JP2017088368A - Elevator apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an elevator apparatus capable of reliably closing a space between a landing side sill and a car side sill by a closing member having an appropriate dimensional shape even when a clearance dimension thereof fluctuates by constituting the closing member closing the space in a swingable manner in an interval direction of the space.SOLUTION: An elevator apparatus has a closing member 35 closing a space generated between a car side sill 31 and a landing side sill 32. The closing member 35 is constituted so as to be able to be movable between a closing position closing the space and a retreat position. The closing member 35 is driven by a link mechanism 41 in association with opening/closing operation of a car door. Further, the closing member 35 is coupled to a bracket 51 provided at a link mechanism 41 side via an elastic member 52, and is supported in a swingable manner in an interval direction between the car side sill 31 and the landing side sill 32.

Description

  An embodiment of the present invention relates to an elevator apparatus having a structure for closing a gap formed between a landing side and a sill on a car side provided at an entrance to a car.

  In an elevator system in which a car installed in the hoistway of a building moves up and down between floors to carry people and luggage, there is a constant distance between the landings on each floor and the car in order to raise and lower the car. The gap is provided. For this reason, when the car stops landing at the landing and the door of the entrance is opened, a gap (also referred to as running clearance) is generated between the landing side sill and the car side sill. The gap between the sills is dangerous because it causes a person to stumble or a wheel such as a wheelchair or a bogie falls. In addition, small articles such as keys and cards may fall into the pit from the sill gap, making recovery difficult.

  In view of this, there has conventionally been proposed a member that is provided with a closing member for closing the gap between the sills and is operated so as to close the sill gap when the door is opened (see, for example, Patent Document 1).

JP 2009-286504 A

  In such a mechanism that closes the running clearance when the door is opened, the clearance dimension is not necessarily a constant value but varies depending on the installation error of each floor. Also, the clearance dimension varies depending on the back and forth of the car guide device and the car vertical deviation when getting on and off. For this reason, it is necessary for the conventional blocking member to be arranged with a gap corresponding to this variation, and it has not been possible to apply a blocking member having an appropriate size and shape.

  The present invention supports a blocking member that closes the gap between the platform-side sill and the car-side sill so as to be slidable in the gap interval direction, so that even when the clearance dimension varies, An object of the present invention is to provide an elevator apparatus that can be properly closed by a member.

  The elevator apparatus according to an embodiment of the present invention includes a car-side sill that guides a car door provided at an entrance of a car along its opening and closing direction, and each floor on which the car can land, A plane that can block a gap formed between a sill on the landing side that guides a landing door provided at the entrance to the cradle along the opening and closing direction and a sill on the car side and the sill on the landing side. A closing member having a shape and configured to be movable between a closing position where the gap is closed and a retreat position at the lower part of the sill on the car side, and the opening operation of the car door connected to the closing member Accordingly, the closing member is moved from the retracted position to the closing position, and the closing member is moved from the closing position to the retracted position when the car door is closed, the closing member, and the driving mechanism side. Bracket provided on By connecting the door, characterized in that the closing member and a resilient member for supporting the arm can swing in the spacing direction of the sill of the car side and the hall side.

  According to the above-described configuration, even if there is a change in the clearance dimension of the gap generated between the platform side sill and the car side sill when the door is opened, the gap interval at the closing position where the closing member protrudes to the landing side. It can be swung in the direction and is urged in the direction of the landing by an elastic member, retracting when pushed in the direction of the car, and returning to the original closing position when the pushing force is removed, so the running clearance is narrower than usual In this case, it is pushed back to the car side, and when it is wide, it projects to the closing position, so that a closed state with a higher sealing degree can be obtained.

