EP4368803A1 - Door closer and method for controlling a smoke protection printing installation with said door closer - Google Patents

Abstract

The invention relates to a door closer, a housing (1), an arm (2) connected to the housing (1) and an actuating unit (3) for exerting a rotational, tensile or compressive force on the arm (2), characterized by a linear sensor (6) or a rotation angle sensor (7) for measuring the linear position or rotational position of the arm (2) relative to the housing (1). The invention also relates to a method for controlling a smoke protection pressure system for keeping an area of a building to be protected free of smoke, the area to be protected having at least one door which is provided with the door closer according to the invention.

Description

The present invention relates to a door closer according to patent claim 1 and a method for controlling a smoke protection pressure system with this door closer according to patent claim 9.

In order to ensure fire protection in a multi-storey building and to prevent smoke from entering an area of the building that is to be protected, the use of a smoke protection pressure system is standard in the state of the art. To ensure that the smoke protection pressure system functions, a lock control is required, which is sometimes implemented using electrically controlled door closers or free-wheel door closers. The door closers perform various functions, such as closing locks against the overpressure of the smoke protection pressure system in the event of a fire or braking doors that are closed by the smoke protection pressure system. As soon as all doors in the area of the building that is to be protected are closed, the smoke protection pressure system maintains a defined overpressure in it, which prevents smoke from entering.

The opening of a door in the area to be protected, for example by fleeing persons or by the Fire brigade, causes a drop in pressure in the area to be protected. To counteract this drop in pressure, the output of the smoke protection pressure system is temporarily increased. As soon as the opened door begins to close again, the escaping air flow becomes smaller and smaller within a few seconds and finally suddenly reaches zero. The output of the smoke protection pressure system is reduced again accordingly, but only with a certain delay. In the meantime, the excess pressure generated can no longer be reduced and such a high pressure peak can build up in the area to be protected that the braking force of the door closers is no longer sufficient and the door slams shut or, if the air flow is in the opposite direction, the door can only be closed with a great deal of additional force. The infrastructure can therefore suffer considerable damage due to the pressure peaks or there can even be a risk of injury to people nearby.

The present invention now has the task of reducing or even avoiding the pressure peak caused by a closing door in the area of the building to be protected when the smoke protection pressure system is activated.

This object is achieved by the door closer according to claim 1 and the method for controlling a Smoke protection pressure system with this door closer according to patent claim 9. Further features and embodiments emerge from the dependent claims and their advantages are explained in the following description.

The basis of the invention is a door closer which, in addition to its conventional function as a door closer, is also suitable for measuring the opening angle of the door to which it is attached. The measured opening angle of the door is transmitted to the smoke protection pressure system so that the closing process of the door can be monitored and the performance of the smoke protection pressure system can be adjusted as quickly as possible depending on the opening angle of the door. The smoke protection pressure system can thus detect that a door in the area to be protected is closing and reduce its performance depending on the opening angle in order to reduce or even avoid a pressure peak in the area to be protected.

Figur 1a

Bandseitige Montage des Türschliessers

Figur 1b

Gegenbandseitige Montage des Türschliessers

Figuren 2a-e

Ausführungsvarianten des Türschliessers

Figur 3a

Schnitt durch den Türschliesser mit Zahnrad und Zahnstange

Figur 3b

Schnitt durch den Türschliesser mit Kurvenscheibe und Kraftübertragungsrollen

Figur 4

Türschliesser, verbunden mit einer fernen Einheit

The drawings show:

Figure 1a

Hinge-side installation of the door closer

Figure 1b

Mounting the door closer on the opposite hinge side

Figures 2a-e

Versions of the door closer

Figure 3a

Cross-section of the door closer with gear and rack

Figure 3b

Section through the door closer with cam disc and power transmission rollers

Figure 4

Door closer connected to a remote unit

The figures represent possible embodiments, which are explained in the following description.

