DE102013109685A1 - RFID antenna for tubular drive - Google Patents

Abstract

It is a tubular drive (1) for controlling a darkening or closing device, such as a roller shutter, a blind, an awning, a garage door or the like, with a connection cable (12) for its electrical supply, wherein the connecting cable (12) at least one Wire (13), described, wherein a transponder chip (10) in the tubular drive (1) arranged to store its data and parameters and wirelessly readable via at least one wire acting as an antenna (11) of the connecting cable (12).

Description

The invention relates to a tubular drive for controlling a darkening or closing device, such as a roller shutter, a blind, an awning, a garage door or the like, with a connecting cable to its electrical supply, wherein the connecting cable has at least one core.

Such a tubular drive is for example from the DE 202 13 126 U1 known. With the aid of a radio transmitter, a high-frequency signal for controlling the tubular drive of a roller shutter, a blind or awning is emitted. The signal is received by a built-in tubular drive radio receiver via acting as an antenna core of led out of the roller shutter shaft electrical connection cable of the tubular drive.

From the DE 20 2005 019 992 U1 Furthermore, a control system for a blackout or security system is known. In this case, for example, the end positions of several control systems of the drive motors can be programmed separately with a programming device. For communication of the programming device with the corresponding drive motor control, a communication address is necessary. This address is stored in an RFID chip which is mounted outside of the drive motor and the roller shutter shaft, preferably in the vicinity of the shutter shutter box opening flap, and has a separate antenna.

A disadvantage of the known tubular drives, that in the case of subsequent parameterization, repair or replacement of the drive this often from the roller shutter shaft and the shutter box or shaft must be removed to the mounted on the drive nameplate and thus necessary data and Parameters of the drive, such as article and serial number, drive type and train performance, read and order the appropriate replacement drive or perform the parameterization correctly.

The object underlying the present invention is therefore that data and / or parameters of the tubular motor in the installed state of the tubular drive are accessible.

To solve this problem, a tubular drive according to the invention with the features of claim 1 is proposed. Advantageous embodiments of the invention are the subject of dependent claims.

Characterized in that a transponder chip in the tubular drive for storing its data and parameters arranged and wirelessly readable via at least one acting as an antenna wire of the connecting cable, the tubular drive in the case of parameterization, repair or replacement does not have the example roller shutter shaft or the like get extended.

A transponder essentially consists of an antenna and a so-called transponder chip. The transponder chip in turn consists of an analogue circuit for receiving and transmitting as well as a digital circuit in the form of a microcontroller and a permanent memory. This permanent memory is writable at least once. If rewritable memories are used, further data or parameters, such as operating or motor data, can be stored during the lifetime.

The tubular drive is in the case of a motor-driven shutter typically in a roller shutter shaft, which is installed in a roller shutter box or in a roller shutter shaft and is usually then, for example, wallpapered. The tubular drive is then no longer accessible without opening the roller shutter box or shaft. However, in order subsequently to be able to make adjustments to the tubular drive, for example the correction of the end positions, the operator or user and / or the service specialist must know which tubular drive type has been installed. The required data or parameters of the tubular drive, such as article and serial number, drive type and pulling power are preferably mounted on a nameplate on the tubular drive. If these data or parameters are now stored within a transponder in the tubular drive, they can be read out wirelessly with the aid of an electronic programming and reading device. Since both the roller shutter shaft and the housing tube of the drive but mostly made of metal, such as sheet metal, they would shield the mounted in or on the roller shutter drive transponder as much as possible electrically, so that it is no longer readable from the outside. Similarly, roller shutter boxes, such as lintels or porch elements are largely made of metal and thus shield the transponder on the tubular drive electrically.

Therefore, it is advantageous to bring the antenna of the transponder out of the roller shutter box, so that it can be read with an electronic programming and reading device. Since each tubular drive usually has a connecting cable to its electrical supply, it is inventively provided to use the at least one wire of the connecting cable as an antenna for the transponder chip. The antenna of the transponder is thereby no longer by the Shutter shaft or the shutter box shielded so that the radio signals of the electronic programming and reading device are guided over the at least one acting as an antenna wire of the connecting cable in the tubular drive to the transponder chip. This at least one wire acting as an antenna of the connection cable is also used by the transponder chip for transmitting its information, such as data and parameters of the tubular drive. Thus, all required data and parameters of the tubular drive can be read out wirelessly from the transponder chip mounted in the tubular drive without having to remove the tubular drive from the roller shutter shaft.

