WO2007082602A1

WO2007082602A1 - Communication system for supplying data to electronic devices in the electronic installation industry

Info

Publication number: WO2007082602A1
Application number: PCT/EP2006/069432
Authority: WO
Inventors: Norbert Brehm; Nikolaus Dellantoni; Michael Ernst; Peter Veith
Original assignee: Siemens Aktiengesellschaft
Priority date: 2006-01-12
Filing date: 2006-12-07
Publication date: 2007-07-26
Also published as: EP1972071A1; DE102006001651A1

Abstract

The aim of the invention is to produce a communication system (1) for supplying data to electric devices (2.1 to 2.n) in the electronic installation industry, which allows the devices (2.1 to 2.n), which are part of the system, to be coordinated due to simple topology and low installation costs. As a result, data is transferred by means of quasi-stationary electric fields (N and/or S) having a high frequency alternating current (I) on the electrically conductive elements (6.1 to 6.n) in the direction of a capacitive near field communicator and according to signal technology, in order to align the devices (2.1 to 2.n) which are to be coupled.

Description

description

Communication system for data supply of electrical devices of electrical installation technology

The invention relates to a communication system for data supply of electrical equipment of electrical installation technology, which also has a functional element in addition to the devices.

From WO 2004/036784 Al an asymmetrical message transmission system using an electric near field is known, which is provided with a transmitter having at least one coupling element, on the ^{essen ¬} chen an electric near field is spread. In this case, the message transmission system comprises an infrastructure body which is present anyway and which has an electrically insulated, electrically grounded conductor element into which the electric field is coupled. By means of a receiver which has at least one coupling element, the field transmitted in the conductor element is coupled out.

From DE 199 30 153 Al a device for increasing the reception of a DCF-77 signal is known, in which a feed of the DCF-77 signal into an electrical energy network takes place, wherein at the place of need the electrical energy ^¬ net a filter is connected downstream to filter out the DCF-77 signal and the signal is provided to a unit which requires the DCF-77 signal.

The invention is based on the object to provide for data onssystem electric supply devices of the electric installation technique, a Kommunikati ^¬, the light enable a coordination of participating in the system devices in a simple topology and low installation costs. This object is achieved by the features of Pa ^¬ tentanspruchs 1; advantageous embodiments are ever ^¬ object of further claims.

By the data transmission between at least one central functional element and a plurality of decentralized devices, in particular household consumers, by means of electric fields with a high-frequency alternating current, which impressed on existing in the installation arrangement electrically conductive, possibly from each other galvanically isolated infrastructure elements by Sen ^¬ means of the functional element or . Emp by ^¬ catch means of the devices of the infrastructure elements abge ^¬ be accessed, a common function devices, for example in the sense of a synchronization device sawn acts are. Only by including the infrastructure elements in the communication system is the implementation of such a matching functionality, in particular a central time signal, economically viable.

Accordingly, it can on a complex wired Kommunikati ^¬ onsnetzwerk one hand and susceptible to a complex and therefore sturgeon ^¬ radio network on the other hand are omitted. According to the ^¬ contrary to the conventional communication systems, such as in the European Installation Bus, the Local Operating Network or Powerline, no Steuerlei ^¬ lines or no power lines needed for signal transmission; Rather, it can be pro ^¬ fi ed by a communication system with a simple structure and low installation costs. The communication system is also ideal for retrofitting.

In such a near-field communication, the data transmission system has a transmitter, with the coupling element essentially an electric near field is emitted. This field is coupled tiv in an electrically conductive element capaci ^¬ in which then a current, in particular an impulse-shaped displacement current due to a load change occurs at the electrically conductive element. The e- lectric conductive member is electrically capacitively coupled to the Erdpotenti ^¬ al and optionally with further electrically conductive elements. By suitable capacitive input and Auskopp ^¬ development of a signal is det gebil ^¬ by means of such an element and possibly by means of further elements over between the same and existing ground potential coupling capacitances and resistances including the communication-capable devices or at least one functional element of a circuit.

At an arbitrary point of one of the electrically conductive infrastructure elements, a potential difference between the electrically conductive element and ground can now be measured with suitable receiving means and thus a signal can be received. The signal, in particular control signal comprises general ^¬ mean a data message and is used to make ^¬ bereitzu the system devices accurate and mutually synchronous time basis.