The door closer according to the invention has a conventional structure with a housing 1, an arm 2 connected to the housing and an actuating unit 3 for exerting a rotational, tensile or compressive force on the arm 2 ( Figures 1a-b ). In the assembled state, the housing 1 is arranged on a door, the arm 2 is connected to the door frame (or vice versa) and when the door moves, the arm 2 is moved relative to the housing 1. The invention lies in the fact that the arm 2 is connected to the housing 1 in a linearly displaceable manner or the door closer comprises another component connected to the arm 2 and linearly displaceable, in which case the door closer has a linear sensor 6 for measuring the linear position of the arm 2 or the component connected thereto relative to the housing 1. Alternatively, the arm 2 can also be rotatably connected to the housing 1 or the door closer comprises another component connected to the arm 2 and rotatable, in which case the door closer has a rotation angle sensor 7 for measuring the angle of rotation of the arm 2 or the component connected thereto relative to the housing 1. By calibration, the door opening angle can be determined from the measured position of the arm 2 or the component connected thereto.

• Der Arm 2 ist mit dem Gehäuse 1 drehbar verbunden. Die Betätigungseinheit 3 ist im oder am Gehäuse 1 angeordnet und ist zur Ausübung einer Drehkraft auf den Arm 2 geeignet (Figur 2a).
• Der Arm 2 ist mit dem Gehäuse 1 linear verschiebbar verbunden. Die Betätigungseinheit 3 ist im oder am Gehäuse 1 angeordnet und ist zur Ausübung einer Zug- und/oder Druckkraft auf den Arm 2 geeignet (Figur 2b).
• Der Arm 2 ist mit dem Gehäuse 1 drehbar verbunden. Die Betätigungseinheit 3 ist am anderen, mit dem Gehäuse 1 nicht verbundenen Ende des Arms 2 angeordnet und ist zur Ausübung einer Drehkraft auf den Arm 2 geeignet (Figur 2c).

• Der Arm 2 ist mit dem Gehäuse 1 drehbar verbunden. Die Betätigungseinheit 3 ist am anderen, mit dem Gehäuse nicht verbundenen Ende des Arms 2 angeordnet und ist zur Ausübung einer Zug- und/oder Druckkraft auf den Arm 2 geeignet (Figur 2d).
• Der Arm 2 ist mit dem Gehäuse 1 linear verschiebbar verbunden. Die Betätigungseinheit 3 ist am anderen, mit dem Gehäuse nicht verbundenen Ende des Arms 2 angeordnet und ist zur Ausübung einer Drehkraft auf den Arm 2 geeignet (Figur 2e).

Preferably, the actuating unit 3 comprises at least one spring 3a, 3b, which exerts a rotational, tensile or compressive force on the arm 2, with which the door is always forced towards the closed position. The actuating unit 3 does not necessarily have to be arranged in or on the housing 1, but can also be located at the other end of the arm. Below are a couple of examples of possible embodiments of the door closer according to the invention:

• The arm 2 is rotatably connected to the housing 1. The actuating unit 3 is arranged in or on the housing 1 and is suitable for exerting a rotational force on the arm 2 ( Figure 2a ).
• The arm 2 is connected to the housing 1 in a linearly displaceable manner. The actuating unit 3 is arranged in or on the housing 1 and is suitable for exerting a tensile and/or compressive force on the arm 2 ( Figure 2b ).
• The arm 2 is rotatably connected to the housing 1. The actuating unit 3 is on the other side, connected to the housing 1 non-connected end of the arm 2 and is suitable for exerting a rotational force on the arm 2 ( Figure 2c ).

• The arm 2 is rotatably connected to the housing 1. The actuating unit 3 is arranged at the other end of the arm 2, which is not connected to the housing, and is suitable for exerting a tensile and/or compressive force on the arm 2 ( Figure 2d ).
• The arm 2 is connected to the housing 1 in a linearly displaceable manner. The actuating unit 3 is arranged at the other end of the arm 2, which is not connected to the housing, and is suitable for exerting a rotational force on the arm 2 ( Figure 2e ).

As it is from the Figures 1a-b As can be seen, the door closer can be mounted on the hinge side as well as the counter hinge side. This also applies to the design variants according to Figures 2a-e , in which the housing 1 is always connected to the door. The housing 1 can also be connected to the door frame.

If the arm 2 is connected to the housing 1 in a linearly displaceable manner, the housing 1 can be provided with a slide rail 4 in which the end of the arm 2 connected to the housing 1 is slidably mounted. If the actuating unit 3 is mounted on the other end not connected to the housing 1 connected end of the arm 2 and is suitable for exerting a tensile and/or compressive force on the arm 2, the actuating unit 3 can be arranged in or on a slide rail 4 in which the end of the arm 2 not connected to the housing 1 is slidably mounted.

