EP1849951B2 - Sliding door assembly - Google Patents

Description

The invention relates to a sliding door system according to the preamble of claim 1.

From the DE 39 40 762 A1 An automatic sliding door system which can be used in an escape and rescue route and has at least one sliding leaf which can be driven by a drive device is known. The drive device is controlled by an electronic control device. With sliding door systems of this type, it is necessary for the sliding wing to be opened as quickly and completely as possible after activation of the control device with an emergency signal and / or in the event of a mains power supply failure to release an escape route, but at least within a predetermined maximum time, also a predetermined minimum opening width, for example 80% of the full Opening width reached. In order to prevent unauthorized passage of the sliding door system, it can be locked in at least one operating state, for example the so-called night mode, by a locking device. The locking device is actuated via a device for switching operating states of the sliding door system, specifically here via a program switch.

Program switches of this type are distinguished by the fact that certain switching operations, often even all switching operations, can only be carried out by persons authorized for this purpose, for example by key actuation or via a code input device. This means that the sliding door system locked in at least one operating state cannot be unlocked by persons who are not authorized to operate the program switch. This in turn could mean that, in an emergency, those persons who are not authorized to operate the program switch could not leave the hazardous location, for example the interior of the building, through the sliding door system. Automatic sliding doors for use in escape routes may only be locked if there are no requirements for the escape door as escape and rescue route for this period. This is usually the case when there are no more people in the building, or when another escape route is designated for these people. If, in turn, other operating states enabling the leaving of the building are set by means of the program switch, the leaving of the building must be done by everyone, i.e. also possible by persons not authorized to operate the program switch, however, when these operating states are set, there is no protection against unauthorized passage due to the lack of locking.

From the GB 1 368 218 a hydraulically controllable sliding door with an electromechanical drive is known. To lock the sliding door there is a polarized envelope magnet which can be switched between its two positions by means of pulses and remains in its current position by permanent magnets even in the event of a power failure. Use of this sliding door in escape and rescue routes is not intended.

From the DE 40 28 190 A1 automatic door monitoring is known. An emergency opening of the sliding sash can be triggered by means of a release device designed as an emergency button. The activation device is self-monitoring. A locking device, in particular its control, is not shown.

From the AU 570 637 B an automatic sliding door system is known, the sliding leaf of which is moved into one of its end positions in the event of a power failure by a mechanical energy store which is locked in normal operation and is pretensioned. An activation device for the manual creation of the escape route is not available.

From the DE 43 44 729 A1 A control and / or regulation of a door which can be used in an escape and rescue route is known. A release device, referred to as an emergency stop button, is connected to a basic unit of the control system, while the lock interacts with an expansion module of the control system. The base unit and expansion modules are networked using a bus system. There is no interaction between the activation device and the lock.

The invention has for its object to provide a sliding door system, which both meet the requirements of escape and rescue routes and ensures protection against unauthorized passage.

The object is achieved by the features of patent claim 1. The subclaims form advantageous design options for the invention.

The sliding door system can be locked securely in certain operating states, so that protection against unauthorized passage is provided. Due to the fact that there is an unlocking device that serves to unlock the locking device and to open the sliding sash, if necessary, especially in an emergency, anyone who has to pass the escape route leading through the locked sliding door system can unlock the sliding door system and open it trigger the sliding sash.

A redundant, in particular fail-safe, design of the unlocking device enables reliable unlocking and opening of the sliding door system even if a fault occurs in the unlocking device. Redundancy can be achieved by maintaining components several times, whereby if one component fails, its function is taken over by another, similar component.

Devices for self-monitoring of the activation device and / or the control device can be provided. This will make additional Safety is achieved because faults in the activation device and / or the control device are automatically recognized and reactions to these faults are triggered automatically.

The activation device can have a manually actuable actuating device, which can be designed, for example, as an emergency button.

Alternatively or additionally, the activation device can have an electrically controllable actuating device, which can have an electrical signal input, for example. This makes it possible to transmit an electrical emergency signal from an external device, for example an emergency detector or a central monitoring device.

