EP3084106A1 - Method and device for transmitting electrical power and signals between a wall and a leaf pivotable relative thereto - Google Patents

Abstract

Method and device for transmitting electrical power and signals between a wall and a leaf pivotable relative thereto, in order to supply electric consumers (79) provided on the leaf with electrical actuating power depending on the state of actuation and to supply electric signal transmitters (62) provided on the leaf with electrical operating power, wherein the actuating power and the operating power are transmitted from the wall to the leaf in a galvanically separated manner by means of a single power-transmitting unit (44) and signals are transmitted from the leaf to the wall by means of a first optocoupler (48) in order to adjust the electrical power provided at the wall end as a function of the actuating and operating power requirement, and wherein signals are transmitted bidirectionally between the wall and the leaf, between a control and evaluation unit at the wall end and the signal transmitters, by means of a second optocoupler (50).

Description

 Method and device for transmitting electrical power and signals between and against a wall

 swiveling wings

The invention relates to a method and a device for transmitting electrical power and signals between a wall and a relative to this pivotable wing, wherein the electrical power is transmitted galvanically separated, in particular inductively.

Such a method and such a device are known from DE 39 15 812 A1. For power transmission concentrically arranged coils or a cylindrically formed capacitor are provided. Signal transmission should likewise take place via the coils or the capacitor or via radio.

The disadvantage of this is that in the transmission of the signals by the same arrangement, which also serves for power transmission, a mutual influence of the transmission can not be excluded. In addition, an optimized power transmission regularly requires a different structural adaptation of the coil or the capacitor as an optimized signal transmission, so that the use of the same transmission arrangement can always be only a non-optimal compromise. Also, in the case of an inductive data Transmission limits the speed of data transmission to the maximum transmission frequency.

To remedy this situation, DE 43 44 071 A1 proposes to carry out the data transmission in a light-optical manner. In the case of, for example, a pivotable arrangement of a wing on a wall, the transmitting and receiving diodes should be arranged in the center of a respective coil core, so that the transmitter and receiver work on a common axis. From DE 43 44 071 A1 is also known that - such a device is installed, for example, in Türschar- kidney, without cabling from the door frame to the door energy and thus data can be transmitted. Examples of applications are: detection of electronic keys, door access controls, alarm systems and automatic detection of inductance changes in the event of door hooking.

Although it is possible with a device known from DE 43 44 071 A1, a galvanically isolated power transmission from a wall to a wing movable relative to this and also a data exchange by a light-optical signal transmission. However, in order to be able to use such a device in conjunction with a wing fastened to a building wall in the event of sabotage safety sufficient for certification, a particularly reliable signal transmission and power transmission must be ensured. The invention is therefore based on the object to provide a method in this respect improved and a device suitable for carrying out this method.

This object is achieved by the reproduced in claim 1 method and by the reproduced in claim 4 device.

In the inventive method for transmitting electrical power and signals between a wall and one opposite to this wall pivotable wings are provided on the wing provided electrical consumers operating state dependent with electrical actuation power. By "electrical consumers" are meant, in particular, those devices whose electric power consumption depends substantially on the respective operating state and therefore varies widely, examples being motor locks, door openers and lighting devices By "electrical signal transmitters" are meant in particular those for which a substantially constant electrical power is required, such as glass-breakage sensors, magnetic contacts for shutter monitoring, etc. Both the actuating power and the operating power become galvanic in the method according to the invention transmitted separately by means of a single transformer from the wall to the wing. In order to control the electric power provided on the wall side as a function of the operating and operating power requirement, in the method according to the invention signals are transmitted from the wing to the wall by means of a first optocoupler. In other words, the first optocoupler is part of a likewise galvanically isolated control loop. In order for the regulation and the provision of the actuating and operating power to be insensitive to interference, only signals from the wing to the wall side are transmitted to the demand-oriented provision of the electrical power with the aid of the first optocoupler. On the other hand, with the aid of a second optocoupler, signals are transmitted bidirectionally between a wall-side control and evaluation device and the signal generators so that they can not be adversely affected by interaction with other signals.

The electrical power can be transmitted in particular inductively.

The device suitable for carrying out the method according to the invention comprises a power transmission device, which has an arrangement for the galvanically separated transmission of the electrical power, as well as a first optical system. having coupler for transmitting signals from the wing to the wall for controlling the electrical power provided by the first power transmission device as a function of the wing-side total electrical power demand. With the aid of the control circuit which is completed by means of the opto-coupler, the electrical power provided to the first power transmission device is regulated as a function of the wing-side total electrical power requirement. In this way, the power loss of the device according to the invention can be reduced and unwanted heating of components of the device can be avoided. The first optocoupler is used according to the invention only the formation of the control circuit for the needs-based provision of the wings required, total electrical power.