It is essential that signal frequency, electrically conductive elements and transmitter / receiver are coordinated so that actually a near field communication takes place, with no radio link with predominant radiation of the signal is present over the interior of a building, but in fact a predominantly capacitive coupling to electrically conductive elements takes place, however, must be given in such a way that at a designated receiving point a signal can be ^¬ nal received with sufficient signal level.

With the system according to the invention, the losses of a radiating system are sometimes avoided, and thus achieved a very low power consumption in the transmitter and receiver. There are no wide-spreading unwanted stray fields produced during transmission, since the capacitive coupling from the transmitter into the electrically conductive element by an electric near field with only a short range vonstatten. The main losses arise as a result the Kopplungskapa ^¬ capacities and feedback resistors between the different conductive elements and the self-inductances of these elements.

A signal transmission in the quasi-stationary electric field requires no clock generation on the receiver side, because the system clock is uniformly fed into the transmission medium, in particular in the electrically conductive elements. Basically, however, the usual methods of wireless technology, such as carrier preparation, modulation, Multiplexverfah- can reindeer, reception and demodulation fully applied ^¬ to.

In an advantageous embodiment, the synchronization for the synchronization of the building devices using a periodically transmitted radio clock signal, in particular a DCF-77 signal, wherein the detection of the signal by means of a building-related central time signal generator, in particular by means of a DCF-77 receiver, takes place as a functional ^¬ element. Here, the devices can be provided a uniform, common and reliable time base, with the help of valuable additional functions in the devices can be realized. For this example, counts the auto ^¬ matic switch from winter to summer time and vice versa. A complex equipment of each device with a separate signal generator can therefore be avoided, especially since separately provided signal generator are not necessarily synchronous to ^¬ each other.

Advantageously, the radio controlled clock signal is coupled into the at least one electrically conductive infrastructure element capacitively and ko ^¬ coupled diert and from capacitive and decoded, whereby the signals are in analog form ^¬ reacted in suitable for the transmission of bit patterns and back to analog bit signals become. Here, a adaptation to existing channel conditions and possibly an error ^¬ be made on channel level detection. Advantageously, one or more system devices are each ^¬ weils provided with a control device, in particular in the form of a mountable to the device adapter, to the implementation and processing of the DCF-77-signal so that a signal originally not in favor equipped installation Bus systems can be coupled and thus the overall functionality of the system is significantly expandable.

The advantageous use of the frequency band between 5 MHz and 50 MHz for the high-frequency alternating current means that used in the devices electronic transmitter and / or receiver circuits can be performed in low-power CMOS technology, and the coupling elements whose dimensions are low compared to the Wavelength of the alternating current should have the maximum size of conventional Rei ^¬ heneinbaugeräte. Particularly favorable is the use of a frequency of 13.56 MHz and / or 40.68 MHz for the high-frequency alternating current. These frequencies are in a so-called ISM band, ie a freed-up for industry, science and medical applications frequency range with a general authorization, which is not subject to government regulation and may be used license-free. It must only be complied with conditions regarding the transmission power and the interference of adjacent frequency ranges. Overall rate, which operate in this frequency band, can be immediately removed from Benut ^¬ zer into operation without having to be sought before initial startup to a separate approval.

As an infrastructure body all bodies can be used which have electrically conductive elements, including ^¬ example, heating pipes or electrically conductive films count, so that can be dispensed with specifically for the communication network instal ^¬ lating lines. In cases de- existing infrastructure nen for signal routing is insufficient, can in the simplest way gen with a clotting ^¬ expenses including via roller, spray or brush elekt ^¬ driven conductive layers on walls, systems, components and The same can be applied to improve the conductivity of the system.

The invention and advantageous embodiments according to the features of the other claims are explained in more detail below with reference to embodiments shown in the drawings, without limiting the invention so far; show in it:

1 shows a communication system for data supply of electrical devices of electrical installation technology according to claim 1 in a schematic representation; and FIG 2 is an electrical equivalent circuit diagram of erfindungsge ^¬ MAESSEN communication system.