It is a figure showing the whole elevator device composition concerning one embodiment of the present invention. It is the front view which looked at the door part of the car in one embodiment of the present invention from the landing side. It is a perspective view which shows the relationship between the operation member by the side of the car door in one Embodiment of this invention, and a drive mechanism. It is a top view which shows the relationship between the closing member in a retracted position, and a drive mechanism. It is a top view which shows the relationship between the closing member in a closing position, and a drive mechanism. It is a side view which shows the relationship between the closing member in a closing position, and the sill on the car side and the landing side. It is a side view which shows the relationship between the blocking member in a retracted position, and the sill on the car side and the landing side. FIG. 8 is a side view in which some components are removed from FIG. It is a figure which takes out and shows a stopper part. It is a figure which shows an example of the bending part provided in the leaf | plate spring. It is a figure which shows the other example of the bending part provided in the leaf | plate spring. It is the front view which looked at the door part of the cage | basket | car in other embodiment of this invention from the landing side. It is a perspective view which shows the relationship between the operation member by the side of the car door in another embodiment of this invention, and a drive mechanism.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  First, the overall configuration of the elevator apparatus will be described with reference to FIG. As shown in FIG. 1, the elevator apparatus 1 includes a passenger car 4 and a counterweight 5 disposed in a hoistway 3. Above the hoistway 3 is provided a machine room 6 in which a hoisting machine 7 for driving a main rope 9 and a control device 8 are installed. The control device 8 controls the entire elevator device 1 and controls the hoisting machine 7 in accordance with a landing call or a car call so that the car 4 is landed on the floor where the call was made.

  A so-called machine room-less elevator device in which the hoisting machine 7 and the control device 8 are downsized and provided in the upper part in the hoistway 3 without providing the machine room 6 may be used.

  In this elevator apparatus 1, an entrance 12 that leads to a car 4 in the hoistway 3 is provided at a landing 11 provided on each floor of the building, and a landing door 2 is provided at the entrance 12. The landing door 2 is engaged with the side of the car door 25 provided at the entrance / exit 24 of the car 4 via an interlock mechanism (not shown) when the car 4 is landed, and interlocks with the opening and closing of the car door 25. Opens and closes.

  FIG. 2 is a front view of the car door 25 provided at the entrance of the car 4 as seen from the landing 11 side. The car door 25 is a so-called double-opening method in which two door panels 25a and 25b (only the door contact portions are shown, and the other portions are not shown) are opened to the left and right in the drawing different from each other. These two door panels 25a, 25b are connected to door opening / closing mechanisms 27 formed on both sides of the entrance / exit 24 of the car 4, and are driven in the left-right direction in the figure by the door opening / closing mechanism 27 to open / close.

  The door opening / closing mechanism 27 is a well-known one and is not directly related to the present invention, so the description of the structure is omitted. However, the power of the motor (not shown) causes the two door panels 25a and 25b to interlock with each other, It is driven in the left-right direction along the guide rail to open and close.

  A car-side sill 31 is provided at the entrance / exit part of the car 4, and the two door panels 25a and 25b constituting the car door 25 described above are slidably guided along the opening and closing direction thereof. . This car-side sill 31 is provided at the lower side of the car doorway 24, and the guide grooves formed on the upper surface thereof engage with the lower ends of the two door panels 25a and 25b, respectively. Guide in the opening and closing direction.

  As shown in FIGS. 6 to 8, a sill 32 is provided on the platform 11 side with respect to the sill 31 on the car side. The platform side sill 32 is disposed opposite to one side surface (the left side surface in FIGS. 6 to 8) of the car side sill 31 with a predetermined distance. A guide groove is also formed on the upper surface of the threshold 32 on the landing side, and guides the landing door 2 shown in FIG. 1 so as to be slidable along the opening and closing direction.

  The landing-side door 2 is also of a double-opening type having two door panels (not shown). As described above, when the car 4 reaches the landing 11, it engages with the car door 25 and the car door. 25 opens and closes together. That is, the landing door 2 has two door panels locked in a closed state by an interlock mechanism (not shown) when the car 4 is not landing, and when the car 4 is landing, the car 4 The locking state described above is released by engaging with an engaging member (not shown) on the side, and the door is opened and closed together with the car door 25.

  When the car 4 reaches the predetermined floor, the gap (running clearance) shown in FIGS. 6 to 8 is generated between the car-side sill 31 and the landing-side sill 32 as described above. In the embodiment of the present invention, a closing member 35 is provided to close this gap.