The device according to the invention further comprises a second optocoupler for bidirectional transmission of signals between the wall and the wing. On the wall side, for example, a control and evaluation device can be provided, which exchanges bidirectional signals with wing side signal generators, for example, to read the operating state (signal transmission from wing to wall), or to control the signal generator (signal transmission from the wall to the wing).

The power transmission device may include a primary coil assembly and a secondary coil assembly. The power transmission is then galvanically isolated inductive. It is particularly preferred if the primary and secondary coil arrangements are arranged in such a way that the coil windings of the primary and secondary coil arrangements lie approximately on a common straight line.

In a variant of the device according to the invention, the coil windings of the primary and secondary coil arrangement have approximately the same diameter and, with the exception of the smallest possible clearance gap, but preferably directly, lie against one another in the direction of the straight line. Since the first optocoupler only transmits signals from the wing to the wall, namely those which characterize the wing-side total power requirement, the first optocoupler can have a wing-side (only) transmitting unit and a wall-side (only) receiver unit.

In contrast, since signals must be transmitted bidirectionally between a wall-side control and evaluation device and wing-side signal generators regularly, the second optocoupler has a transmitting / receiving unit both on the wing side and on the wall side.

Both the first and the second optocoupler may comprise light-emitting diodes. In the case of the second optocoupler two bidirectional, d. H. either find use as a transmitter or as a receiver operating light emitting diode assemblies.

The invention will now be further explained with reference to the drawings, in which an embodiment of a device according to the invention is shown. FIG. 1 shows the embodiment of the device according to the invention in partial longitudinal section; FIG.

Figure 2 shows the detail A in Figure 1 in an enlarged view ..; 3 shows an exploded perspective view of a power transmission module comprising the power transmission device and the first optical coupler; an exploded perspective view of a second optical coupler comprehensive signal transmission assembly; a block diagram of a wall-side electrical circuit and Fig. 6 is a block diagram of a wing-side electrical circuit.

The apparatus designated as a whole by 100 in FIG. 1 comprises two wall parts 1, 2, which are spaced from one another in the direction of a hinge axis S on a wall, not shown in the drawing, which has a door or window opening. The above or subsequent use of the term "wall" includes a frame or frame usually provided at the wall in the region of a door or window opening for receiving a fastening screw 6 and a bore 7 for passing through electrical and / or optical cables 8, which are merely indicated in FIG. 1 and which produce the electrical or optical connection of power or signal transducers and associated electronic or optoelectronic circuits as will be described in more detail below.

Usually, the wall forms a primary side PS, from which electrical power is transmitted to the wing, which is then the secondary side SS.

To the fastening parts 3, 4 is in each case a receiving part 9, 10 for receiving components of power and signal transmission assemblies 1 1, 12 integrally formed. The power and signal transmission modules 1 1, 1 2 form power and signal transmission devices 44, 46 in the exemplary embodiment described here.

The device 100 moreover comprises a wing part 13, which engages in the spacing space formed between the band parts 1, 2. It likewise has a fastening part 14 and a receiving part 15 integrally formed on the fastening part 14. On the fastening part 14, a bore 16 is provided for a fastening screw 17, with which the wing member 13 is mounted on a wing, not shown in the drawing. The fastening part 14 also has, moreover, holes 18 which are the passage of electrical and / or optical cables 19 serve, which are again shown only schematically in the drawing. These cables are used to connect the power and signal transmission modules 1 1, 12 with wing-side electronic or optoelectronic circuits, here the primary electronics 60 and the secondary electronics 75th

The receiving part 15 serves to receive wing-side components of the power and signal transmission assemblies 1 1, 12. These wing-side components comprise two bearing sleeves 20, 21 which are spaced from each other in the direction of the hinge axis S and slidably mounted in this direction relative to each other , The displacement and fixation in a desired position is a spindle drive 22. It comprises an adjusting spindle 23 which centrally a crown gear 24 comprises. This crown wheel is used for the selective attachment of a rotary tool not shown in the drawing or the engagement of a likewise not visible in the drawing rotary actuator. The adjusting spindle also has two threaded portions 25, 26 which comprise externally formed threads in the opposite sense. The threaded portions 25, 26 engage in complementary internal threads 27, 28 of the bearing sleeves 20, 21 a. By rotational actuation of the spindle drive 22, the bearing sleeves 20, 21 can thus be displaced in the direction of the hinge axis, in order thus to move between a mounting position in which the bearing sleeves 20, 21 are at a minimum distance from each other, and an operating position in which the bearing sleeves 20, 21 at bearing sleeves 29, 30 in the receiving parts 9, 10 of the wall parts at least almost rest, to be adjusted. The structure and operation of the power and signal transmission assemblies will be explained below with reference to Figures 2 to 4.