If no end of the arm 2 is slidably mounted in a slide rail 4, the arm 2 can comprise at least two arm parts 22, 23 which are rotatably connected to one another (see eg Figures 1a-b ).

If the actuating unit 3 is suitable for exerting a rotational force on the arm 2, the arm 2 has an axis 21 about which it can be rotated. It is advantageous if the actuating unit 3 acts on this axis 21. The actuating unit 3 either exerts a rotational force directly on the arm 2, or it exerts a tensile or compressive force, which is converted into a rotational force by suitable means. These means comprise, on the one hand, a linearly displaceable means for transmitting a tensile and compressive force 5 and, on the other hand, a rotatable means for converting a tensile and compressive force into a rotational force 24. In one possible embodiment of the door closer, the means for transmitting a tensile and compressive force 5 is a rack 5 and the means for converting a tensile and compressive force into a rotational force 24 is a gear 24 ( Figure 3a ). The gear 24 connected to the axle 21 is with the rack 5 in such a way that a rotation of the gear 24 is translated into a linear movement of the rack 5 and vice versa. In an alternative embodiment of the door closer, the means for transmitting a tensile and compressive force 5 is a force transmission roller 5 and the means for converting a tensile and compressive force into a rotational force 24 is a cam disk 24 ( Figure 3b ). The power transmission roller 5 is forced against the edge of the cam disc 24 by the actuating unit 3, and due to the non-uniform edge of the cam disc 24, a rotation of the axle 21 and the cam disc 24 connected thereto is translated into a linear movement of the power transmission roller 5 and vice versa. In order to enable the power transmission in the two directions of rotation and in the two linear directions of movement, it is advantageous if the means for transmitting a tensile and compressive force 5 comprises two power transmission rollers 5 which are arranged on opposite sides of the edge of the cam disc 24.

The linear sensor 6 measures the position of a linearly moving component of the door closer, for example the position of the end of the arm 2, which is slidably mounted in the slide rail 4. Alternatively, the linear sensor 6 can also measure the position of the means for Transmission of a tensile and compressive force 5, for example of the rack 5 or the force transmission roller 5. By means of calibration, the door opening angle can be determined from this measured linear position. The angle of rotation sensor 7 measures the rotational position of a rotating component of the door closer, for example the rotational position of the axis 21 of the arm 2. Alternatively, the angle of rotation sensor 7 can also measure the rotational position of the means for converting a tensile and compressive force into a rotational force 24, for example of the gear 24 or the cam disk 24. By means of calibration, the door opening angle can be determined from this measured linear position.

Preferably, the linear sensor 6 or the angle of rotation sensor 7 outputs an output signal 10 which can be transmitted to a remote unit 9, for example to a control unit of the smoke protection pressure system ( Figure 4 ). This output signal 10 can be transmitted by cable or wirelessly and by the linear sensor 6 or the angle of rotation sensor 7 itself or by a separate transmitter 8. In the preferred embodiment of the invention, the linear sensor 6 or the angle of rotation sensor 7 is controlled via a cable connection, for example with a voltage of 24VDC and has an output signal of 4 to 20 mA. This output signal of the sensor is fed into a central control of the Smoke pressure system recorded and evaluated.

The output signal 10 can be the measured position of the linearly displacing or rotating component of the door closer or can contain the door opening angle derived therefrom. If the output signal 10 contains the door opening angle, the door closer can be provided with a processor 11 in which the calibration is stored and which is programmed to convert the measured position of the linearly displacing or rotating component of the door closer into the corresponding door opening angle. The energy for operating the linear sensor 6 or the angle of rotation sensor 7, the processor 11 and the transmitter 8 could be stored in the actuation unit 3 when the door is opened and converted into electricity by a small power generator when the door is closed.

In an alternative design variant, the door closer does not emit a signal, but the linear sensor 6 or the angle of rotation sensor 7 is designed in such a way that a physical quantity is changed depending on the door opening angle, and this physical quantity is measured by an external unit, for example by the smoke protection pressure system, from a distance with a cable or wirelessly. For example, the electrical resistance between two electrodes of the linear sensor 6 or the angle of rotation sensor 7 vary depending on the position of the linearly moving or rotating component of the door closer.