Another advantage of the invention is that an improvement in the storage and logistics of the tubular drives during the manufacturing and shipping process by the wireless readout of the data and parameters of the tubular drive from the mounted in the tubular drive transponder chips is achieved. For this purpose, all necessary data and parameters of the drive, such as article and serial number, drive type and train power are programmed into the transponder chip in the production of the tubular drive. These data and parameters can be read out wirelessly at any time during the remaining manufacturing and shipping process via the at least one wire of the connection cable acting as an antenna. The reading out of the transponder chip is also possible in the already packaged state of the tubular drive, as long as the packaging material does not electrically shield the at least one wire of the connecting cable acting as an antenna. In order to be able to access further data and information such as customer, order and delivery data or hard and software versions of the tubular drive in the event of repair or replacement of the drive, these are stored together with those stored in the transponder chip data and parameters in a database ,

In order to subsequently assign further data and parameters to the tubular drive, the transponder chip can be wirelessly programmed via the at least one wire of the connecting cable that acts as an antenna. It is thus possible to store further data and parameters, such as repair and service data, via the electronic programming and reading device in the transponder chip. In the event of repair or replacement of the drive, data and parameters may be subsequently added, ie. H. stored in the transponder chip.

Furthermore, it is provided that the transponder chip is an active or passive transponder chip. Active transponder chips are characterized by the fact that they have an externally supplied electrical supply. For this purpose, the electrical supply of the tubular drive can be used or a separate supply, such as a battery. The advantage of transponder chips with their own power supply is, for example, a higher range. In comparison, passive transponder chips do not have their own power supply. They provide themselves with the radio signal emitted by the electronic programming and reading device itself with energy, which is usually sufficient to send the data and parameters to the electronic programming and reading device. Of advantage here are the lower cost of the transponder chip and the ability to read data and parameters from the transponder chip of the tubular drive, even if it is not supplied with electrical energy.

It is provided that the transponder chip is arranged in the region of the drive electronics or the cable outlet. The drive electronics are preferably arranged in the region of the cable outlet, and the wires of the connection cable are connected to the drive electronics by means of plug or clamp connections or are soldered to the circuit board of the drive electronics. In order to connect the transponder chip to the at least one wire acting as an antenna of the connecting cable, it is therefore advantageous to place the transponder chip in the vicinity of the drive electronics or the cable outlet. As a result, the at least one wire of the connecting cable acting as an antenna does not have to be longer than the wires of the tubular drive required for electrical supply, for example. Furthermore, the available antenna length for the transponder chip within the tubular drive, and thus in the electrically shielded area, is kept as short as possible.

According to an advantageous embodiment of the invention, the transponder chip is connected to the at least one wire acting as an antenna of the connecting cable, for example glued, connected by means of a plug or clamp connection or soldered. The transponder chip is arranged for this purpose at a suitable location in the tubular drive housing, for example in the region of the cable outlet or the drive electronics, and connected to the at least one wire acting as an antenna of the connection cable, preferably adhered thereto.

Transponder chips usually have very small geometric dimensions and are therefore supplied for further processing on straps or rolls. In order to simply and safely connect the transponder chip with the at least one wire of the connection cable acting as an antenna and additionally to minimize the production effort, it is advantageous to connect the transponder chip to the wire to glue. For this, it is not necessary to remove the insulation of the wire to make a conductive connection between the transponder chip and the strand of the wire. It is sufficient to glue the transponder chip to the insulation of the at least one wire of the connection cable acting as an antenna. Due to the small distance between the transponder chip and the strand of the at least one wire acting as an antenna of the connection cable, the reception and transmission signals are coupled by means of an electromagnetic field generated therebetween.

If the transponder chip is connected to the at least one wire of the connection cable acting as an antenna by means of a plug-in or clamp connection, then the connection can be released again at any time. Again, the insulation of the wire does not need to be removed to make a directly conductive connection. It is sufficient to arrange the transponder chip on a plug-in or clamping device, and to connect them to the insulation of the at least one wire acting as an antenna of the connecting cable. The receiving and transmitting signals also couple here by the small distance between the transponder chip and the strand of at least one acting as an antenna wire of the connecting cable via an intervening electromagnetic field.

