CH663406A5 - DOOR DRIVE DEVICE WITH LOCKING MECHANISM FOR ELEVATORS. - Google Patents

Abstract

1. Door drive device with locking mechanism for lifts, in which a cage door (33), which in the region of the floors is shape-lockingly connectable through a coupling mechanism with a shaft door (44), is movable by a drive, wherein the coupling mechanism consists of an entraining parallelogram linkage (11) borne at the cage door (33) and two respective spigots (12) fastened to each shaft door (44), the drive is disposed in a dead centre position when the cage door (33) is closed and the drive means of the door drive device (38) is driven by way of a step-down gear from a motor (34) arranged on the cage (31), characterized thereby, that a pawl (7), which is pivotably borne at the cage door (33) and rests against an abutment (23) arranged at the cage (31), is locked in a retaining position through a toggle lever (5), which at one end is pivotably borne at the entraining parallelogram linkage (11) and at the other end is connected through a strap (20) with the pawl (7), and is pressed into a release position through a control roller (9), which is rotatably borne at the toggle lever (5) and has run up on a fixed control cam (10) provided at the shaft door.

Description

The present invention relates to a door drive device with a locking mechanism for lifts, in which a car door which can be positively connected to a shaft door by a coupling mechanism can be moved by a drive in the area of the floors, the coupling mechanism comprising a driver parallelogram mounted on the car door and two each Each shaft door has a fixed pin, the drive is 45 when the car door is closed and the drive means of the door drive device is driven by a motor arranged on the car via a reduction gear.

With CH-PS 523 199, such a door drive device has become known, in which for the coupling 50 of the car door with a shaft door, a driver parallelogram arranged on the car door cooperates with two roller journals attached to the shaft door.

During the journey, an electric motor holds an actuation device in a dead center position in which the cabin door is kept closed and cannot be opened by passengers. The driver parallelogram assumes a compressed position so that it can pass through a floor with play between the roller journals of the shaft door when passing through a floor. When the two doors are coupled on a target floor, the driver parallelogram is pushed apart by the actuating device against the force of a spring until it rests on the roller journal. The cabin door and the shaft door are opened together by the further movement of the actuation device.

For safety reasons, the Kabi65 should be used in the event of a power failure when the cabin is on the same floor

The passenger can open the shaft door and the landing door manually, and if the cabin is outside this area, the cabin door must remain locked. Therefore, in the event of a power failure, on the one hand, the actuating device is automatically guided out of the dead center position by the force of the spring arranged on the driver parallelogram and, on the other hand, a locking lever arranged on the driver parallelogram and moved with the parallelogram cooperates with a stop attached to the elevator car. In the area of one floor, the cabin and shaft doors can thus be opened by hand, while outside this area, with the parallel parallelogram spread as far apart, the locking lever is at the stop and the cabin door cannot be opened.

A disadvantage of the locking mechanism of this door drive device is that under certain circumstances it would be theoretically possible to open the cabin door if it had to remain closed. If, for example, there is an elevator car outside the floor area in the event of a power failure, the car door can be opened for a short period of time after the actuating device has been moved out of the dead center position by the spring acting on the driver parallelogram and before the driver parallelogram is moved by the same spring into the maximally spread-out end position is pulled, at which the locking lever is against the stop.

