also networked data technology. This can be done, for example, by simply connecting the sensors and actuators to a bus system.

In the method according to the invention, the fact that the user knows which sensor belongs to the selected actuator and thus can manually activate this sensor is used for configuring the sensors. For example, if the selected actuator is one Luminaire, the user knows the corresponding sensor, ie light switch, so that he can activate it manually. The knowledge of the user is thus used according to the invention to assign the sensors to the corresponding actuators.

Another significant advantage of the method according to the invention is its high fault tolerance. When installing a building automation system, it often happens that sensors or actuators are not wired in their designated location in the network.

In most cases, the components are still electrically wired correctly, but logically, they are not in the right place; H. in the place intended for them. So it may happen, for example, that two actuators were connected electrically correct, but were reversed in their position. The detection of such errors was associated with a great effort in systems that are known from the prior art, since a possible malfunction can not only have their cause in the exchange of position of two actuators, but also in other sources of error, the laborious succession must be excluded.

In contrast, in the method according to the invention, no malfunctions can be caused by a logical interchange of the position of various actuators or sensors, as long as these components are electrically connected correctly, d. H. as long as they have a connection to the phase and the neutral and are also connected to the system in terms of data technology. The lower error rate is due to the fact that only when carrying out the method according to the invention is a localization of the actuators and storing their physical address at which these actuators are wired, and also a logical assignment of the sensors to the corresponding actuators. As a result, a reconfiguration of the system is considerably simplified so that changes in the sensors or actuators used can be performed in a simple manner.

The said mobile terminal used by the user may be, for example, a smartphone, a mobile phone, a mobile computer such as a tablet PC, an ^iPad® or similar devices. On the mobile terminal, a corresponding application is installed, through which the said method steps are performed by the user.

The confirmation of the switch-on state of the selected actuator is performed by a mobile detection device. This may be a portable device comprising a sensor by which the on state of the selected actuator can be detected. For example, the selected actuator can be an incandescent lamp or another illuminant, whose on-state can be judged according to whether or not a voltage is applied to this actuator. This voltage can be tested for example by a voltage tester in the form of a screwdriver known from the prior art or by a similar device. Here, the device is data technology, in particular wireless, connected to the building automation system.

By confirming the switch-on state of the selected actuator is understood according to the invention that at the time at which the user or the mobile detection device detects that the selected actuator has been turned on by the building automation system, confirms this on state, d. H. tells the building automation system that the actuator has just been switched on. This should, of course, be done with a small time delay so that the building automation system can confirm the on-state to the correct actuator, i. H. can assign the actor who has just been switched on.

Before the on-state of the selected actuator is confirmed by the user or the mobile detection device, it is possible to communicate to the building automation system the information that the selected actuator is currently not turned on. The transmission of this negative information takes place until the user or the mobile detection device detects the switching on of the selected actuator and the on state of this selected actuator can be confirmed.

In other words, the user or the mobile detection device thus sends a "No" to the building automation system as long as the selected actuator has not been switched on. As soon as this selected actuator has been switched on, on the other hand, the information "yes" is transmitted to the building automation system, so that the on state of the selected actuator is hereby confirmed.

Due to the communication between the mobile detection device and the building automation system, a much faster confirmation of the on state of the user selected by the actuator is possible because the mobile detection device much faster than the user can recognize the on-state of the actuator and report back to the building automation system. Such a process takes about 4 to 5 seconds per manual activation of the power-on state by the user and can be shortened by the use of the mobile detection device many times.

It is preferably possible for an actuator profile with a multiplicity of different actuator states to be programmed by the following method steps:
First, several actuators are activated and / or adjusted by the user. Setting an actuator can be, for example, setting a specific power value. For example, a light bulb can be set to 50% light output. The entirety of the various actuator states selected or activated and / or set by the user is stored. This is done after a corresponding command that the user has entered on the mobile terminal. It is not necessary to save the actuator states of all activated or set actuators. Rather, it is possible that the user selects certain actuators whose actuator states are stored while the actuator states of the remaining actuators are not stored. The stored actuator states are assigned to an actuator profile, which is then retrievable by the user.

This can be done, for example, by setting up a corresponding command or softbutton on the mobile terminal, by means of which an actuator profile can be called up. As a result, preferably an automatic production of the entirety of the stored actuator states by the building automation system takes place.

