WO2009027023A1 - System and method for controlling a plurality of switching devices - Google Patents

Abstract

The invention relates to a system and a method for controlling a plurality of switching devices located in system components to be actuated, which are connected to each other via a central unit and a communication network, wherein the system components each have at least one radio receiver module for exchanging commands and/or data via the communication network. The radio receiver module is equipped with a radio terminal unit comprising a transmitter and a receiver, carrying out the communication with the central unit via the communication network. The radio terminal unit interacts with at least one switching device that switches the system components directly or indirectly via a microprocessor connected to the radio terminal unit.

Description

 System and method for controlling multiple switching devices

description

The invention relates to a system and a method for controlling a plurality of switching devices to be controlled in system components, which are interconnected via a communication network according to claims 1 and 23 and is provided in particular control of electronic utility meters and communication devices for their remote reading.

For controlling a plurality of electrical consumers via the power supply network, also referred to as mass control, the audio frequency ripple control technique is usually used, which is based on the fact that control commands and data requests are transmitted via the power grid to the consumer. For this type of remote transmission audio frequency - ripple control systems and corresponding audio frequency ripple control receiver are used.

Another method of driving consumers uses longwave or FM transmitters and corresponding radio receivers communicating with each other over a radio network. Both methods described above are also used to control individual electrical consumers.

The consumers to be controlled are, for example, lighting devices, such as street lamps, special lighting of buildings, etc., electrical and non-electrical loads, such as boilers, electric water heaters, night storage heaters, direct heaters, etc, power generation systems, such as emergency generators, wind turbines, combined heat and power plants, etc.

The information transmission in the audio frequency ripple control technology is carried out by means of the existing power supply network, while the information transmission for the radio technology uses air as the transmission medium. Both techniques used to transmit the information from the consumer to a center and vice versa special transmission protocols, which are specified in predetermined standards and guidelines, such as in DIN 43861 301/302.

Also for tariff switching in electricity meters, the previously described ripple control technology and radio technology are used today.

The invention has for its object to provide a system and a method for controlling a plurality of to be controlled system components switching devices which are interconnected via a communication network, thereby improving the control of system components to be controlled, in particular of electronic utility meters and communication devices for their remote reading becomes.

This object is achieved by a system having the features specified in claim 1. Advantageous embodiments, improvements of the system according to the invention and a corresponding method are specified in further claims and in the description.

According to the invention, the system comprises for controlling a plurality of electrical or electronic switching devices to be controlled in system components, which via a central unit and a communication network with each other At least one radio receiver module located in the respective system component is connected for exchanging control commands and / or data via the communication network.

The system components according to the invention are in particular lighting devices, such as street lamps or special lighting of buildings; electrical or non-electrical loads, such as boilers, electric water heaters, night storage heaters, direct heaters; Energy generation systems, such as emergency generators, wind turbines, combined heat and power or Tarifumschaltvorrichtungen in consumption meters, such as electricity, gas, water or heat meters.

The radio receiver module is equipped with a radio terminal unit having a transmitter and a receiver which performs communication with the central unit via the communication network and cooperates with at least one switching device which switches the system components directly or indirectly via a microprocessor connected to the radio terminal unit ,

The microprocessor simulates the functionality of a known ripple control receiver.

The communication network, which connects the central unit and the system components to be controlled to the switching devices provided, is a telecommunications network, in particular a GSM, GPRS, UMTS, WIMAX, wireless LAN network or a short-distance radio network based on 868 MHz or 433 MHz is working.

In a particular embodiment of the system according to the invention, the near-field radio network is provided for meter reading data remote reading or smart metering.

The switching devices of the system according to the invention are potential-free relays, or non-floating control outputs designed as semiconductors. In an advantageous embodiment, the radio terminal unit has a communication module designed as an interface, which interacts with the radio receiver module and can be connected to communication-capable gas, water, electricity and / or heat meters.

The communication module works as a gateway for smart metering or as a data concentrator and can be connected to the meter via a wireless or wired metering bus (M-Bus), whereby the M-Bus is intended as a fieldbus for the consumption data acquisition.

