EP4050187A1 - Door drive - Google Patents

Abstract

The invention relates to a door drive, in particular a door closer, with a slide rail and a slide block which is guided in the slide rail and is coupled to a drive unit of the door drive via a slide arm, a displacement sensor for determining a position of the slide block in the slide rail being arranged on or in the slide rail is.

Description

The present invention relates to a door drive, in particular a door closer, with a slide rail and a slide block which is guided in the slide rail and is coupled to a drive unit of the door drive via a slide arm.

It is an object of the invention to be able to easily and reliably determine a leaf angle of a door leaf, which is driven by a door drive of the type mentioned above, preferably over the entire range of motion of the door leaf.

This object is achieved by a door drive according to claim 1, and in particular in that a displacement sensor for determining a position of the sliding block in the slide rail is arranged on or in the slide rail.

The path covered by the sliding block during an opening and/or closing movement can be easily measured and/or monitored by the path sensor. In particular, the displacement sensor can be used to measure the displacement, ie the distance between the sensor and the sliding block. The position of the sliding block relative to the slide rail can thus be determined. Depending on the mechanical relationships, the leaf angle of a door leaf driven by the door drive can be inferred.

The invention makes it possible, for example, to monitor the complete opening and/or closing movement of the door leaf in a simple manner. Alternatively, it is fundamentally also conceivable to only determine when the sliding block has reached certain points, such as end positions, and/or zones by means of the displacement sensor.

In principle, a displacement sensor enables a simple structure for determining and monitoring the position of the sliding block or the wing angle. This applies in particular if the slide rail is arranged on the frame, since in this case no flexible cable connection between the sash and the frame is necessary. In principle, however, the displacement sensor can also be designed wirelessly, for example, which offers further advantages.

The displacement sensor can be designed, for example, as an inductive, optical, laser, radar, ultrasonic, PMD, and/or TOF sensor. "PMD" stands for "Photomixing Detector". "TOF" stands for "Time Of Flight".

In principle, the displacement sensor can advantageously be arranged in a sensor housing.

In an advantageous embodiment, it is provided that the sensor housing forms a fastening device for fastening the slide rail to the window frame or to the door leaf. This forms an advantageous integration of functions and enables the door drive to be constructed in a simple manner. The slide rail can thus be attached to the frame or the door leaf in a simple manner via the sensor housing. For example, the sensor housing can form or include a mounting bracket.

Basically, door drives of the type mentioned are typically either attached in such a way that the slide rail is attached to the window frame and the drive unit is attached to the door leaf, or vice versa, i. H. that the slide rail is attached to the door leaf and the drive unit to the frame.

A development provides that the sensor housing has a mounting hole for mounting on the window frame or on the door leaf. So it can Sensor housing and advantageously here also the slide rail are attached, for example by means of a fastening screw on the frame or on the door leaf.

Alternatively or additionally, a fastening device can be provided which is used to fasten the slide rail to the window frame or the sash, with the fastening being carried out independently of the sensor housing. For this purpose, the slide rail itself can have a fastening hole and/or other fastening means, for example.

In particular, it is also possible for the slide rail to have its own fastening device for fastening to at least one fastening point and for the sensor housing to have a fastening device for fastening the assembly of slide rail and sensor housing to at least one second fastening point.

According to a particularly advantageous exemplary embodiment, the sensor housing can form an end cap and/or end cover for the slide rail. In particular, the sensor housing and slide rail can be constructed in a modular manner, in particular as individual modules that are easy to use. The modular design makes it possible, for example, that a sensor housing can be retrofitted with a sensor if required, without having to replace the entire slide rail.

Advantageous exemplary embodiments include the sensor housing being plugged, glued, clipped, clamped and/or screwed onto or into the slide rail. When the sensor housing is plugged into the slide rail, the insertion direction is preferably parallel to the longitudinal direction of the slide rail. The sensor housing can preferably have a projection which is provided for insertion into the slide rail. The projection can, for example, by means of a Be clamped in the slide rail by clamping means such as a screw. For example, the sensor housing or the projection can be inserted into a slideway of the slide rail provided for the slide block.

In a further advantageous exemplary embodiment, it is provided that the displacement sensor is designed to determine the displacement by means of a transit time measurement. This provides a simple and accurate method of determining the path between the sliding block and the sensor, or the position of the sliding block.

According to a further embodiment, the path sensor is designed to determine the path by means of laser distance measurement, in particular by means of laser triangulation and/or laser interferometry. These methods are particularly precise.

For example, it can also be advantageous for a counter-sensor element to interact with the displacement sensor to be arranged on the sliding block. Such a counter-sensor element can also be described as a sensor partner, for example. Depending on the sensor principle used in each case, the counter-sensor element basically serves to enable or improve, in particular the functional reliability or the accuracy, of the position determination by the sensor.

Advantageous exemplary embodiments include the sensor counter-element having a matt, shiny, rough, smooth colored and/or reflective surface for interacting with the displacement sensor. If the path is determined by means of laser triangulation, for example, then the counter-sensor element preferably has a matte surface for interacting with the sensor.