The automatic sequential switching on and off of different unconfigured actuators preferably comprises the following steps:
Initially, half of the previously unconfigured actuators are switched on. In the initial state, the number of previously unconfigured actuators equals the total number of actuators. After switching on, a confirmation of the switch-on state by the user at the mobile terminal or by a mobile detection device is awaited. For this purpose, a certain waiting time, for example 5 seconds, can be provided. Alternatively, it is possible to wait for information that the selected actuator is not turned on. The activated actuators are then switched off.

Unless during the wait, d. H. During the waiting time, an acknowledgment of the switch-on state has taken place, this means that the actuator to be determined belongs to that of the half of the actuators that was switched on when first switched on. There is thus a switching on of the half of the last switched on actuators, so that the number of possible actuators, which may include the actuator sought, can be reduced to a quarter of the total number of actuators. Accordingly, half of the actuators that were not switched on during the last switch-on are switched on, provided that no confirmation of the switch-on state has taken place during the wait or the information has been transmitted that the selected actuator is not switched on.

The said method steps are repeated until only one actuator is switched on, whose switch-on state is then confirmed by the user on the mobile terminal or by the mobile detection device. Thus, by the proposed method, it becomes possible to find out the position where an actuator is wired although a very large number of actuators may exist. The proposed method is of particular interest when, for example, a commercial or industrial building is equipped with a multiplicity of actuators and thus a quick selection or screening is necessary.

Alternatively, it is possible to first turn on those actuators that are more likely to have been selected by the user. This can be done, for example, by using information about a pre-configuration of the system. Furthermore, the information can be used that certain device classes are preferably installed on certain types of actuators. This can be achieved that not unnecessarily many actuators have to be tried by the system until the right actuator has been located.

In a preferred embodiment, the relevant part of the configuration logic is stored in each actuator and sensor.

In order to check that the actuator selected by the user has been wired correctly, it is possible to activate all actuators in a previous step. If the user or the mobile detection device confirms the switched-on state of the selected actuator, correct wiring can be assumed. If there is no or negative acknowledgment, there is a defect or fault in the wiring.

A building automation system suitable for carrying out the method described will be described below. The system comprises a large number of sensors and actuators, as well as a controller, which is connected to the sensors and actuators in terms of data technology. This connection can be made for example via a bus system. The system further comprises a mobile detection device having a sensor for detecting the on-state of an actuator and a transmitting device for transmitting an acknowledgment of the detected on-state to the controller of the system.

The transmitting device is preferably designed as a Bluetooth or WLAN transmitting device. Furthermore, the transmitting device can use a wireless M-bus, an enocean radio bus, Zigbee and ZWave.

In the following, a preferred embodiment of the invention will be explained with reference to a figure.

The figure shows the schematic structure of an embodiment of the building automation system according to the invention.

The system 11 includes a variety of sensors 10 and actuators 12 via a wireless or wired bus system 14 with each other and with the controller 16 of the system 11 are connected.

The control 16 has a WLAN transmitting and receiving device 18 on, over which the controller 16 with the mobile device 20 For example, a smartphone can communicate. Furthermore, the controller has 16 a Bluetooth transceiver 24 on, over which the controller 16 with the mobile detection device 22 can communicate. It also has a Bluetooth transceiver 26 ,

When configuring the actuators, the user selects the screen icon for a particular actuator 12c on the smartphone 20 at. The information about which actor 12c dialed by the user is from the smartphone 20 to the building automation system 11 ie to the controller 16 , transmitted. There is now an automatic sequential switching on and off of various non-configured actuators 12 , For example, first the actuators 12a and 12b be turned on. If there is no confirmation of your switch-on state, the actor can in the next step 12c be turned on, because then it is known that the actuator sought only the actuator 12c or 12d can be. If an acknowledgment of the switch-on state of the actuator 12c this was successfully located. If this is not the case, the actor sought is the actor 12d , If an acknowledgment of the switch-on state of the first selected half of the actuators 12a and 12b takes place, one of these two actuators is turned on in the next step, for example, the actuator 12a , so that here also a clear localization of the sought actuator can be made.

Since in the example mentioned the actuator 12c was selected, this would be actuated by the user.

Confirming the switch-on state of the selected actuator 12c can by the user on the smartphone 20 or by the illustrated mobile detection device 22 respectively. This includes a sensor, not shown, for detecting the on state of the actuator 12c ,

A confirmation of the switch-on state of the selected actuator 12c is from the mobile device 20 or the mobile detection device 20 to the building automation system 11 or the controller 16 transmitted. This can be done via the illustrated WLAN or Bluetooth connection.