The power transmission assembly 11 comprises in addition to the bearing sleeve 21, which is displaceably mounted in the receiving part 15 of the wing part 13 by means of the adjusting spindle 23, the bearing sleeve 29 which is arranged in the receiving part 10. The functionally corresponding bearing sleeve 30 is accordingly arranged in the receiving part 9 of the upper hinge part 1 (see FIG. 1). A displaceability of the bearing sleeves 29, 30 in the direction of the hinge axis S is not provided. The upper bearing sleeve 30 includes a radially protruding clamping device 31, so that it is rotatably mounted and after a possible removal of the wing member 13 does not fall out automatically down.

The bearing sleeve 29 includes a primary coil assembly 32. It comprises a coil housing 34, which may consist of a soft magnetic, especially ferritic material. It has a central core 36 around which a coil winding 38 is guided. In the core 36, a central bore 40 is provided. It serves to receive a phototransistor 41, which is part of a first optoelectronic signal transmission device 43. The bearing sleeve 29 is provided in the bearing sleeve 30 corresponding manner with a clamping device not shown in the drawing. In the provided in the receiving part 15 of the wing member 13 bearing sleeve 21, a secondary coil assembly 45 is arranged. It comprises a coil housing 47 with a core 49 around which a secondary coil winding 51 is wound. The secondary coil housing 47 in turn has a central, extending through the core 49 central bore 53. It serves to receive a light-emitting diode (LED) 55, which does not necessarily have to work in the visible light range, but which is adapted to the phototransistor 41 with regard to the wavelength of the emitted electromagnetic radiation (or of the visible or invisible light). The light-emitting diode 55 belongs to the primary part of the first optoelectronic signal transmission device 43 and forms a first optocoupler 48 with the phototransistor.

In order to improve the optical coupling of the light emitting diode 55 to the phototransistor 41, light guide inserts 56, 57 are provided, which are inserted from the mutually facing sides of the coil housing into the bores 40, 53 and approximately flush with the mutually facing sides of the coil housing , As in Fig. 3, in which the power transmission assembly is shown in an exploded perspective view, the components of this assembly are arranged approximately symmetrically to a central axis A. In the assembled state, this axis A coincides approximately with the hinge axis S.

4, the signal transmission assembly 12 is shown in a representation corresponding to approximately Fig. 3 representation. It comprises the bearing sleeve 30, a first LED carrier 33, a first transmit / receive LED array 35, light guide inserts 58, 59, a second LED carrier 37, a second transmit / receive LED array 39 and the Bearing sleeve 20. The first transmitting / receiving LED array 35 and the light guide insert 58 are inserted into a central bore 42 of the first LED support, the second transmission / reception LED array 39 and the light guide insert 59 in a bore 44th of the second LED carrier 37. The first and second transmit / receive LED arrays together form a second optocoupler 50.

The signal transmission assembly 12 does not include coil assemblies. The first and second LED carriers 33, 37 may be made of a plastic material.

The frame-side electrical circuit shown as a block diagram in FIG. 5 comprises primary electronics 60, which among other things serve to provide the electrical power as a function of the wing-side actuation and operating power requirement. For this purpose, the primary electronics 60 is electrically connected both to the phototransistor 41 and to the coil winding 38 of the primary coil arrangement 32.

To signals between a wall-side control and evaluation, in the illustrated embodiment formed by a burglar alarm 61, and wing-side signalers 62 in the form of magnetic contacts 63, glass breakage sensors 64, closing contacts 65 and sabotaging 66 bidirectional In addition, the primary electronics 60 is electrically connected to the first transceiver LED array 35.

Further, the primary electronics 60 is electrically connected to a power pack 67, which provides the wing-side actuating power when needed, and to a buffered power supply 68, which is part of the intruder alarm panel 61 and in the event of a power outage or technical failure of the wing-side power supply 67 the operating power requirement of the signal generator 62 is used, connected. If there is no wing-side consumer, the power supply 67 can be omitted.

The primary electronics 60 further includes a plurality of relays 69 that depict signals communicated from opening, breakthrough, shutter and sabotage monitoring. They are connected to the corresponding inputs of the burglar alarm panel, with terminators 70 in series with the trunks. Furthermore, relays are provided for a lid contact and a lift-off contact, as well as for the transmission of disturbances transmitted by a "watchdog." The relays 69 are operated by a processor 71 of the primary electronics in response to the signals received by the first transmit / receive LED array 60 receives the processor 71 via evaluation electronics 72 information about the reporting group voltage and signals of the burglar alarm 61, for example, a latch and trap control.