Another known door locking device according to CH-PS 570 341 has a push crank drive, a door lock for the shaft door and a driver parallelogram, here called a spreading sword. The driver parallelogram consists of two parallel coupling rails and two articulated double levers mounted on the cabin door. The coupling rails are spread by a spring engaging them and pressed together by means of a lever of the push crank drive. The driver parallelogram works together with two pins arranged on the shaft door, one being fixed and the other being mounted on a pivotable angle lever and being movable to a limited extent. When the elevator car approaches a target floor, the compressed coupling rails move between the two pins. The door operating device put into operation releases the driver parallelogram. Due to the force of the associated spring, the spread driver parallelogram unlocks the shaft door lock in a first phase, against the force of another spring, in order to positively engage the two pins in a second phase. The cabin and shaft doors are opened together by the door operating device. It does not appear from the patent description whether the cabin door is locked in the closed position in the event of a power failure by means of separate locking by means of a dead center position of this drive linkage or not at all. If the lever arrangement with the cabin door closed is not in a dead center position in the event of a power failure and there is also no separate lock or a lock that unlocks in the event of a power failure, the cabin door can be moved in the area and also outside the area of the shaft door. If, on the other hand, the lever arrangement is in a dead center position when the car door is closed and there is a power failure, or if the car door has a separate locking mechanism that does not unlock in the event of a power failure, then the car door cannot be moved from the cabin in the event of a power failure.

The invention has for its object to propose a door drive device with a locking mechanism, which a common opening of cabin

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and shaft door permitted if the cabin is in the area of a floor access and passengers are clearly prevented from opening the cabin door if the cabin is outside a floor.

This object is achieved by the invention characterized in the claims.

The advantages achieved by the invention are essentially to be seen in the fact that the car door is only opened automatically or can be opened by hand by passengers if the elevator car is located in the area of one floor. Only in this area can the pawl of the cabin door be unlocked by the control cam arranged on the shaft doors and the control roller running on it. In all other positions, the latch remains locked and the cabin door cannot be opened.

On the accompanying drawings, an embodiment of the invention is shown, which is explained in more detail below. Show it:

1 is a view of a door drive device with a cabin sliding door and a lock of the cabin door,

2 is a plan view of the door drive device of FIG. 1 and a shaft door,

3 is a schematic representation of the various holding positions and the release position of the lock of the cabin door,

4 shows the view of the locking mechanism in a holding position with the maximum compressed parallelogram for the free passage of the elevator car through a floor,

5 shows the view of the locking mechanism with the driver parallelogram in the release position,

if the elevator car is in the area of a target floor, and

6 shows the view of the locking mechanism with the driver parallelogram in the stop position in the event of a power failure when the elevator car is outside the floor area.

1 and 2, 31 denotes an elevator car, the entrance 32 of which is closed by a one-piece car door 33. Above the car door 33, an electric motor 34 and a belt transmission 35 are mounted on the elevator car 31 on a support plate (not shown). The electric motor 34 and the belt transmission 35 are connected to one another with a drive belt 36. A drive roller 37 of the belt transmission 35 drives a drive belt 38 which is guided over two deflection wheels 45 and is connected to the cabin door 33 via a driving bracket 39 and a pivot point 40. For the uniform tensioning of the drive belt 38, two tensioning rollers 42 and 43 which are pivotally mounted about the axis of the belt transmission 35 and are connected to one another by a tension spring 41 are used. A driver parallelogram 11 is pivotably mounted on the cabin door 33 with two pivot points 4 in a certain range. A support 19 is arranged on the driver parallelogram 11. At a pivot point 6 of the support 19, an angle lever 5 is articulated, which has a control roller 9 and is connected to a pawl 7 via a bracket 20. The pawl 7 is rotatably supported at a pivot point 8 on a bracket 28 attached to the cabin door 33. The pawl 7 is in contact with a stop 23 arranged on the cabin 31. A shaft door 44 is arranged opposite the car door 33. On the shaft door 44 two driver pins 12, which cooperate with the driver parallelogram 11 of the cabin door 33, and a fixed control cam 10 for actuating the control roller 9 are fastened. The cabin door 33 is suspended from rollers 46 which run on a rail 47. A control roller 48 actuated by the movement of the driver parallelogram works together with a double lever 49 in order to guide the driver bracket 39 of the door drive from the dead center position when the cabin is at a standstill.