The counter-sensor element can, for example, be magnetic or non-magnetic and/or metallic or non-metallic.

With a further advantage, the door drive can have a control device which is connected to the displacement sensor for processing and/or forwarding the sensor data. The control device can, for example, be arranged on a control circuit board or be formed by such a circuit board.

The control device can preferably be set up to determine the position of the sliding block and/or the wing angle from the sensor data. The sensor data can be raw data, for example, which can also be processed by the control device. Alternatively, the sensor can, for example, output a measured path or distance, which can be used, for example, by the control device to determine the position of the sliding block and/or the wing angle.

According to one embodiment, it is provided that the control device is arranged in a sensor housing. The sensor housing can preferably be of the type described above.

A development provides that the control device can be connected to a building network, a telecommunications network and/or to other devices provided on the relevant door by means of a communication interface. Such devices provided on the door can include additional drives or door closers, particularly if the door includes multiple leaves. The position of the sliding block and/or the wing angle can thus be easily transmitted via the communication interface. For example, the leaf angle of one or more doors and/or door leaves can be monitored centrally in a building network.

The communication interface can be wired and/or wireless, for example. A wireless communication interface can be designed, for example, as a radio, mobile radio, WLAN and/or Bluetooth interface. In the case of a mobile radio interface, the control device can have its own SIM card, for example. A mobile radio interface can be implemented as a 2G, 3G, 4G and/or 5G interface, for example.

According to a development, it is provided that the control device is set up to make the sensor data, the position of the sliding block and/or the wing angle available in real time via the communication interface. This allows particularly precise and reliable monitoring.

In principle, the door drive for the sensor can have a wired energy supply, for example via a mains connection. Alternatively or additionally, the door drive for the sensor can have a wireless power supply, for example from a battery.

The object of the invention is also achieved by a method according to the independent claim directed thereto. This teaches a method for determining a wing angle of a door wing, which is driven by a door drive of the type described above, the wing angle being determined using the path between the displacement sensor and the sliding block, in particular using the position of the sliding block relative to the slide rail and using the mechanical dimensions of the door drive and the wing on the wing angle is closed.

Fig. 1

zeigt einen Türflügel, welcher mit einem erfindungsgemäßen Türantrieb ausgestattet ist.

Fig. 2

zeigt in perspektivischer Darstellung einen Endabschnitt einer Gleitschiene eines Türantriebs.

Fig. 3

zeigt den in Fig. 2 gezeigten Endabschnitt der Gleitschiene in geschnittener Darstellung.

The invention is explained below purely by way of example with reference to the schematic drawings.

1

shows a door leaf which is equipped with a door drive according to the invention.

2

shows a perspective view of an end section of a slide rail of a door drive.

3

shows the in 2 shown end portion of the slide in a sectional view.

In 1 a door arrangement 10 is shown, which comprises a door leaf 12 and a door drive 14 for driving the door leaf 12 . The door leaf 12 is designed as a rotating leaf. The door drive 14 forms a door closer for the door leaf 12.

The door drive 14 includes a sliding rail 16 in which a sliding block 18 is guided. The sliding block 18 is coupled to a drive unit 22 of the door drive 14 via a sliding arm 20 .

To determine the position of the slide block 18 in the slide rail 16 , the door drive 14 includes a displacement sensor which is arranged in a sensor housing 24 . The distance between the sliding block 18 and the sensor or the sensor housing and the position of the sliding block 18 in the slide rail 16 can be determined by means of the displacement sensor. Based on the position of the slide block 18 in the slide rail 16 and knowing the mechanical relationships, such as the dimensions of the slide arm 20 and the mounting position of the door drive 14, the leaf angle of the door leaf 12 can be determined.

In the Figures 2 and 3 is an end portion of a slide rail 16 of a door drive according to the invention, for example that of 1 , shown. In the slide rail 16, a sliding block 18 is arranged and in the longitudinal direction of Slide rail 16 guided movable. The longitudinal direction is indicated by the double arrow.

A displacement sensor 26 is arranged on the slide rail 16, by means of which a displacement of the slide block 18 relative to the displacement sensor 26 and via this the position of the slide block 18 in the slide rail 16 can be determined. The displacement sensor 26 can be used to monitor the complete opening and closing movement of the door.

In the Figures 2 and 3 a sensor signal 28 is indicated as a line between the displacement sensor 26 and the sliding block 18 . The sensor signal 28 is aligned parallel to the longitudinal direction of the slide rail 16 . The displacement sensor 26 looks, as it were, into the guide area of the slide rail 16 .

A counter-sensor element 30 is provided on sliding block 18, which interacts with displacement sensor 26 or sensor signal 28 and enables or improves the measurement. The counter-sensor element 30 can be designed differently depending on the sensor principle.