It is particularly advantageous if the linear sensor 6 or the angle of rotation sensor 7 not only measures the door opening angle, but can also check whether the door closer is actually mounted on the door and operational. The aim is to be able to detect if the door closer has been removed from the door, if the door closer has broken, or if there is a disruption in communication between the door closer and a remote unit 9 (e.g. due to a broken cable). For this purpose, the output signal 10 or the measurable physical quantity of the linear sensor 6 or the angle of rotation sensor 7 is different when the door closer is mounted on the door and operational than when it is not mounted on the door or is not operational. This can be implemented technically as follows: The linearly moving or rotating component of the door closer, the position of which is measured by the linear sensor 6 or by the angle of rotation sensor 7, can be moved or rotated linearly in the housing 1 between a first end position and a second end position and is always pushed, pulled or rotated in the direction of the first end position by the actuating unit 3. In the When the door closer is in the assembled state, however, this component is only moved within a small range between the first and second end positions when the door is opened and closed, and when the door closer is in the assembled state, it never reaches the first end position. For example, the end of the arm 2, which is slidably mounted in the slide rail 4, or the means for transmitting a tensile and compressive force 5, for example the toothed rack 5 or the force transmission roller 5, can be linearly movable in the housing 1 between a first end position and a second end position, can always be pushed or pulled in the direction of the first end position by the actuating unit 3, but when the door closer is in the assembled state, they never reach the first end position. Thus, the rotating axis 21 of the arm 2 or the means for converting a tensile and compressive force into a rotational force 24, for example the gear 24 or the cam disk 24, can be linearly movable in the housing 1 between a first end position and a second end position, can always be rotated in the direction of the first end position by the actuating unit 3 but never reach the first end position when the door closer is assembled. When assembling the door closer, the actuating unit 3 is pre-tensioned and the linearly moving or rotating component of the door closer, the position of which is determined by the linear sensor 6 or by the angle of rotation sensor 7 is moved away from its first end position. If the door closer or the arm 2 is dismantled, this component is immediately moved to its first end position by the actuation unit 3. The linear sensor 6 or the angle of rotation sensor 7 will therefore determine a value which is outside the normal operating range and will be recognised by the remote unit 9 as a sign of dismantling or damage to the door closer. This can, for example, trigger an alarm or repair work and avoids the function of a smoke pressure system being affected in the event of a fire due to incorrect input regarding the door opening angle. It is particularly advantageous if the output signal 10 always contains a value which is above a certain minimum value under normal conditions and this value is lower or zero in the event of a fault. In this way, a cable break or a malfunction of a transmitter 8 can also be detected if the remote unit 9 no longer receives an output signal 10 from the door closer. As long as the linear sensor 6 or the angle of rotation sensor 7 determines a value that is within the normal operating range, it can be assumed that the door closer is operational.

In the event of a fire, the smoke protection pressure system of a building raised in order to generate an overpressure in an area to be protected. This zone to be protected has at least one door which is equipped with the door closer according to the invention. The smoke protection pressure system is usually equipped with a pressure sensor which is arranged in the area to be protected and serves as the basis for controlling the smoke protection pressure system so that a defined overpressure is maintained in the area to be protected. In the stationary state, all doors in the area to be protected are closed and the smoke protection pressure system is operated according to a first power level with which the smoke protection pressure system compensates for the pressure loss through the various leakage points in the area to be protected and maintains a constant overpressure therein. The opening of the door, which is equipped with the door closer, causes a pressure drop in the area to be protected, which is detected by the pressure sensor and the smoke protection pressure system is operated in response to this according to a second, increased power level, with which the smoke protection system tries to compensate for the additional pressure loss caused by the opened door and to restore the defined overpressure. When the door is closed, the reducing door opening angle is determined by the door closer and the smoke protection pressure system is activated before the completely closing the door according to at least a third performance level between the first and second performance levels. By reducing the performance of the smoke protection pressure system depending on the door opening angle and in any case before the door is completely closed, the pressure peak in the area to be protected is reduced or even completely avoided after the door is closed. Thanks to the door closer, the smoke pressure system immediately detects the door closing process and its performance can be adjusted immediately in response. The time delay that results from controlling the smoke pressure system exclusively based on the pressure measurement in the area to be protected and which causes a pressure peak there is avoided. It is particularly advantageous if there is not just a third performance level between the first and second performance levels, but several levels, or the performance of the smoke protection pressure system can be continuously reduced. From which door opening angle, how quickly and up to which level the performance of the smoke protection pressure system should be optimally reduced when the door is closed can be determined for each specific application by tests or simulations.