The processor 71 is also connected to a switching converter 73, which fed back the coil winding 38 in response to the determined by the processor power requirements via the phototransistor 41 with electrical power.

This electrical power is supplied to the switching converter via a switching 74 in the normal operating state of the power supply 67 or in the case of a power failure from the buffered power supply 68. provided. The switch 74 comprises a first electrical energy buffer 54. These energy buffers serve to provide the wing-side actuating power in the event that the supply voltage fails during an actuation process of a consumer 79. This avoids that the actuation process stops, should the supply voltage fail in this case. Basically - if a consumer 79 is present - the provision of both the wing-side actuating power, and the wing-side operating power by means of the power supply 67, only in the event of failure of the power provided by the power supply part supply is switched by means of the switch 74 to the buffered power supply. The uninterrupted operation of the safety-relevant secondary circuit parts is thus ensured. The above-described type of electrical power supply to the primary electronics via the switchover 74 can be used independently of the further embodiment of the device 100 for increasing the reliability in a galvanically separate application of electrical power of an electrical consumer provided on a wing. The above-described method of switching between a power supply and a buffered power supply in case of failure of the power supply, as well as the equipment of primary electronics with a switchover with two electrical energy buffers thus comes to independent inventive importance.

In order to convert the electrical DC voltage provided by the switching 74 to the switching converter 73 into an AC voltage suitable for acting on the primary coil winding 38 and thus for transmission by induction of a secondary alternating voltage in the secondary coil winding 51 of the secondary coil arrangement 45, the switching converter 73 comprises a special variant of a flyback converter. This includes a four high-performance MOSFETs H-bridge. The MOSFETs are controlled by MOSFET drivers, which are controlled by intelligent logic. A controller that has been optimized for this application is used in such a way that both the intelligent, fast control of the H-bridge and the program sequence for monitoring and controlling all functionalities of the H-bridge Secondary electronics 75 can be realized independently of each other in a confined space. In this way, the controller can influence the control of the H-bridge in its program sequence, but retroactive influencing of the control of the H-bridge to the program sequence of the controller is excluded.

The secondary coil winding 51 is electrically connected to a wing-side secondary electronics 75. With this AC voltage, a rectifier 76 is applied, which rectifies this AC voltage. Smoothed by means of a buffer, this DC voltage is fed to a power supply 77 of the secondary electronics 75. Among other things, an overcurrent detection and load separation circuit 78 is connected to this power supply 77. It comprises a power output to which the wing side electrical consumers 79 may be connected.

Furthermore, the power supply 77 comprises a stabilized, short-circuit proof DC voltage output 80, to which, for example, structure-borne sound detectors can be connected and supplied with operating voltage. The processor 81 is provided by means of the power supply 77, the necessary operating power. The processor 81 is also connected to the overcurrent detection and load disconnect circuit 78 by a signal line to effect load disconnection if needed. Furthermore, the second transmission / reception LED arrangement and the LED 55 are connected to the secondary electronics 75.

During operation of the arrangement, the coil winding 38 of the primary coil arrangement 32 is acted upon by the switching converter 73 with the electrical power required to provide the actuating and operating power in the secondary coil winding 51 of the secondary coil arrangement 45 as needed. The regulation takes place via a by the LED 55 and the phototransistor 41 galvanically isolated unidirectional return channel, directly in hardware the control of the H-bridge of the switching converter 73 acts. This type of control employs a flyback converter implemented exclusively in hardware, which does not require a software-controlled program sequence with corresponding delay / response times. However, operating states can be set in which the switch-on / switch-off frequency of the flyback converter is within the audible range. In this case, the control frequency can be changed using the controller software-controlled. Also, without software control, an operating condition may occur in which the system enters a congestion state. Even such an operating state can be prevented by software-controlled shutdown of the blocking converter.

Furthermore, bidirectional signal transmission takes place during operation via the first and second transceiver LED arrays 35, 39. On the one hand, this serves to provide the operating states of the signal transmitters 62 of the burglar alarm control panel 61, and on the other hand, the processor 81 and the signal transmitters, as well as optionally further consumers, can be actuated by the burglar alarm control panel 61.

The secondary electronics further comprises a safety contact 82 for a cover monitoring and a safety contact 83 for a lift-off protection. Further, relays 84, 85 are provided for latch and latch control of the load 79 designed as an engine lock.