The displacement sensor 26 is arranged in a sensor housing 24 which forms an end cap for the slide rail 16 in this embodiment. The sensor housing 24 includes a projection 32 which is inserted into the slide rail 16 . To fasten the sensor housing 24 to the slide rail 16 or the projection 32 in the slide rail 16 , the projection 32 is held in the slide rail 16 by means of a screw 34 . Specifically, the projection 32 can be clamped in the slide rail 16 by means of the screw 34 . The screw 34 is easily accessible through the longitudinal opening 36 in the slide rail 16, which is typically directed downward during operation. The screw 34 is designed here as a grub screw, which has the advantage that the path of the sliding block 18 is not impaired.

Due to the advantageous modular design, in particular the design of the sensor housing 24 as an end cap and/or as a plug-in module, the sensor housing 24 can also be retrofitted if necessary without having to replace the entire slide rail 16 .

The sensor housing 24 includes a mounting hole 38 through which the sensor housing 24 and here the slide rail 16 can be attached to a surface provided for this purpose, namely on the window frame or on the door leaf by means of a fastening screw, not shown. The sensor housing 24 thus forms a fastening device for the slide rail 16.

A control board 40 is also arranged in the sensor housing 24, which is connected to the displacement sensor 26 via lines 42 and is set up to evaluate the sensor data. The control board 40 typically includes a communications interface for communicating sensor data, sliding block position, and/or wing angle. This can preferably be implemented wirelessly. This allows - as it turns out about 2 clearly results - a compact structure of the sensor housing 24, since no connection sockets or cable outlets must be provided.

Reference List

10

door arrangement

12

door leaf

14

door drive

16

sliding rail

18

sliding block

20

sliding arm

22

drive unit

24

sensor housing

26

displacement sensor

28

sensor signal

30

sensor mating element

32

head Start

34

screw

36

longitudinal opening

38

mounting hole

40

control board

42

cables

Claims (20)

Door drive (14), in particular door closer, with a slide rail (16) and a slide block (18) guided in the slide rail (16) and coupled to a drive unit (22) of the door drive (14) via a slide arm (20), characterized in that a displacement sensor (26) for determining a position of the sliding block (18) in the slide rail (16) is arranged on or in the slide rail (16). Door drive (14) according to claim 1,
characterized in that the displacement sensor (26) is designed as an inductive, optical, laser, radar, ultrasonic, PMD and/or TOF sensor. Door drive (14) according to claim 1 or 2,
characterized in that the displacement sensor (26) is arranged in a sensor housing (24). Door drive (14) according to claim 3,
characterized in that the sensor housing (24) forms a fastening device for fastening the slide rail (16) to the frame or to the door leaf (12). Door drive (14) according to claim 3 or 4,
characterized in that the sensor housing (24) has a fastening bore (38) for fastening to the frame or to the door leaf (12). Door drive (14) according to at least one of claims 3 to 5,
characterized in that a fastening device is provided which is used to fasten the slide rail (16) to the window frame or to the door leaf (12), the fastening being carried out independently of the sensor housing (24). Door drive (14) according to at least one of claims 3 to 6,
characterized in that the sensor housing (24) forms an end cap and/or end cover for the slide rail (16). Door drive (14) according to at least one of claims 3 to 7,
characterized in that the sensor housing (24) is plugged, glued, clipped, clamped and/or screwed onto or into the slide rail (16). Door drive (14) according to at least one of the preceding claims, characterized in that the path sensor (26) is designed to determine the path by means of a transit time measurement. Door drive (14) according to at least one of the preceding claims, characterized in that the path sensor (26) is designed to determine the path by means of laser distance measurement, in particular by means of laser triangulation and/or laser interferometry. Door drive (14) according to at least one of the preceding claims, characterized in that a counter-sensor element (30) for interacting with the displacement sensor (26) is arranged on the sliding block (18). Door drive (14) according to claim 11,
characterized in that the counter-sensor element (30) has a matt, glossy, rough, smooth, colored and/or reflective surface. Door drive (14) according to claim 11 or 12,
characterized in that the counter-sensor element (30) is designed to be magnetic or non-magnetic and/or metallic or non-metallic. Door drive (14) according to at least one of the preceding claims, characterized in that the door drive (12) has a control device (40), in particular a control circuit board, which is connected to the displacement sensor (26) for processing and/or forwarding the sensor data. Door drive (14) according to claim 14,
characterized in that the control device (40) is set up to determine the position of the sliding block (18) and/or the wing angle from the sensor data. Door drive (14) according to claim 14 or 15,
characterized in that the control device (40) is arranged in a sensor housing (24). Door drive (14) according to at least one of claims 14 to 16,
characterized in that the control device (40) can be connected to a building network, a telecommunications network and/or to other devices provided on the relevant door by means of a communication interface. Door drive (14) according to claim 17,
characterized in that the communication interface is wired and/or wireless. Door drive (14) according to at least one of claims 14 to 118,
characterized in that the control device (40) is set up to make the sensor data, the position of the sliding block (18) and/or the wing angle available in real time via the communication interface. Method for determining a leaf angle of a door leaf (12) which is driven by a door drive (14) according to one of the preceding claims, the wing angle being determined based on the path between the path sensor (26) and the sliding block (18), In particular, the wing angle is determined based on the position of the sliding block (18) relative to the slide rail (16) and based on the mechanical dimensions of the door drive (14) and the wing (12).

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