Elevator systems are in widespread use for carrying passengers between various levels in buildings, for example. Access to an elevator car requires that elevator car doors open when the car is at a landing at which a passenger desires to board the elevator car, for example. Each landing includes hoistway doors that move with the elevator car doors between open and closed positions.
The elevator car doors and the hoistway doors have locks that prevent the doors from being improperly opened. The elevator car door lock typically includes a relatively expensive mechanism. For example, the elevator car door lock may include a solenoid to move the lock between a locked and unlocked condition. In addition to the component cost of typical mechanisms, door locks tend to increase the cost of maintaining an elevator system. It is believed that elevator door system components, such as the locks, account for approximately 50% of elevator maintenance requests and 30% of callbacks. One contributing factor to such issues is the way in which typical elevator car door locks are designed.
An illustrative example embodiment of an elevator door lock includes a latch that is moveable between a locking position and a released position. The latch includes a locking surface configured to engage a stop when the latch is in the locking position. A magnet is situated to magnetically attract a portion of the latch to selectively move the latch from the locking position into the released position
In an example embodiment having at least one feature of the elevator door lock of the previous paragraph, the locking surface is near a first end of the latch, the portion of the latch that is magnetically attracted by the magnet is near a second end of the latch, and the latch pivots about a pivot axis as the latch moves between the locking position and the released position.
In an example embodiment having at least one feature of the elevator door lock of any of the previous paragraphs, a mass of the latch is greater near the second end, gravity biases the second end in a downward direction to move the latch into the locking position, and the magnet attracts the portion against the bias of gravity to move the latch into the released position.
In an example embodiment having at least one feature of the elevator door lock of any of the previous paragraphs, the magnet is supported for movement relative to the latch between a first position and a second position, the latch is in the locking position when the magnet is in the first position, the magnet attracts the portion of the latch when the magnet is in the second position, and the latch is in the released position when the magnet is in the second position.
In an example embodiment having at least one feature of the elevator door lock of any of the previous paragraphs, the magnet moves in one direction between the first position and the second position, and the latch moves in a different direction between the locking position and the released position.
In an example embodiment having at least one feature of the elevator door lock of any of the previous paragraphs, the magnet moves in a horizontal direction between the first position and the second position, and the portion of the latch moves in a vertical direction.
In an example embodiment having at least one feature of the elevator door lock of any of the previous paragraphs, the magnet is a first distance from the portion of the latch when the magnet is in the first position, the magnet is a second distance from the portion of the latch when the magnet is in the second position, and the second distance is shorter than the first distance.
An illustrative example embodiment of an elevator door assembly includes the elevator door lock of any of the previous paragraphs, a door, and a door mover configured to move the door between open and closed positions. The magnet is associated with the door mover for movement between a first position and a second position. The magnet does not attract the portion of the latch when the magnet is in the first position. The latch is in the locking position when the magnet is in the first position. The magnet attracts the portion of the latch when the magnet is in the second position and the latch is in the released position when the magnet is in the second position.
In an example embodiment having at least one feature of the elevator door assembly of the previous paragraph, the stop is situated in a fixed position. The locking surface of the latch engages the stop when the latch is in the locking position. The door is prevented from movement out of the closed position when the locking surface engages the stop, and the magnet attracts the portion of the latch to move the locking surface away from the stop when the magnet is in the second position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the magnet is supported on at least one guide and the magnet moves along the guide as the magnet moves between the first position and the second position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the guide comprises at least one rail including a low friction material and the magnet slides along the low friction material.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the magnet moves in a horizontal direction between the first position and the second position, and the portion of the latch moves in a vertical direction as the latch moves between the locking position and the released position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the latch is supported for pivotal movement relative to the stop between the locking position and the released position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the locking surface is near a first end of the latch, the portion of the latch that is magnetically attracted by the magnet is near a second end of the latch, and a mass of the latch is greater near the second end. Gravity urges the second end in a downward direction to move the latch into the locking position when the magnet is in the first position, and the magnet attracts the portion against the bias of gravity to move the latch into the released position when the magnet is in the second position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the latch is supported for movement with the door as the door moves between the open position and the closed position, the magnet moves with a corresponding portion of the door mover as the door moves between the open position and the closed position, and the portion of the latch remains attracted by the magnet during movement of the door between the open position and the closed position.