There are numerous applications for the door closer presented here. Monitoring the opening angle of a Door can also be of interest, for example, in the context of monitoring a building and protecting it against intrusions.

Claims (10)

Door closers comprehensive a housing (1), an arm (2) connected to the housing (1) and an actuating unit (3) for exerting a rotational, tensile or compressive force on the arm (2), marked by a linear sensor (6) for measuring the linear position of the arm (2) or a component connected thereto relative to the housing (1) or a rotation angle sensor (7) for measuring the rotational position of the arm (2) or a component connected thereto relative to the housing (1). Door closer according to claim 1 with a linear sensor (6),
characterized in that the linear sensor (6) is suitable for measuring the linear position of the arm (2) movably connected to the housing (1) or of another component of the door closer connected to the arm (2) and linearly displaceable, the linear sensor (6) is suitable for outputting an output signal (10) which contains the measured position of the arm (2) or the component connected thereto or the door opening angle derived therefrom, and the linear sensor (6) or a separate transmitter (8) is suitable for transmitting this output signal (10) to a remote unit (9). Door closer according to claim 1 with a linear sensor (6),
characterized in that
the linear sensor (6) is suitable for measuring the linear position of the arm (2) slidably mounted in the housing (1) or of another component of the door closer connected to the arm (2) and linearly displaceable, and a measurable physical quantity of the linear sensor (6) depends on the door opening angle. Door closer according to claim 2 or 3
characterized in that
the output signal (10) or the measurable physical quantity of the linear sensor (6) is different when the door closer is mounted on a door than when it is not mounted on a door. Door closer according to claim 1 with a rotation angle sensor (7),
characterized in that the angle of rotation sensor (7) for measuring the linear position of the arm (2) rotatably connected to the housing (1) or of another arm (2) connected to the arm (2) and rotating component of the door closer, the angle of rotation sensor (7) is suitable for outputting an output signal (10) which contains the measured position of the arm (2) or the component connected thereto or the door opening angle derived therefrom, and the angle of rotation sensor (7) or a separate transmitter (8) is suitable for transmitting this output signal (10) to a remote unit (9). Door closer according to claim 1 with a rotation angle sensor (7),
characterized in that
the angle of rotation sensor (7) is suitable for measuring the linear position of the arm (2) rotatably connected to the housing (1) or of another rotating component of the door closer connected to the arm (2) and a measurable physical quantity of the angle of rotation sensor (7) depends on the door opening angle. Door closer according to claim 5 or 6
characterized in that
the output signal (10) or the measurable physical quantity of the angle of rotation sensor (7) is different when the door closer is mounted on a door than when it is not mounted on a door. Door closer according to claim 4 or 7
characterized in that
the arm (2) or the component connected to it: • is linearly movable or rotatable in the housing (1) between a first end position and a second end position; • the actuating unit (3) always pushes, pulls or turns in the direction of the first end position; • during assembly the door closer is moved away from its first end position and the actuating unit (3) is pre-tensioned; • when the door closer is mounted, it can only move within a small range between its first and second end positions when the door is opened and closed; and • when the door closer is installed it never reaches its first end position. Method for controlling a smoke protection pressure system for keeping an area of a building to be protected free of smoke, wherein the area to be protected has at least one door which is connected to the door closer according to claim 1,
comprising the following procedural steps: • in the event of a fire, the smoke protection pressure system is started up and a stationary state is reached in which the door is closed, the smoke protection pressure system is operated at a first power level and a defined stable overpressure prevails in the area to be protected; • in response to the door being opened, the smoke protection pressure system is operated at a second, increased performance level; • When the door is closed, the reducing door opening angle is determined by the door closer and the smoke protection pressure system is operated at at least a third power level between the first and second power levels before the door is completely closed, so that a pressure peak in the area to be protected is reduced or even completely avoided after the door is closed. Method according to claim 9,
characterized in that the smoke protection pressure system between the first and second performance levels on several performance levels between the first and second performance levels is operated, or the performance of the smoke protection pressure system is continuously reduced between the first and second performance levels.

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