  As shown in FIG. 2, the closing member 35 is divided into left and right. This divided part is a part where the car-side sill 31 passes over an interlock mechanism (specifically, a roller part engaged with the car side) provided on the landing side when the car 4 is raised and lowered, In order to allow passage of the interlock mechanism, it is divided with a space left and right. That is, even if the car goes up and down with the closing member extended to the closing position, the landing-side interlock mechanism passes through the space formed in the divided portion of the extended closing member 35. The extended closing member and the interlock mechanism do not collide.

  In the sill 32 on the landing side, a block that protrudes and freely fits into the divided space portion is provided in a state of facing the sill 31 on the car side. This block is provided integrally with the sill 32 on the landing side facing the car-side sill 31 and facing the divided space portion of the closing member 35. Therefore, when the car 4 is landed and the landing side sill 32 and the car side sill 31 face each other, the blocks provided on the landing side sill 32 protrude and loosely fit into the divided space portion. It becomes a state. For this reason, the space generated in the divided portion is substantially blocked by the block that is loosely fitted in the divided portion, and it is possible to prevent small items from falling from the space of the divided portion.

  The upper surface of the closing member 35 is located below the upper surfaces of the car-side sill 31 and the landing-side sill 32 as shown in FIGS. Moreover, the planar shape is formed in the shape dimension which can block | close the clearance gap between the thresholds 31 and 32 as shown in FIG. That is, it has a planar shape consisting of a length that is slightly larger than the entrance of the car-side doorway 24 shown in FIG. 2 and a width that is slightly larger than the gap between the sills 31 and 32 shown in FIGS.

  Moreover, the cross section is made into a vertically long shape, and the recessed part 35a is formed in the opposing part with the illustration right side surface of the threshold 32 on the landing side. The recess 35a is provided to avoid the head of a screw 36a provided on the right side of the sill 32 on the landing side. The screw 36a is for attaching the plate 36 that partitions the space between the lower floors. Further, a chamfer 35 b is applied to the upper corner portion of the closing member 35.

  The closing member 35 may be made of metal or resin, but a resin material may be used in consideration of workability and buffering properties with other components.

  The closing member 35 is slidable between a closing position where the gap between the sills 31 and 32 shown in FIG. 6 is closed and a retreat position where the sill 31 is retracted to the lower part of the car-side sill 31 shown in FIGS. 8 is a diagram in which some parts are removed from FIG. 7 to make it easier to see the state of the closing member 35 at the retracted position in FIG. 8. The drive mechanism 41, which will be described later, slides between the closing position and the retracted position as the car door 25 is opened and closed.

  The closing member 35 is attached to a bracket 51 provided on the drive mechanism 41 side via a leaf spring-like elastic member (hereinafter referred to as a leaf spring) 52. Therefore, the closing member 35 is supported by the leaf spring 52 so as to be swingable in the interval direction between the car-side sill 31 and the landing-side sill 32 (which is also the front-rear direction with respect to the sliding movement direction). The bracket 51 and the leaf spring 52 are also divided at the same portion as the closing member 35, and support the divided corresponding portions of the closing member 35.

  As shown in FIG. 3, the drive mechanism 41 is configured to be able to engage with the operation member 42 on the car door 25 side as the car door 25 opens and closes. Then, the force received from the operating member 42 by the engagement with the operating member 42 is converted into the sliding movement direction of the closing member 35, and the closing member 35 is driven in the sliding movement direction.

  In this embodiment, as shown in FIGS. 4 and 5, the drive mechanism 41 is rotatable through four links 46, 47, 48, 49 and one end of each of these links and a connecting shaft 50. And a bracket 51 connected thereto. The four links 46, 47, 48, and 49 are rotatably supported via a pivot shaft 45 on a support member 44 provided on the car 4 side.

  Out of these four links, the inner links 47 and 48 are for connection driving, and the other end thereof is connected to a connection rod 55 via a connection shaft 54. The inner links 47 and 48 and the connecting rod 55 interlock the closing member 35 with the left and right parts of the bracket 51 and the leaf spring 52 associated therewith. To do. A tension spring 56 is stretched between the right end of the connecting rod 55 in the figure and the support member 44, and applies a force in a direction to translate the bracket 51 toward the support member 44 to the drive mechanism 41.