In an example embodiment having at least one feature of the elevator door assembly of any of the previous paragraphs, the magnet comprises a permanent magnet, and the portion of the latch comprises a ferromagnetic material.
The various features and advantages of at least one disclosed example embodiment will become apparent to those skilled in the art from the following detailed description. The drawings that accompany the detailed description can be briefly described as follows.
At least one of the doors 22 includes a door lock 30 that prevents the doors 22 from being improperly opened. A vane 32 couples the elevator car doors 22 to hoistway doors (not illustrated) in a known manner so that the hoistway doors move together with the elevator car doors 22 when the door lock 30 is unlocked and the door mover 24 causes door movement.
The door lock 30 is supported on the door hanger 28 of the corresponding door 22. As shown in
The door lock 30 includes a magnet 42 that interacts with a portion 44 of the latch 34 to selectively move the latch 34 from the locking position into a released position, which is shown in
In the illustrated example embodiment, the magnet 42 is associated with the belt 26 of the door mover 24 so the magnet moves with the belt 26. The magnet 42 moves between a first position relative to the latch 34 as shown in
When the doors 22 are closed and the magnet 42 is in the first position shown in
Gravity urges the latch 34 into the locking position because of the imbalance between the mass of the first and second ends of the latch 34. The latch 34 is supported on the door hanger 28 to pivot about a pivot axis 48 relative to the door hanger 28. The latch 34 pivots about the pivot axis 48 as it moves between the locking position (
When the door mover 24 initiates opening the doors 22, the belt 26 moves (to the left according to the drawings) and the magnet 42 moves from the first position shown in
Movement of the belt 26, the position of the magnet 42 relative to the belt 26, and the position of the portion 44 relative to the door hanger are timed so that some initial movement of the belt 26 causes the latch 34 to move from the locking position shown in
The timing of moving the latch 34 into the released position is coordinated with expansion of the vane 32, which operates a hoistway door lock (not illustrated) to unlock the hoistway door at approximately the same time that the elevator car doors 22 are unlocked. The vane 32 is shown in
In the illustrated example embodiment, the magnet 42 remains in the overlapping, aligned position relative to the portion 44 shown in
As the doors 22 return to the closed position, the belt 26 and the magnet 42 move from the positions shown in
The guide 46 provides support beneath the mass of the magnet 42 to avoid strain on the belt 26. The guide 46 also facilitates expected and smooth movement of the magnet 42. Another feature of the guide 46 is that it facilitates decoupling the magnet 42 and the portion 44 because the guide 46 provide some spacing between the magnet 42 and the portion 44. Without any spacing, the magnet 42 and the portion 44 would directly contact each other, making separation less efficient.
In some embodiments, the guide 46 is made of a material that provides sound dampening to avoid an audible clicking noise as the magnet 42 draws the portion 44 toward the magnet 42 as the latch 34 pivots into the released position.
Elevator door locks like the illustrated example embodiment provide a robust and efficient door lock that is less prone to needing adjustment or repair over the service life of the elevator car 20. Elevator door locks consistent with this description can also be less expensive than other types of locks.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed examples may become apparent to those skilled in the art that do not necessarily depart from the essence of this invention. The scope of legal protection given to this invention can only be determined by studying the following claims.
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Entry |
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Machine translation of the Description of WO 2018037613 A1, Mar. 2018 (Year: 2018). |
Extended European Search Report for Application No. EP 21 19 3650 dated Dec. 13, 2021. |
Number | Date | Country | |
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20220063962 A1 | Mar 2022 | US |