The locking device can advantageously be operated according to the open-circuit principle, in order in any case to get into the unlocking state if the supply voltage fails. The locking device is arranged in a locking circuit, to which a supply voltage is present. To unlock the locking circuit can be interrupted by a switch contact, for example by a switch designed as an opener. Fail-safe can be achieved, for example, in that the interlocking circuit can be interrupted with multiple poles by the isolating device, for example in the interlocking circuit at least two switching contacts designed as openers, which can be actuated by the isolating device, can be arranged, so that even if one of these switching contacts still fails it is possible to interrupt the locking circuit.

The control device has at least one input for a control signal, for example a control voltage. The control device is designed in such a way that the activation or deactivation of the control voltage at the input causes unlocking and opening of the sliding sash by the drive device. The control voltage can be connected to the input via at least one control voltage circuit. At least one switch contact which can be actuated by the isolating device is arranged in the control voltage circuit.

The switching contacts of the locking circuit and the switching contact of the control voltage circuit can be actuated jointly by the isolating device, so that actuation of the isolating device both activates the locking device and activates at least one of the inputs.

As the opening of the previously locked sliding sashes is connected to the activation of the activation device, this should be indicated. For this purpose, the activation device can have at least one display device for displaying the actuation of the activation device, which can be designed as a visual and / or acoustic display. As an alternative or in addition, the activation device can have at least one signal output for outputting a signal indicating the activation of the activation device, which for example is sent to a higher-level monitoring device, e.g. in a building control center. The signal output can be designed as an interface, for example for a bus system. The display device and / or the signal output can also be in another suitable position in or on the sliding door system, e.g. in the control device, arranged, in particular integrated.

There can be a release relay that can be controlled by an output signal, with which a temporary activation of the locking device and a temporary activation of at least one of the inputs can be effected. The release relay can be designed as a time relay, i.e. effect an activation of the locking device limited to a predetermined time. For this purpose, at least one further switching contact, which is designed as an opener and can be actuated by the release relay, and at least one further switch contact, which is designed as a normally open contact and can also be actuated by the release relay, can be arranged in the locking circuit. What can be connected to the release relay for a predetermined time period can be generated by a switch device. The switch device can be designed as a key switch, code input device or the like. The temporary activation described can be useful if the sliding door system is already closed and locked, but must still be passed by authorized persons.

Fig. 1

eine Frontansicht einer erfindungsgemäße n Schiebetüranlage;

Fig. 2

eine schematische Darstellung eines Ausführungsbeispiels des Freigebeschalkreises der erfindungsgemäßen Schiebetüranlage;

Fig. 3

eine schematische Darstellung eines weiteren Ausführungsbeispiels des Freigebeschalkreises der erfindungsgemäßen Schiebetüranlage.

An exemplary embodiment in the drawing is explained in more detail below with reference to the figures. Show:

Fig. 1

a front view of a sliding door system according to the invention;

Fig. 2

is a schematic representation of an embodiment of the release circuit of the sliding door system according to the invention;

Fig. 3

is a schematic representation of another embodiment of the release circuit of the sliding door system according to the invention.

In the Fig. 1 a sliding door system 1 is shown in front view. The sliding door system 1 has two sliding leaves 2, which are guided displaceably in a running rail arranged in the region of a drive device 5 and can be driven by the drive device 5. Two fixed panels 3 are arranged to the side of the sliding sash 2 and delimit a passage area 4 of the sliding door system 1. The sliding sash 2 give the passage area when open 4 freely, which lies between an area 11 arranged in front of the sliding door system 1 and an area 12 arranged behind the sliding door system 1.

The various operating states of the sliding door system 1 can be set by means of a program switch 6, which is arranged in a fixed position in the vicinity of the sliding door system 1. It can be provided that this setting option exists only for persons authorized for this purpose, for example by key actuation or via a code input device, in order to avoid undesired settings of operating states of the sliding door system 1.