Furthermore, it is also conceivable to solder the transponder chip to the at least one wire acting as an antenna of the connecting cable. For this purpose, the transponder chip is preferably soldered to the drive electronics in the connection region of the at least one wire of the connection cable acting as an antenna, in order to produce a direct conductive connection between the transponder chip and the strand of the wire.

The transponder chip can be retrofitted in all existing pipe drive systems with little effort, d. H. without having to make major changes to existing pipe drive systems, be installed.

Advantageously, the transponder chip is arranged on the printed circuit board of the drive electronics. The essential components of the transponder chip, such as the analogue circuit for receiving and transmitting as well as the microcontroller and the permanent memory, are placed on the circuit board for this purpose. Preferably, the circuit of the transponder chip is provided in the printed circuit board layout. This means that the components as well as all other electronic components of the transponder chip are equipped with on the circuit board during the production of the drive electronics. There are therefore no additional modules in the field of drive electronics necessary. The wiring effort is simplified because all the wires of the connection cable are connected to the drive electronics or soldered to the circuit board of the drive electronics. Furthermore, an active transponder chip can be co-supplied by the electrical supply of the drive electronics, without the need for further wiring.

It is provided that the transponder chip is an RFID chip. RFID (Radio-Frequency Identification) is a widely used technology that has been successfully used for years in various fields, such as vehicle keys for the electronic immobilizer or in the textile or clothing industry. RFID transponders differ essentially according to transmission frequency, manufacturer and intended use. RFID transponder chips are manufactured, for example, by EM Microelectronic, Rue des Sors 3, 2074 Marin, Switzerland, and are kept very low in their geometric dimensions. As a result, they can be used or used, for example, in entry tickets, identity cards or together with an antenna cable in small glass tubes.

Furthermore, it is provided that the transponder chip is an NFC chip. Using NFC (Near Field Communication), data is transmitted wirelessly over short distances in the range of a few centimeters. Many modern devices, such as mobile phones, smart phones or the like, are equipped with this technology today. Such devices with NFC are used, for example, in the area of cashless payment transactions or in access control systems. It is therefore also possible for the operator or user and / or the service specialist to wirelessly read out or program data and parameters of the tubular drive with one of the aforementioned devices. The mobile phone, smartphone or the like then advantageously replaces a special, no longer necessary, electronic programming or reading device. As chip technology, for example, the MIFARE technology of NXP Semiconductors Netherlands B.V., High Tech Campus 60, 5656 AG Eindhoven, Netherlands is mentioned here. The transponder chips of this technology are kept so small in the geometric dimensions that they can be used, for example, in identity cards or chip cards for access control.

According to an advantageous embodiment of the invention, the at least one wire acting as an antenna of the connecting cable is a wire already used for the electrical supply of the tubular drive or a separate, unused, core. Preferably, the at least one wire acting as an antenna is also used for power supply or Control of the tubular drive used. The connecting cable then no longer has to have an additional wire. If, however, a separate, unused, wire is used exclusively as a transmitting and receiving antenna for the transponder chip, so this is also advantageous because it comes here to no direct interference with any interference or interference frequencies, for example by the engine. The separate, unused, wire is used neither for electronic supply of the tubular drive nor as a control line or the like.

Other objects, advantages, features and applications of the present invention will become apparent from the following description of an embodiment with reference to the drawings. All described and / or illustrated features alone or in any meaningful combination form the subject matter of the present invention, also independent of their summary in the claims or their dependency.

The only 1 shows a tubular drive in longitudinal section, with a transponder chip and a connecting cable.

In 1 is a tubular drive 1 shown in longitudinal section, in which a transponder chip 10 for storing data and / or parameters of the tubular drive 1 is arranged. Here is the transponder chip 10 for example, an RFID or NFC chip. The tubular drive 1 has an electrical connection cable for its electrical supply 12 on which from the cable exit 14 of the tubular drive 1 led out. The connection cable 12 has several wires 13 on which for electrical supply or control of the tubular drive 1 to the usual household power connection or to an in 1 not shown control device can be connected.