  A base end portion of a lever 58 is integrally attached to the pivot shaft 45 of the link 46 constituting the drive mechanism 41. An operating pin 59 is erected at the tip of the lever 58. As shown in FIG. 3, the upper side surface of the operation pin 59 is disposed so as to be engageable with an operation member 42 provided integrally on the door panel 25 a side of the car door 25. That is, the operating pin 59 abuts and engages with the operating member 42 by opening the car door 25 to a predetermined open position, and the lever 58 and the pivot shaft 45 integral therewith are rotated counterclockwise in the drawing. Let

  Due to this rotation, the link 46 integral with the pivot shaft 45 and the other links 47, 48, 49 connected via the bracket 51 also rotate counterclockwise in the figure against the tension of the tension spring 56. Move. By the operation of the drive mechanism 41, the closing member 35 supported on the bracket 51 and the upper portion thereof via the leaf spring 52 is moved from the retracted position shown in FIGS. 4, 7, and 8 to the closing member shown in FIGS. It is drawn out to the position.

Here, the tension spring 56 described above is finally connected to the closing member 35 via the drive mechanism 41, the bracket 51, and the like. The tension spring 56 applies a force in a direction to return the closing member 35 to the retracted position shown in FIGS. 4, 7, and 8 via the drive mechanism 41. Accordingly, the tension spring 56 functions as a return spring that returns the closing member 35 to the retracted position (hereinafter referred to as the return spring 56).
In this way, the drive mechanism 41 opens the car door 25 to a predetermined open position, so that the operating pin 59 is engaged with the operating member 42 on the car door 25 side as shown in FIG. In response to the movement force in the opening direction of 25, the closing member 35 in the retracted position is slid to the closing position against the spring force of the return spring 56.

  For the above-described sliding movement of the closing member 35, a stopper 61 for stopping the closing member 35 at the closing position and the retracted position is provided on the support member 44 as shown in FIGS. FIG. 9 shows the stopper 61 taken out. The stopper 61 has a U-shaped member fixedly installed on the support member 44, and is provided with a cushioning material 62 such as rubber on both inner side surfaces thereof, and is extended from the bracket 51 on the closing member 35 side therebetween. A contact member 63 having an L-shaped cross section is disposed.

  With this configuration, the abutting member 63 extended from the bracket 51 abuts on both inner side surfaces of the U-shaped member of the stopper 61, so that the sliding movement of the closing member 35 is correctly stopped at the closing position and the retracted position. be able to. The cushioning material 62 such as rubber may be provided on one or both of the stopper 61 and the contact member 63.

  Of the pivot shaft 45 that constitutes the drive mechanism 41, the one disposed at the right end in FIGS. 2 and 3 is integral with the lever 58, and the operating pin 59 erected on the lever 58 is provided on the side of the car door 25. This is a rotating shaft that rotates by abutting engagement with the operating member 42. As shown in FIGS. 6 to 8, a torsion spring 65 is provided on the rotation shaft, and a rotational force is provided against the rotation direction due to the engagement with the operation member 42.

  With this configuration, the operating pin can always be returned to the correct position when the operating pin 59 is not engaged with the operating member 42.

  In the above configuration, when the car door 25 is in the closed state, the operation member 42 on the car door 25 side shown in FIG. 3 is not in contact with and engaged with the operation pin 59 on the drive mechanism 41 side. 41 does not receive the acting force from the car door 25 side. Therefore, the closing member 35 and the bracket 51 supporting the closing member 35 are pulled back to the support member 44 side by the tension of the return spring 56 shown in FIG. 4, and the closing member 35 is moved to the car side sill as shown in FIGS. It is in the retracted position below 31.

  When the car 4 reaches the landing and the car door 25 opens and moves to a predetermined open position, the actuating member 42 provided on the door panel 25a side becomes an actuating pin 59 constituting the drive mechanism 41. The lever 58, which is in contact and engaged and provided with the operating pin 59 by the opening operation force of the door panel 25a, is rotated about the pivot shaft 45 counterclockwise in the figure.