At least one sensor 7 is arranged above the passage area 4 of the sliding door system 1 and can be designed as a motion detector. The sensor 7 detects a detection area located in front of the sliding door system 1, and a further sensor can be arranged on the other side of the sliding door system 1, which detects a detection area located behind the sliding door system 1 in a corresponding manner.

The area 11 arranged in front of the sliding door system 1 can be designed as a potential danger area, for example as an interior of a building, and the area 12 arranged behind the sliding door system 1 can be designed as an escape area, so that an escape route with an escape direction 10 can lead through the passage area 4 of the sliding door system 1 , For this purpose, the sliding door system 1 must be designed in such a way that the sliding leaves 2 are opened as quickly and completely as possible after activation of the control device (SE) with an emergency signal and / or if the mains power supply fails to release the escape route, but at least within a predetermined maximum time a likewise predetermined minimum opening width , for example 80% of the full opening width.

In order to achieve a secure locking of the sliding door system 1 in certain operating states, for example in the event that the sliding door system 1 cannot be permanently monitored, it is provided that the sliding sash 2 of the sliding door system 1 has a (in the Fig. 1 (Not shown) locking device VE can be locked in their closed position. The locking device VE can be actuated via the program switch 6, so that it is effective in at least one operating state of the sliding door system 1 in the locked state. In order to ensure unlocking of the locking device VE and to release the escape route leading through the passage 4 of the sliding door system 1 in the event of failure of the electrical power supply network to which the sliding door system 1 is connected, it is provided that the locking device VE can be operated with the open-circuit principle, that is to say that the locking device VE is in its locking position when energized and automatically reaches its unlocking position in the absence of energization. The locking device VE, which can be operated with the operating current principle, can have an electromagnet or an electric motor as an electrical actuator, which, when energized, applies the locking element of the locking device VE, for example a locking bolt, to its locking position. Furthermore, the locking device VE, which can be operated with the open-circuit principle, can have a feedback device for the locking element which, in the absence of current supply to the electrical actuator, acts on the locking element in its unlocking position and can be designed, for example, as a mechanical energy store.

An unlocking device 8, by means of which the locking device VE can be unlocked, is arranged near the sliding door system 1, in this exemplary embodiment on a post arranged next to the fixed field 3. In addition, the activation device 8 can also cause the sliding sash 2 to be opened by the drive device 5. The release device 8 has a manually actuable actuating device 9, which is designed, for example, as an emergency button. The actuation of the unlocking device 8 can be displayed in various ways: on the one hand by optical and / or acoustic signal transmitters in the area of the sliding door system 1 and / or on the other hand at a point remote from the sliding door system 1 via a signal output which is in the unlocking device 8 or elsewhere the sliding door system 1 and is designed, for example, as an interface for a bus system. A signal indicating the actuation of the activation device 8 can thus be output to a central monitoring device via the signal output.

In the Fig. 2 A first exemplary embodiment of the release circuit of the sliding door system 1 according to the invention is shown schematically. The control device SE has an electrical connection which carries a supply voltage U ₂ with respect to a switchable output A _SKV , which can be at ground potential, for example. A locking circuit SK _V , in which the electrical actuator of the locking device VE is located, is connected to these two connections. When the locking circuit SK _V is closed, the supply voltage U _{2 is} thus present at the electrical actuator of the locking device VE, as a result of which the actuator acts on the locking element of the locking device VE in its locking position. By switching the switchable output A _SKV , for example disconnection from the ground potential, the current no longer present in the electrical actuator of the locking device VE triggers the locking device VE. The switchover of the switchable output A _SKV can be triggered, for example, by actuating the program switch 6 or by a program sequence of the control device SE.

To interrupt the energization of the locking device VE is also arranged in the locking circuit SK _V a switch contact S _{3 designed} as an opener, which can be actuated via the actuating device 9 of the isolating device 8.