Suitable relays are any remote-controlled switches. In the described embodiment are electro-optically operating switch. LIST OF REFERENCE NUMBERS

100 device

 1, 2 band parts

 3, 4 mounting parts

 5 hole

 6 fixing screw

 7 hole

 8 cables

 9, 10 receiving part

 1 1 power transmission module

12 signal transmission module

 13 wing part

 14 fastening part

 15 recording part

 16 hole

 17 fixing screw

 18 hole

 19 cables

 20, 21 bearing sleeves

 22 spindle drive

 23 adjusting spindle

 24 crown wheel

 25, 26 external thread

 27, 28 female thread

 29, 30 bearing sleeves

 31 clamping device

 32 primary coil assembly

 33 first LED carrier

 34 bobbin case

 35 first transmission / reception LED arrangement

36 core 37 second LED carrier

 38 coil winding

 39 second transmission / reception LED arrangement

 40 central hole

41 phototransistor

 42 bore

 43 first opteelectronic signal transmission device

44 power transmission device

 45 secondary coil assembly

46 signal transmission device

 47 coil housing

 48 first optocoupler

 49 core

 50 second optocouplers

51 secondary coil winding

 52 buffers

 53 bore

 54 buffers

 55 LED

56, 57 Fiber optic inserts

 58, 59 fiber optic inserts

 60 primary electronics

 61 Intrusion control panel

 62 signal transmitter

63 magnetic contacts

 64 glass breakage sensors

 65 contacts

 66 sabotage contacts

 67 power supply

68 buffered power supply

 69 relays

 70 monitoring resistors

71 processor 72 evaluation electronics

 73 switching converter

 74 switching

 75 secondary electronics

76 rectifier

 77 power supply

 78 overcurrent detection and load disconnection circuit

79 consumers

 80 DC output

81 processor

 82 safety contact

 83 safety contact

 84 relays

 85 relays

Claims

claims:

A method of transmitting electric power and signals between a wall and a wing pivotable relative to said wall to provide electric actuators (79) operatively connected to said wing with electrical actuation power and electric powered actuators (62) provided on said wing supply,

wherein the actuating power and the operating power are transmitted galvanically separated from the wall to the wing by means of a single power transmission device (44) and signals from the wing to the wall by means of a first optical coupler (48) for controlling the electric power provided on the wall side in dependence on the operating and operating power requirement. be transmitted,

and wherein signals between a wall-side drive and evaluation device and the signal transmitters are transmitted bidirectionally between the wall and the wing by means of a second optocoupler (50).

A method according to claim 1, characterized in that the electrical power is transmitted galvanically isolated inductively.

Device (100) for transmitting electrical power and signals between a wall and a wing pivotally mounted to said wall,

with a power transmission device (44) having an arrangement for the galvanically isolated transmission of electric power and a first optocoupler (48) for transmitting signals from the wing to the wall for controlling the electrical power provided to the first power transmission device (44) in dependence on the wing side electrical Having total power requirement,

characterized, in that a second optocoupler (50) is provided for the bidirectional transmission of signals between the wall and the wing.

4. Apparatus according to claim 3, characterized in that the power transmission means (44) comprises a primary coil assembly (32) and a secondary coil assembly (45).

5. The device according to claim 4, characterized in that the central longitudinal axis of the coil windings (38, 51) of the primary and the secondary coil lenanordnung (32, 45) lie approximately on a common line.

6. The device according to claim 5, characterized in that the coil windings (38, 51) of the primary and secondary coil assembly (32, 45) have approximately the same diameter and, with the exception of the smallest possible gap gap, preferably directly, in the direction of the straight line to each other ,

7. Device according to one of claims 3 to 6, characterized in that the first optocoupler (48) has a wing-side transmitting unit and a wall-side receiver unit.

8. Device according to one of claims 3 to 7, characterized in that the second optocoupler (50) both on the wing side, and on the wall side comprises a transmitting / receiving unit.

9. Device according to one of claims 3 to 8, characterized in that the optocouplers include light and / or photodiodes and / or phototransistors. 10. Apparatus (100) for transmitting electrical power and signals between a wall and a wing pivotally mounted to said wall, with a power transmission device (44) which comprises an arrangement for the galvanically isolated transmission of the electric power from the wall to the wing, in particular according to one of claims 4 to 10, wherein the power transmission device is connected to primary electronics (70).

characterized,

in that the primary electronics (70) have a change-over (74) which comprises a first electrical energy buffer (52) at a first input and a second energy buffer (54) at a second input, and which serves to switch over between the two inputs, wherein the first input to a power supply, the second input is connected to a buffered power supply of a burglar alarm.