  By this operation, the drive mechanism 41 rotates in the same direction against the tension of the return spring 56, and the bracket 51 and the closing member 35 supported by the bracket 51 are extended from the state of FIG. 4 to the state of FIG. Therefore, the closing member 35 slides to the left in the drawing from the retracted position at the lower part of the car-side sill 31 shown in FIGS. 9 and 10, and reaches the closing position shown in FIG. The front end portion (the left end portion in the drawing) of the closing member 35 is in contact with the right side surface in the drawing of the sill 32 on the landing side to close the gap between the sills 31 and 32.

  Here, the gap interval between the sills 31 and 32, that is, the clearance dimension is not a constant value as described above, but differs depending on the installation error of each floor. Also, the dimensions fluctuate due to the back and forth play of the car guide device and the car vertical displacement when getting on and off.

  In the embodiment of the present invention, the closing member 35 is attached to the bracket 51 via the leaf spring 52 so as to be swingable back and forth in the slide movement direction. That is, the closing member 35 can swing back and forth at the protruding position (closing position). Moreover, it is urged | biased by the board | plate spring 52 (illustration left), and when it pushes in a cage | basket | car direction (illustration right), it will retract, and when the pushing force is removed, it will return to the original closing position. .

  With this structure, when the running clearance is narrower than usual, it can be pushed back to the car side (right side in the figure), and when it is wide, it can protrude to the closing position, so it is possible to obtain a closed state with a higher degree of sealing. Become.

  Thus, when the closing member 35 is in the closing position, it closes the gap between the sills 31 and 32, so that small items do not fall into the pit from this gap and can be easily collected. Moreover, since the upper surface of the closing member 35 is located below the upper surfaces of the sills 31 and 32, the load of the object located on the sills 31 and 32 is not applied to the closing member 35, and the load is applied. Damage to the support portion of the closing member 35 can be prevented.

  When the load on the car 4 changes greatly in the state where the gap is closed by the closing member 35, the car 4 may temporarily rise slightly. Even if such a temporary raising of the car 4 occurs, the chamfer 35b is applied to the upper corner portion of the closing member 35 and the closing member 35 is supported by the leaf spring 52. Does not occur.

  For example, when a passenger who has been in a full state in the car 4 goes down at a time, the car 4 slightly rises temporarily. At this time, the closing member 35 located at the closing position shown in FIG. 6 is also lifted and brought into contact with the lower side portion of the sill 32 on the landing side. However, since the chamfer 35b is applied to the upper corner portion of the closing member 35 facing the lower side portion of the sill 32 on the landing side, the contact force of this portion is weakened, and damage due to contact can be prevented. In addition, since the closing member 35 is supported by the leaf spring 52, the leaf spring 52 is also bent in the vertical direction at the time of contact as described above. Can prevent damage due to contact.

  On the other hand, when the car door 25 is closed and moved to a predetermined door closing position, the operating member 42 provided on the door panel 25 a side is separated from the operating pin 59 constituting the drive mechanism 41. Therefore, the force applied to the drive mechanism 41 via the operating pin 59 is released, and the drive mechanism 41 causes the pivot shaft 45 to rotate in the clockwise direction in the figure by the tension of the return spring 56, so that the bracket 51 and this The closing member 35 supported on the back is pulled back from the state of FIG. 5 to the state of FIG. Accordingly, the closing member 35 slides to the right in the drawing from the closing position shown in FIG. 6 to the retracted position below the car-side sill 31 shown in FIGS.

  In this way, the closing member 35 slides from the retracted position to the closing position by the link mechanism that operates in response to the moving force in the opening direction of the car door, and the spring force of the return spring during the closing operation of the car door To slide from the closing position to the retracted position. In this sliding movement, the stopper 61 can correctly stop the closing member 35 at both the closing position and the retracted position. For this reason, it is possible to reliably prevent the blocking member from overrunning without stopping at the normal position and colliding with other parts to be damaged. Even if an overrun occurs, the closing member 35 is supported by the leaf spring 52, so that an impact caused by a collision with another component can be buffered by the bending of the leaf spring 52, and damage to the component can be prevented. .