The sensor 7, for example in the form of a motion detector, is only shown schematically in this exemplary embodiment, since only its function in the control voltage circuit SK _A is to be shown here. Via the control voltage circuit SK _A , a control voltage U _{1 can be} applied to several inputs E ₁ , E ₂ , E _{3 of} the control device SE via several partial circuits SK _A1 , SK _A2 , SK _A3 . The sensor 7 has a switching contact S ₄ which is arranged in the partial circuit SK _A1 and is designed as an opener and which opens when the sensor 7 is activated and thus interrupts the partial circuit SK _A1 . When the control voltage U _{1 is} thereby switched off from the input E ₁ used to control the drive device 5, the control device SE triggers an opening of the sliding sash 2 by the drive device 5. When the switching contact S ₄ closes, ie when the sensor 7 is not activated and the control voltage U ₁ at the input E ₁ is repeated, the control device SE closes the sliding sash, if necessary after a predetermined hold-open time stored in the control device SE 2 caused by the drive device 5.

In addition, two further switching contacts S ₁ , S ₂ , each designed as an opener, can be actuated via the actuating device 9 of the isolating device 8, together with the switching contact S ₃ described above, which are arranged in the control voltage circuit SK _A. The opening of the switching contact S _{1 of} the disconnecting device 8, which is in series with the switching contact S4 of the sensor and also in the partial circuit SK _A1 , thus also causes the opening of the sliding sash 2 by the drive device 5.

The free inputs E ₂ , E _{3 of} the control device are used for error safety, specifically for checking the sensor 7, the disconnection device 8 and the associated cabling:

When the sensor 7 is activated, in addition to the switch contact S ₄ in the partial circuit SK _A1 already described, the switch contact S5 of the sensor 7, which is in the further partial circuit SK _{A3 and} is designed as an opener, is opened and thus the control voltage U ₁ from the input E _{3 of} the Control device SE switched off. The signals (voltages) present at the inputs E ₁ , E ₃ are compared with one another. A deviation of the signals present at the inputs E ₁ , E ₃ from one another means a fault, for example one of the switch contacts S ₄ , S _{5 of} the sensor 7. The control device SE can then with a safety response, for example with an emergency opening of the sliding leaf 2 and possibly with a display of the fault, react to this fault.

When the actuating device 9 of the isolating device 8 is actuated, in addition to the switching contact S ₁ already described in the sub-circuit SK _A1 , the switching contact S ₂ in the further sub-circuit SK _A2 is also opened and the control voltage U _{1 is} thus switched off from the input E _{2 of} the control device SE. The signals (voltages) present at the inputs E ₁ , E ₂ are also compared with one another. A deviation of the signals present at the inputs E ₁ , E ₂ from one another means a fault, for example one of the switch contacts S ₁ , S ₂ . The control device SE can then also respond to this fault with a safety response.

In the Fig. 3 A further exemplary embodiment of the release circuit of the sliding door system 1 according to the invention is shown schematically. The control device SE has an electrical connection which carries a supply voltage U _{3 in} relation to a connection with ground potential GND. A locking circuit SK _V , in which the electrical actuator of the locking device VE is located, is connected to these two connections. When the locking circuit SK _V is closed, the supply voltage U _{3 is} thus present at the electrical actuator of the locking device VE, as a result of which the actuator acts on the locking element of the locking device VE in its locking position. For multi-pole interruption of the energization of the locking device VE, two switching contacts S ₉ , S ₁₀ are arranged in the locking circuit SK _V and can be actuated together via the actuating device 9 of the isolating device 8. The multi-pole interruption of the interlocking circuit SK _V serves to ensure single-fault safety, since if one of the switch contacts S ₉ , S _{10 is} assumed to be defective (not opening), the interlocking circuit SK _{V is} interrupted by the other switching contact S ₁₀ , S ₉ .