Configuring the sensors 10 includes the following steps:
First, a specific actor 12c selected by the user. This is also done within an application running on the mobile device 20 is installed. Subsequently, a transmission of information about the selected actuator 12c from the mobile device 20 to the controller 16 , The sensor 10c who is the selected actor 12c is now manually activated by the user. Is it the sensor 10c For example, a light switch, it can be operated by the user. The control 16 can thus the manually activated sensor 10c the corresponding actuator 12c assign logically.

Claims (7)

Method for configuring a building automation system ( 11 ), in which a plurality of sensors ( 10 ) and actuators ( 12 ), the method comprising the steps of: configuring the actuators ( 12 ) by performing the following steps: - selecting a specific actuator ( 12c ) on a mobile terminal ( 20 ) - transmission of information about the selected actuator ( 12c ) from the mobile terminal ( 20 ) to the building automation system ( 11 ) - automatic sequential switching on and off of various non-configured actuators ( 12 ) - Confirming the switch-on state of the selected actuator ( 12c ) on the mobile terminal ( 20 ) or by a mobile detection device ( 22 ), as soon as it has been switched on automatically - transmission of the confirmation of the power state from the mobile terminal ( 20 ) or the mobile detection device ( 22 ) to the building automation system - storing the physical address at which the relevant actuator ( 12c Wired is configuring the sensors ( 10 ) by performing the following steps: - Selecting an actuator ( 12c ) on the mobile terminal ( 20 ) - transmission of information about the selected actuator ( 12c ) from the mobile terminal ( 20 ) to the building automation system ( 11 ) - manual activation of the sensor ( 10c ) connected to the selected actuator ( 12c ) by the user - logically assigning the manually activated sensor ( 10c ) to the selected actuator ( 12c ), characterized by the step: - automatic detection of the switch-on state of the selected actuator ( 12c ) by a sensor of the mobile detection device ( 22 ), wherein the mobile detection device ( 22 ) in terms of data technology with the building automation system ( 11 ) and the building automation system ( 11 ) by the mobile detection device ( 22 ) the confirmation of the switch-on state of the selected actuator ( 12c ) is transmitted as soon as it is turned on. A method according to claim 1, characterized in that an actuator profile with a plurality of different actuator states is programmed by the following steps: - manually activating and / or setting multiple actuators ( 12 ) by the user - storing the entirety of the user-selected or activated and / or set different actuator states after a corresponding command given by the user to the mobile terminal ( 20 ) - associate the stored actuator states with an actuator profile that is subsequently retrievable by the user. A method according to claim 1, characterized in that upon retrieval of a stored Aktorprofils the entirety of the stored Aktorzustände is automatically established by the building automation system. Method according to one of claims 1 to 3, characterized in that the automatic sequential switching on and off of various non-configured actuators ( 12a . 12b . 12c . 12d ) comprises the following method steps: (a) switching on the half ( 12a . 12b ) of the previously unconfigured actuators ( 12a . 12b . 12c . 12d ) (b) Waiting for confirmation of the power-on state by the user at the mobile terminal ( 20 ) or by a mobile detection device ( 22 ) or waiting for information that the selected actuator ( 12c ) is not switched on (c) switching off the activated actuators ( 12a . 12b ) (d) switching on the half ( 12a ) of the actuators switched on at the last switch-on ( 12a . 12b ), if during the waiting an acknowledgment of the switch-on state has taken place or (e) switching on the half ( 12c ) of the actuators not switched on at the last switch-on ( 12c . 12d ), if there was no confirmation of the switch-on state during the wait or the information was transmitted that the selected actuator ( 12c ) is not switched on (f) repeating the method steps (b) to (e), until, according to method step (d) or (e), only one actuator ( 12c ), whose power-on state is then switched on by the user at the mobile terminal ( 20 ) or by the mobile detection device ( 22 ) is confirmed. Method according to one of claims 1 to 3, characterized in that those actuators ( 12 ) are turned on first, which are more likely to have been selected by the user. Method according to one of claims 1 to 5, characterized in that in each actuator ( 12 ) and sensor ( 10 ) the relevant part of the configuration logic is stored. Method according to one of claims 1 to 6 with the preceding step: - activating all actuators ( 12 ) of the building automation system - waiting for a confirmation by the user or the mobile detection device ( 22 ) via the switch-on state of an actuator selected by the user ( 12c ).

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