In Fig. 3, 1 denotes a schematically shown maximum compressed position of the driver parallelogram 11, in which the pawl 7 remains in a horizontal, locked position. With 2 is a position when coupling the driver parallelogram 11 with the coupling parts of the shaft door 44, namely before the control roller 9 runs onto the control cam 10 arranged on the shaft door, with T a release position after the control roller 9 runs onto the control curve 10 and with 3 a maximally spread position of the driver parallelogram 11, for example in the event of a power failure, if the elevator car is located outside the floor area. With 4 the two pivot points of a double lever 15 to the parallel parallelogram 11 are designated, while with 6 the different positions of the common pivot point of the support 19 or the angle lever 5 and 8 the pivot point of the pawl 7 are designated. The pins required for coupling between the cabin door and the shaft door and fastened to the shaft door are numbered 12.

In FIGS. 4 and 5, 4 denotes the points of rotation of the double lifts 15, which are fixed to the cabin door, for the driver parallelogram 11. The connection points between the coupling rails 13 and 14 and the double levers 15 are given the numbers 17 and 18. The control roller 48 is mounted on the upper double lever 15. One end of a tension spring 16 hinged to the cabin door at the other end is fastened to the driver parallelogram 11. On one coupling rail 13, the support 19 is fastened with the fulcrum 6 for the angle lever 5. The control roller 9 is rotatably mounted on the angle lever 5 at one end and the tab 20 is connected to an articulation point 21 at the other end. The tab 20 is connected to the pawl 7 with a second hinge point 22, which in turn is rotatably fastened to the bracket 28 arranged on the cabin door at the pivot point 8. A damping stop 25 for the pawl 7 is also attached to the bracket 28. Another damping stop 26 is provided on the pawl 7. On a further console 24 arranged on the elevator car, a stop 23 for holding the pawl 7 and a monitoring contact 27 are provided, which is opened or closed by a bridge 29 attached to the pawl 7. 5, the control roller 9 rests on one of the control cam 10 arranged on the shaft doors.

In FIG. 6, 4 again denotes the pivot points of the double levers 15, which are fixed to the cabin door, for the driver parallelogram 11. The driver parallelogram 11 consists of the two coupling rails 13, 14, the two double levers 15 and the tension spring 16. The connection points of the double levers 15 with the coupling rails 13 and 14 are designated 17 and 18. The control roller 48 is mounted on the upper double lever 15. The support 19, which carries the angle lever 5, is fastened to the coupling rail 13. The control roller 9 is arranged on the angle lever 5 and the tab 20 is arranged with the articulation point 21. The tab 20 is connected to the pawl 7 at the second hinge point 22. The pawl 7 is rotatably attached to the bracket 28 arranged on the cabin door with the fulcrum 8. The console 28 also carries a damping stop 25. Another damping stop 26 is provided on the pawl 7. On a further console 24 arranged on the cabin there is a stop 23 for the holder

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the pawl 7 and a monitoring contact 23 is provided, which is opened or closed by a bridge 29 attached to the pawl 7.

In Fig. 3 the three possible fixed positions of the driver parallelogram 11 and the associated latching device are shown schematically. The position shown in FIG. 1 is taken up by the device while the elevator car is moving, in which the parallelogram 11 of the driver is held in a compressed position by the door drive device turned into a dead center position. This position also corresponds to the device shown in FIG. 4. In this position, the cabin door also remains closed and locked and cannot be opened by passengers. When the elevator car drives past a landing door in the floor area, the compressed parallelogram 11 travels through without contact between the pins 12 of the landing door. The position shown in FIG. 2 corresponds to the release position also shown in FIG. 5 when the elevator car is located in the area of a floor. If the elevator car approaches a target floor, the door drive device is driven approx. 25 cm before the flush position of the car floor and floor and is brought out of the dead center position. The driver parallelogram 11 engages between the two pins 12 attached to the shaft door. The control roller 9 runs on the fixed cam 10 also arranged on the shaft door and the angle lever 5 lifts the pawl 7 on one side by its rotary movement and on the other side tilts it from the locked holding position into the release position. At the same time, the monitoring contact 27 is opened. The cabin door can open when the door drive device continues to move and also takes the shaft door with it due to the parallelogram 11 of the driver 12 which grips between the pins 12. The same position 2 is assumed if the elevator car is in the area of one floor in the event of a power failure. The door drive device is guided by the tension spring 16 of the driver parallelogram 11 from position 1 to position 2, wherein the control roller 9 comes to rest on the control cam 10 during this movement sequence and the pawl is guided on the lock by the further movement of the driver parallelogram. Likewise, the control roller 48 of the driver parallelogram 11 presses the double lever 49 up on one side, whereby the other side is pressed down together with the driver bracket 39 and the door drive is guided out of the dead center position. For the