1 shows a communication system 1 for supplying data to electrical devices, in particular control devices 2.1 to 2.n, by means of a functional ^element 3, designed as a time signal generator, of the electrical installation technology, which are arranged within a building 4. The time signal generator 3 in turn represents a DCF-77 receiving unit. The DCF-77 technology radio clocks are supplied via a radio signal with the central European clock. As communication ^¬ means for forwarding the received data a Sig- serves nalgenerator 5, which is arranged in or on the functional element 3 e lectric and / or mechanically and is used dung change, for example in the form of a frequency or pulse generator for La ^¬. Accordingly, the functional element 3 has a transmitter and a coupling element with which essentially a quasi-stationary near field N according to FIG. 2 can be ^generated or transmitted. Under a quasistatio ^¬ ary near field a field N is understood, which is produced in the interaction between a signal source and a spaced apart to the coupling element and has a predominantly electric near-field.

This field is einge- asymmetrically on an existing in the building 4 elekt ^¬ driven conductive Infrastukturelement 6.1 coupled. In addition to the one infrastructure element 6.1, in the building 4 there are further electrically conductive elements, in particular metal reinforcements 6.2 to 6.n, for walls and floors, which are mainly capacitively coupled to one another and to ground potential E. The asymmetrical coupling ei ^¬ nes high-frequency alternating current I in the Infrastukturelement 6.1 is now on the further conductive elements 6.2 to 6.n and between the same and the ground potential E existing coupling capacitances and resistances K - as anschaulicht comparable in FIG 2 - a circuit educated. In this context ^¬ hang asymmetric coupling means that the Koppelkapa ^¬ capacity may arise between each coupling surface and the electrically conductive element or medium, or are different between each coupling surface and the ground E, and thus a potential difference.

The asymmetrical coupling of the high-frequency alternating current I results in a quasi-stationary stray field S according to FIG. 2, which is emitted by the electrically conductive elements 6.1 to 6.n. A quasi-stationary stray field S is understood as meaning a field which is generated in interaction between the undefined electrically conductive elements 6.1 to 6.n and a signal detector 7 which is spaced therefrom and has a predominantly electric near-field component. At any point one of the elements 6.1 to 6.n can subsequently with suitable receiving elements 7.1 to 7.n, in particular by means of a high-resistance Signalde ^¬ tektors or also by means of an integrated in the respective functional unit ^¬ radio receiver, measured a potential difference and thus the signal will be received. Possibly. existing actuators, which may be part of the respective receiver 7.1 to 7.n or connected to them as modules, take over in the sequence, for example, a device setting. The devices 2.1 to 2.n thus receive a central radio clock system within the building 4 via the data supply system 1 and are supplied with operating current via a line 8. In the present exemplary embodiment, the time signal is thus coded and capacitively coupled into the conductive infrastructure of the building 4 by means of the near field communication. Thus, the central time signal in the form of a coded quasi-stationary field is available anywhere in and around the building infrastructure - up to a distance of a few centimeters - and can be capacitively decoupled and decoded by the connected receivers. In this case, all devices connected to the system, in particular control devices, can use an exact and synchronous time base.

It is essential in the communication system 1, the frequency of the high-frequency alternating current I, which must be chosen so that the transmission characteristics of the elements 6.1 to 6.n reach an optimum. The transmission characteristics of the existing elements can be improved by the assembly of additional conductive elements, such as an electrically conductive foil. This film is advantageously mounted in electrical installation installations in the form of a circulating belt at the level of the usually installed power distribution, so that good coupling properties are ensured. Instead of the film and a metalli ^¬ cal grid is conceivable, which is incorporated into the plaster before application. A particularly simple application of the electrically conductive infrastructure element 6.1 to 6.n is given when electrically conductive coatings are used, which can be applied for example by roller, spray or brush on the wall. Thus, the possibility is given ^¬ even electrically problematic conditions in a simple way to improve significantly.

In FIG 2 is an equivalent circuit diagram of the communica ^¬ tion system is shown with means for near field 5 and 7 1 by way of example. The electric near-field communication that is used here is based on a circuit having a displacement current I, which is connected to electrically conductive media or elements 6 and the ground potential by capacitive coupling K1 to Kn of the signal generator 5 and of the signal receiver 7. tial E is closed. In the area of the transmitter 5, a near field N and in the region of the receiver 7 a stray field S are formed. The coupling resistors Kn are unavoidable within the system 1, but are known and can thus be considered in the system design. The smaller the coupling resistors Kn are, the more reliable the post ^¬ is directed transmission.

In the present embodiments, frequencies of 13.56 MHz and 40.68 MHz, respectively, are selected for the high-frequency alternating current I. These frequencies are in a Fre ^¬ quenzband released for industry, science and medical applications, a so-called ISM band.