In addition, two further switch contacts S ₁₁ , S ₁₂ , each formed as a make contact, can be actuated via the actuating device 9 of the isolating device 8, together with the switch contacts S ₉ , S ₁₀ described above, which are each arranged in a control voltage circuit SK _A4 , SK _A5 . A control voltage U _{4 is} applied to an input E _{4 of} the control device SE via the control voltage circuit SK _A4 , ie when the control voltage U _{4 is applied to} the input E ₄ , the control device SE triggers an opening of the sliding sash 2 by the drive device 5. The same applies to the input E _{5 of} the control device SE, to which a control voltage U ₅ can be applied via the control voltage circuit SK _{A5 in} order to trigger an opening of the sliding sash 2 by the drive device ₅ via the control device SE. The control voltage U ₄ , U ₅ can be the same, but advantageously different Voltage sources come so that if one voltage source fails, it is still possible to control the control device from the other voltage source. The actuation of the isolating device 8 leads to the switching contacts S ₁₁ , S _{12 being closed} and thus to the control voltages U ₄ , U _{5 being applied} to the inputs E ₄ , E _{5 of} the control device SE. The multiple presence of the inputs E ₄ , E ₅ and the connection of the control voltages U ₄ , U ₅ via a plurality of switching contacts S ₁₁ , S ₁₂ serves to ensure single-fault safety since one of the switching contacts S ₁₁ , S _{12 is} defective (not closing) a control voltage U ₅ , U _{4 is applied} via the other switching contact S ₁₂ , S ₁₁ .

The actuation of the unlocking device 8 thus leads to the unlocking of the locking device VE and to the opening of the sliding leaves 2 by the drive device 5, which is triggered by the control device SE. The unlocking device 8 is provided for emergency situations in which the passage area 4 of the sliding door system 1 is used as an escape route, i.e. After actuation of the unlocking device 8, the sliding leaves 2 remain in the open state after being opened until an authorized person resets the unlocking device 8. For this purpose, the actuating device 9 of the isolating device 8 can be a protective device, e.g. have a sealed cover, which allows actuation, but not a reset of the actuating device 9.

However, in order to enable the locked sliding door system 1 to be opened temporarily, ie with subsequent closing and locking of the sliding sash 2, a short-term release device is also provided in addition to the release device 8. This has an enable relay KF, which can be controlled by a trigger signal A _KF . The trigger signal A _KF can be emitted by a switch device (not shown), which can be designed as a key switch, code input device or the like. The enabling relay KF can be designed as a time relay, ie after it has been activated, the relay remains in the switching state triggered by the activation for a predetermined time and automatically switches back to its original switching state after this time has elapsed.

A switching contact S ₆ , which is designed as an opener and can be actuated by the release relay KF, is arranged in the locking circuit SK _V and interrupts the locking circuit SK _V when the release relay KF is activated and thus causes the energization of the locking device VE to be canceled. Furthermore, the release relay KF can be used to actuate two switching contacts S ₇ , S ₈ , each arranged in the control voltage circuits SK _A4 , SK _A5 and designed as normally open contacts, which close the control voltage circuits SK _A4 , SK _A5 when the release relay KF is activated and thus via the control device SE trigger an opening of the sliding sash 2 by the drive device 5. After the activation of the release relay KF, the switch contacts S ₆ , S ₇ , S _{8 come} into their starting position. As a result, the A n control voltage circuits SK _A4 , SK _{A5 are} interrupted, which, if appropriate after a predetermined open time which can be stored in the control device SE, causes the sliding sash 2 to be closed by the drive device 5. Furthermore, the locking circuit SK _{V is} closed, whereby the sliding sash 2 can be locked again after reaching its closed position.