By means of the functionality described above, it is furthermore possible to connect the communication module to the radio receiver module in such a way that information can be transmitted via near-field radio, for example via energy references, tariffs, load optimization measures and recommendations.

The addressing of the radio receiver module can be executed via the communication network, commands in the receiver of the radio receiver module with a specific coding can be stored, via which the switching of the outputs of the switching device takes place as soon as the corresponding commands are received by the radio receiver module. For this purpose, broadcast commands are sent via the communication network, so that advantageously a large number of radio receiver modules can be reached with one command.

Furthermore, it is also provided that fixed IP addresses are stored in the radio receiver module via which the radio receiver module, preferably by means of a bidirectional data transmission, can be addressed.

The outputs of the switching devices, which are initiated via the central unit, are directly switchable, wherein the radio receiver module, in particular with regard to the deposit of switching commands, can be remotely parameterized.

The switching commands can either be addressed directly via the control center or can be executed by the stored switching commands in conjunction with a timer. A further feature of the system according to the invention is the possibility of tele-assignability of the time and the synchronization of the time in the respective radio receiver modules, which require them for independent processing of stored switching operations. The switching operations can also be parameterized remotely so that the radio receiver modules can be switched independently via an integrated clock. The time is derived from the Internet or the wireless network.

In one embodiment of the system according to the invention, the radio receiver module is equipped with a weekly, monthly or annual time switch, via which also prepared switching commands can be triggered.

The mechanical design of the radio receiver module is designed so that the module is designed, for example, for snapping onto a D! N rail and in the housing according to DIN 43861 Part 2. Alternatively, housing variants for installation in light poles are possible.

The antenna of the receiver is either housed as an integrated antenna in the housing radio receiver module or alternatively executed via an antenna connection as an external antenna.

The method by which the problem is still solved, can be found in claim 23. In this case, a plurality of electrical or electronic switching devices located in the system components to be controlled, which are interconnected via a central unit, are controlled via a communication network.

Control commands and / or data are exchanged via the communication network by means of at least one radio receiver module integrated in the respective system component.

Communication with the central unit via the communication network is carried out by means of a radio terminal unit located in the radio receiver module, and the respective switching device is switched directly or indirectly by means of a microprocessor integrated in the radio terminal unit. Based on an exemplary radio receiver module shown in the following FIG. 1, the invention and advantageous embodiments, improvements and further advantages of the invention will be explained and described in more detail.

1 shows a radio receiver module 1 of the system according to the invention for controlling a plurality of electrical or electronic switching devices in the system components to be controlled, which are connected to one another via a central unit and a communications network.

The radio receiver module 1 located in the system components is provided for exchanging control commands and / or data via the communication network. For this purpose, the radio receiver module 1 has a radio terminal unit 10 having a transmitter and a receiver, which carries out the communication with the central unit via the communication network.

For connection of the radio receiver module 1 to the power grid, a power supply unit 50 is further provided.

The radio terminal unit 10 cooperates with several, preferably eight switching devices 30, which switches the respective system component directly or indirectly via a microprocessor 20 connected to the radio terminal unit 10.

The microprocessor 20 provides the actual functionality that is comparable to the functionality of known ripple control receivers.

The radio receiver module 1 is equipped so that over load-free contacts (relays) 30 loads and objects can be switched directly or indirectly. The number and design of the relays 30 varies in the present embodiment vary between 1 and 8. Depending on the relay version, the switching currents range from 2A to 63A. In addition to potential-free relay 30 and non-floating control outputs (semiconductors) can be used.

A variant represents the possibility to control via the radio receiver module 1, a current from 0 - 100mA or a voltage 0 - 20V at one or more outputs for the analog control of controllable, for example, dimmable consumers.

According to the embodiment according to FIG. 1, the radio receiver module 1 is equipped with an interface 40 to which communication-capable gas, water, electricity and / or heat meters can be connected.