The invention explained above can be summarized as follows:

In order to provide a communication system 1 for data supply of electrical devices 2.1 to 2.n of the electrical installation technology, which allows for a simple topology and low installation costs coordination of participating in the system devices is provided by means of qua ^¬ sistationärer electric fields N and S with a high-frequency alternating current I to existing in the installation arrangement electrically conductive elements 6.1 to 6.n in terms of a capacitive Nahfeldkommunikation signal technology for

Matching of devices 2.1 to 2.n, i. to coordinate with each other, to couple.

Claims

claims

1. communication system (1) for data supply of electrical equipment (2.1 ... 2.n) of electrical installation technology, in addition to the devices (2.1 ... 2.n) and at least one functional element (3), each with resources for Because ^¬ are provided tenübertragung, of which an average is provided at least one functional element (3) for receiving despatched outside of the system data and of which a further means (5) of at least one functi ^¬ onselements (3) of the received for sending data on at least one electrically conductive infrastructure element is such asymmetrically coupled (6.1 ... 6.n) that ^¬ sem a quasi-stationary near-field (N) is imprinted with a high-frequency alternating current (I), wherein a resulting quasi-stationary scatter field ( S) with ei ^¬ nem high-frequency alternating current (I) to the at least one electrically conductive infrastructure element (6.1 ... 6.n) is ready, and wherein the means (7.1 ... 7.n) of the devices (2.1 ... 2 .n) z to receive the data asymmetrically such an electrically conductive infrastructure elements are coupled (6.1 ... 6.n) on which at least that the scatter field (S) for adjustment of the devices (2.1 ... 2.n) abgegrif ^¬ fen of this is ,

2. Communication system (1) according to claim 1, wherein the electrical field is capacitively coupled into the electrically conductive Inf ^¬ rastrukturelement (6.1 ... 6.n) and is coupled capacitively from this.

3. Communication system (1) according to claim 1, wherein the electric field is capacitively coupled into the electrically conductive Inf ^¬ rastrukturelement (6.1 ... 6.n) and is decoupled from this galvanic.

4. Communication system (1) according to claim 1, wherein the e- lectric field galvanically in the electrically conductive Infrastructure element (6.1 ... 6.n) coupled and is decoupled from the ^¬ sem capacitively.

5. Communication system (1) according to claim 1, in which the equalization, in particular by means of a periodic Ab ^¬ states transmitted radio clock signal, for Synchronisie ^¬ tion of the devices (2.1 ... 2.n) is used.

6. Communication system (1) according to claim 1 and 5, wherein the detection of the radio clock signal, in particular a

DCF-77 signal, by means of a building-related zentra ^¬ len time signal generator (3), in particular DCF-77 receiver, as a functional element.

7. A communication system (1) according to claim 1,5 or 6, wherein the radio controlled clock signal, at least one electrically conductive infrastructure element (6.1 ... 6.n) encodes and decodes eingekop ^¬ pelt of this is coupled into the.

8. Communication system (1) according to claim 1, wherein the devices (2.1 ... 2.n) are designed as household appliances.

9. Communication system (1) according to claim 1, wherein the devices (2.1 ... 2.n) are designed as control devices for the implementation and processing of the DCF-77 signal.

10. Communication system (1) according to claim 1, wherein each device provided with a control device (2.1 ... 2.n), in particular in the form of an attachable to the device adapter, for implementation and processing of the DCF-77 signal is.

11. Communication system (1) according to claim 1, wherein the at least one electrically conductive infrastructure element (6.1 ... 6.n) is designed as a water pipe, heating pipe, metal bracing or metal foil.

12. Communication system (1) according to claim 1 or 11, wherein the electrically conductive infrastructure elements (6.1 ... 6.n) be carried out by means of roller, spray, brush or the like on ^¬ brought electrically conductive layers.

13. Communication system (1) according to claim 1,11 or 12, wherein the electrically conductive infrastructure elements (6.1 ... 6.n) are laid in or under plaster.

14. Communication system (1) according to claim 1, wherein the means for data transmission (5; 7) are designed as transmitter and / or receiver.

15. Communication system (1) according to one of the preceding claims, in which the frequency of the high-frequency alternating current (I) is in the range of 5 to 50 MHz, in particular 13.56 and / or 40.68 MHz.

16.Use of the communication system (1) according to claim 1 in a building (4).