Passengers can now open the coupled cabin and shaft doors by hand. The position shown in FIG. 3 corresponds to the maximally spread position of the driver parallelogram 11, which is also shown in FIG. 6. It is only adopted if the elevator car is outside the area of one floor in the event of a power failure. The door drive device is in turn guided by the tension spring 16 of the driver parallelogram 11 from position 1 to position 3. Since the control roller 9 cannot run onto the control cam 10 outside the floor area, the pawl 7 remains locked and the monitoring contact 27 is closed; the cabin door cannot be opened.

From FIG. 3 it can further be seen that a locked position of the pawl 7 is assigned to all positions of the driver parallelogram 11 when the control roller 9 does not run onto the control cam 10. Only in the area of the floors, where the control cam 10 arranged on the shaft doors unlocks the pawl 7 via the control roller 9 and opens the monitoring contact 27, is it possible to open the cabin door together with the associated shaft door, be it automatically by the door drive device. normally or by the passengers by hand in the event of a breakdown caused by a power failure. The angle lever 5 and the tab 20 have the task of keeping the pawl 7 locked outside the regions of the control cams 10 at each spread position of the driver parallelogram 11. The control roller 9, which is rotatably mounted on the angle lever 5, must never assume a position which would allow the control curve 10 to be undershot and must not touch the control curve 10 when passing through the floors.

It is readily conceivable to provide another holding device for the cabin door instead of a latch. For example, a pivotable stop could be mounted at the upper pivot point 4 of the driver parallelogram 11, which is held in a movement path by the lever linkages 5, 20, which is within the effective range of a counter-stop attached to the elevator car and which, when the control roller 9 runs onto the control cam 10 is pivoted away from this trajectory by lever linkage.

Instead of the one-part sliding door indicated in the example, a two-part telescopic door or a two-part centrally opening sliding door can, for example, also be equipped with the door drive device shown.

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Claims (3)

663 406 2nd PATENT CLAIMS 1. Door drive device with locking mechanism for lifts, in which a car door (33) which can be positively connected to a shaft door (44) by a coupling mechanism can be moved by a drive in the area of the floors, the coupling mechanism consisting of a on the car door (33) mounted parallelogram (11) and two pegs (12) each fastened to each shaft door (44), the drive when the car door (33) is closed is in a dead center position and the drive means of the door drive device (38) is driven by a motor (34) arranged on the cabin (31) via a reduction gear, characterized in that a stop (23) pivotally mounted on the cabin door (33) on a stop (23) arranged on the cabin (31) ) The pending latch (7) is locked in a holding position by an angle lever (5) pivotally mounted on the driver parallelogram (11) on the one hand and on the other hand by a bracket (20) connected to the latch (7) and rotatably mounted on the angle lever (5) a control roller (9) that has run onto a fixed control cam (10) provided on the shaft door is pressed into a release position. 2. Door drive device according to claim 1, characterized in that on the pawl (7) delimiting the release position 25 of the pawl (7) and on a bracket attached to the cabin door (28) limiting the stop position of the pawl (7) damping stop ( 26.25) are arranged. 3. Door drive device according to claim 1, characterized in that a monitoring contact (27) which interacts with a contact bridge (29) arranged on the pawl 30 (7) and controls the holding position and the release position of the pawl (7) is arranged on the cabin. 35