LIST OF REFERENCE NUMBERS

Radio receiver module

Radio terminal unit

microprocessor

switching device

communication module

power supply

Claims

claims

1. A system for controlling a plurality of system components to be controlled switching devices, which are connected to each other via a central unit and a communication network, wherein

the system components each have at least one radio receiver module for exchanging commands and / or data via the communication network,

- The radio receiver module is equipped with a transmitter and a receiver having a radio terminal unit which performs the communication with the central unit via the communication network, and

- The radio terminal unit cooperates with at least one switching device which switches the system components directly or indirectly via a microprocessor connected to the radio terminal unit.

2. System according to claim 1, characterized in that the communication network is a telecommunications network, in particular a GSM, GPRS, UMTS, Wi-MAX, wireless LAN - network.

A system according to claim 1, characterized in that the communication network is a near-field radio network operating on the basis of 868 MHz or 433 MHz.

4. System according to claim 3, characterized in that the Nahfunk network is provided for Verbrauchszählerdatenfemauslesung or smart metering.

5. System according to any one of the preceding claims, characterized in that the microprocessor simulates the function of a known ripple control receiver.

6. System according to any one of the preceding claims, characterized in that the switching devices are designed as potential-free relays or semiconductor designed non-isolated control outputs.

7. System according to one of the preceding claims, characterized in that the radio terminal unit has a communication module which cooperates with the radio receiver module.

8. System according to claim 7, characterized in that on the communication onεmodu! communicable gas, water, electricity and / or heat meters can be connected.

9. System according to claim 7 or 8, characterized in that the communication module operates as a gateway for smart metering.

10. System according to claim 7 or 8, characterized in that the communication module operates as a data concentrator.

11. System according to claim 8 to 10, characterized in that the communication module via a wireless or wired M-bus is connected to the counter.

12. System according to any one of the preceding claims, characterized in that the addressing of the radio receiver module via the communication network is executable.

13. System according to claim 12, characterized in that in the receiver of the radio receiver module commands with a specific coding can be stored, via which the switching of the outputs of the switching device takes place as soon as the corresponding commands are received by the receiver.

14. System according to claim 13, characterized in that over the communication network for this broadcast commands are sent and / or that fixed IP addresses are stored in the receiver, via which the receiver is addressable.

15. System according to any one of the preceding claims, characterized in that the outputs of the switching devices, which are initiated via the central unit, are directly switchable.

16. System according to any one of the preceding claims, characterized in that the radio receiver module is remotely parameterized.

17. System according to one of the preceding claims, characterized in that the radio receiver mode! has a timer, which can be set by means of a Fempa- rametrierbefehl.

18. System according to one of claims 1 to 16, characterized in that the radio receiver module has a timer, which derives the time from the Internet or the wireless network.

19. System according to any one of the preceding claims, characterized in that the radio-receiver module is equipped with a weekly, monthly or annual timer, via the prepared switching commands can be triggered.

20. System according to any one of the preceding claims, characterized in that it is provided for snapping onto a DIN rail or for mounting in a structural housing according to DIN 43861 Part 2.

21. System according to one of claims 1 to 19, characterized in that the radio-receiver module is provided for installation in light poles.

22. System according to any one of the preceding claims, characterized in that the system components lighting devices, such as street lamps or special lighting of buildings, electrical or non-residential electrical loads, such as boilers, electric water heaters, night storage heaters, direct heaters. Energy generation systems, such as emergency generators, wind turbines, combined heat and power plants, or Tarifumschaltvorrichtungen in utility meters, such as electricity, gas, water or heat meters are.

23. A method for controlling a plurality of switching devices to be controlled in system components, which are connected to each other via a central unit and a communication network, wherein

commands and / or data are exchanged via the communication network by means of at least one radio receiver module integrated in the respective system component,

the communication with the central unit is carried out via the communication network by means of a radio terminal unit located in the radio receiver module, and

- The respective switching device switches directly or indirectly by means of an integrated microprocessor in the radio terminal unit.