List of reference characters

1

sliding door system

2

sliding panel

3

fixed panel

4

Passage area

5

driving means

6

program switch

7

sensor

8th

Disconnection device

9

actuator

10

escape direction

11

Area

12

Area

A _KF

trigger signal

E ₁

entrance

E ₂

entrance

E ₃

entrance

E ₄

entrance

E ₅

entrance

GND

ground potential

KF

release relay

SE

control device

SK _V

Locking circuit

SK _A

Ansteuerspannungsstromkreis

SK _A1

Part Circuit

SK _A2

Part Circuit

SK _A3

Part Circuit

SK _A4

Ansteuerspannungsstromkreis

SK _A5

Ansteuerspannungsstromkreis

S ₁

switching contact

S ₂

switching contact

S ₃

switching contact

S ₄

switching contact

S ₅

switching contact

S ₆

switching contact

S ₇

switching contact

S ₈

switching contact

S ₉

switching contact

S ₁₀

switching contact

S ₁₁

switching contact

S ₁₂

switching contact

U ₁

driving voltage

U ₂

supply voltage

U ₃

supply voltage

U ₄

driving voltage

U ₅

driving voltage

VE

locking device

Claims (8)

1. Sliding door assembly (1) with at least one sliding leaf (2), that can be driven by a drive equipment (5) activated by a electronic control equipment,
   wherein the sliding door assembly (1) can be used in an escape and emergency route, in that the drive equipment (5) is implemented such that the sliding leaf (2) is opened in the presence of an emergency signal for enabling an escape route, and wherein the sliding door assembly (1) can be locked in at least one operational state by a locking equipment (VE),
   characterized in that
   the control equipment (SE) comprises at least one input (E₁, E₄, E₅) for at least one activating voltage (U1, U4, U5), wherein the activating voltage (U₁, U₄, U₅) can be connected by at least one activating voltage circuit (SK_A, SK_A4, SK_A5) to the input (E₁, E₄, E₅),
   wherein the activating voltage circuit (SK_A, SK_A4, SK_A5) comprises at least one switch contact, wherein the locking equipment (VE) is arranged in a locking circuit (SK_V) at which a power supply voltage (U₂, U₃) is present, wherein the locking circuit (SK_V) can be interrupted by a release equipment (8), wherein the locking circuit (SK_V) comprises at least one switch contact,
   wherein the release equipment (8) is present for unlocking the locking equipment (VE) and for opening the sliding leaf (2) in that the switch contact(s) of the locking circuit (SK_V) and the switch contact (S₁, S₂, S₁₁, S₁₂) of the activating voltage circuit (SK_A, SK_A4, SK_A5) can be actuated jointly by the release equipment (8), and wherein the release equipment (8) comprises an actuating equipment (9) that can be activated electrically and is provided with at least one input for an emergency signal and/or an actuating equipment (9) that can be actuated manually and is implemented as an emergency switch, and wherein a release relay (KF) which can be activated by a trigger signal (A_KF) is provided with which a temporary release of the locking equipment (VE) as well as a temporary activation of at least one of the inputs (E₄, E₅) can be effected.
2. Sliding door assembly according to Claim 1,
   characterized in that the release equipment (8) is implemented redundantly in that at least one component of the release equipment (8) is present at least twice, so that in the event of failure of one of these components, its function is taken over by another component of the same type.
3. Sliding door assembly according to Claim 1,
   characterized in that the release equipment (8) is of single-fault-safe implementation, so that the function of the release equipment (8) is still ensured even when one component malfunctions.
4. Sliding door assembly according to Claim 1,
   characterized in that the release equipment (8) is of self-monitoring implementation, in that a monitoring equipment is provided which monitors the functional capability of the release equipment (8).
5. Sliding door assembly according to Claim 1,
   characterized in that the control equipment (SE) is of self-monitoring implementation, in that a monitoring equipment is provided which monitors the functional capability of the control equipment (SE).
6. Sliding door assembly according to Claim 1,
   characterized in that the locking equipment (VE) can be operated according to the working current principle, i.e. that the locking equipment (VE) can be put into the locked state by the supply of electrical power.
7. Sliding door assembly according to Claim 1,
   characterized in that the release equipment (8) comprises at least one visual and/or audible indicating equipment to indicate actuation of the release equipment (8).
8. Sliding door assembly according to Claim 1,
   characterized in that the release equipment (8) comprises at least one signal output for the output of a signal indicating the actuation of the release equipment (8).

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