The transponder chip 10 is in the tubular drive 1 preferably near the in 1 not shown drive electronics and thus in the field in the tubular drive 1 and leading to the drive electronics wires 13 of the connection cable 12 arranged. Ideally, the transponder chip 10 in the area of the cable outlet 14 arranged to allow the available antenna length for the transponder chip 10 within the tubular drive 1 , and thus in the electrically shielded area, as short as possible. Furthermore, it may be advantageous if the transponder chip 10 with on the circuit board the in 1 Not shown drive electronics arranged and thus captive with the tubular drive 1 or whose drive electronics is connected.

Because the transponder chip 10 in the tubular drive 1 within the tubular drive housing 19 is arranged electrically shielded to the outside, is a wire 11 of the connection cable 12 as an antenna for receiving radio signals 17 a programming and reading device 15 as well as to send in the transponder chip 10 stored data and / or parameters of the tubular drive 1 via radio signals 18 to the programming and reading device 15 used. Is the transponder chip 10 not on the circuit board in 1 Not shown drive electronics arranged, it is with the wire 11 of the connection cable 12 connected, preferably adhered thereto. It is also conceivable that the transponder chip 10 to the vein 11 of the connection cable 12 by means of a plug or clamp connection with the wire 11 connected or in the connection area of the wire 11 is soldered to the drive electronics. Here is the acting as an antenna vein 11 of the connection cable 12 either one already for electrical supply or control of the tubular drive 1 used wire 13 or a separate, unused, vein 13 ,

The programming and reading device 15 indicates sending and receiving the radio signals 17 . 18 an antenna 16 on. Used as a transponder chip 10 used an NFC chip, so instead of the programming and reading device 15 Also be equipped with an NFC technology equipped mobile phone, smartphone or the like. Even if the tubular drive 1 for example, within an in 1 not shown roller shutter shaft or the like is installed, so is the reception and transmission of radio signals 17 . 18 over the vein 11 of the connection cable 12 possible at any time, as the connection cable 12 always out of the tubular drive 1 and thus also out of the example roller shutter shaft or the shutter box is led out.

LIST OF REFERENCE NUMBERS

1

 tubular drive

10

 Transponder chip

11

 antenna

12

 connection cable

13

 Cores of the connection cable

14

 cable outlet

15

 Programming and reading device

16

 Antenna of the programming and reading device

17

 Radio signal of the programming and reading device

18

 Radio signal of the transponder chip

19

 Tubular drive housing

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 20213126 U1 [0002]
• DE 202005019992 U1 [0003]

Claims (9)

Tubular drive ( 1 ) for controlling a dimming or closing device, such as a roller shutter, a blind, an awning, a garage door or the like, with a connecting cable ( 12 ) to its electrical supply, wherein the connecting cable ( 12 ) at least one wire ( 13 ), characterized in that a transponder chip ( 10 ) in the tubular drive ( 1 ) for storing its data and parameters and at least one wire acting as an antenna ( 11 ) of the connection cable ( 12 ) is wirelessly readable. Tubular drive ( 1 ) according to claim 1, characterized in that the transponder chip ( 10 ) via the at least one wire acting as an antenna ( 11 ) of the connection cable ( 12 ) is wirelessly programmable. Tubular drive ( 1 ) according to claim 1 or 2, characterized in that the transponder chip ( 10 ) an active or passive transponder chip ( 10 ). Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the transponder chip ( 10 ) in the area of the drive electronics or the cable output ( 14 ) is arranged. Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the transponder chip ( 10 ) with the at least one wire acting as an antenna ( 11 ) of the connection cable ( 12 ), for example glued, connected by means of a plug or clamp connection or soldered. Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the transponder chip ( 10 ) is arranged on the circuit board of the drive electronics. Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the transponder chip ( 10 ) is an RFID chip. Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the transponder chip ( 10 ) is an NFC chip. Tubular drive ( 1 ) according to one of the preceding claims, characterized in that the at least one wire acting as an antenna ( 11 ) of the connection cable ( 12 ) one already for the electrical supply of the tubular drive ( 1 ) used wire ( 13 ) or a separate, unused, core ( 13 ).

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