  In addition, when the leaf | plate spring 52 bends, a clearance gap may arise in the junction part with the bracket 51, and if dust etc. are pinched | interposed into this clearance gap, it will be considered that it cannot return to an original shape. Therefore, it is advisable to provide guards such as caulking and gabber installation in advance for the portion where this gap may occur.

  Further, the leaf spring 52 has a function of bending in the vertical direction as described above. For this reason, in order to generate the vertical deflection more effectively, at least one bent portion in the horizontal direction is formed in the vertical intermediate portion of the leaf spring 52 to generate a vertical spring force. Also good. As this bending part, as shown in FIG. 10, the leaf | plate spring 52 may be bend | folded in a cross-sectional square shape, or you may curve in a semicircle as shown in FIG. Furthermore, a plurality of square-shaped bends may be made continuous in the vertical direction, or a plurality of semicircles may be made continuous in the vertical direction to form an S-shaped curve.

  If formed in this way, the leaf spring 52 can be effectively deflected also in the longitudinal direction parallel to the plate surface.

  In the above-described embodiment, the drive mechanism 41 is configured to always pull the bracket 51 back to the support member 44 side by the tension of the return spring (tension spring) 56 as shown in FIGS. 4 and 5. Instead of the return spring 56, an operating spring 66 that generates a repulsive force may be provided between the support member 44 and the right end of the link 47 so that a force for feeding the bracket 51 in the direction of FIG. Good. That is, the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 are connected to the operating spring 66 via the drive mechanism 41, and the moving force to the closing position shown in FIGS. Will always be received.

  In this case, when the drive mechanism 41 is in the door closed end position shown in FIG. 12 where the car door 25 is completely closed, as shown in FIG. 13, the operating pin 59 is an operating member provided on the door panel 25a side. 72 is engaged. For this reason, the drive mechanism 41 is held in the state of FIG. 6 in which the repulsive force of the operating spring 66 is stored. That is, the closing member 35 is held at the retracted position shown in FIGS.

  On the other hand, when the car door 25 is opened and the door panel 25a starts the door opening operation from the door closing end in FIG. 12, the operation member 72 on the car door 25 side is moved to the right in the state shown in FIG. Therefore, the engaging force with the operating member 72 is released. For this reason, each link 46, 47, 48, 49 constituting the drive mechanism 41 is rotated counterclockwise in the figure around the pivot shaft 45 by the repulsive force of the operating spring 66. By the operation of the drive mechanism 41, the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 are extended from the state of FIG. 4 to the state of FIG. That is, the closing member 35 slides from the retracted position shown in FIGS. 7 and 8 to the closing position shown in FIG.

  On the other hand, when the car door 25 is closed from the fully open state, the door panel 25a closes to the vicinity of the door closing end, whereby the operation member 72 engages with the operation pin 59 on the drive mechanism 41 side as shown in FIG. For this reason, the lever 58 having the operating pin 59 is driven in the clockwise direction in the drawing by the force in the closing direction of the door panel 25a. That is, the driving mechanism 41 returns the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 from the state of FIG. 5 to the state of FIG. 4 by the force in the closing direction of the door panel 25a. That is, the closing member 35 slides from the closing position shown in FIG. 6 to the retracted position shown in FIGS.

  Thus, the drive mechanism 41 is disengaged from the actuating member 72 when the door opening operation starts from the door closing end of the car door 25, and therefore, the driving mechanism 41 moves to the closing position of the closing member 35 due to the repulsive force of the actuating spring 66. Allow sliding movement. Further, as the car door 25 moves to the door closing end, it engages with the actuating member 72 on the car door 25 side, receives the moving force of the car door 25, and slides the closing member 35 at the closing position to the retracted position. Let

  That is, when the car door 25 starts to open, the closing member 35 immediately moves to the closing position. When the car door 25 is closed, the closing member 35 moves from the closing position to the retracted position immediately before the car door 25 is fully closed. For this reason, even if a passenger or cargo enters and exits while the car door 25 is open or closed, the closing member 35 is in a state of closing the gap between the sills 31 and 32, so that small items may fall from the gap. Can be reliably prevented.

  Note that the engagement portions of the driving mechanism 41 with the operation members 42 and 72 on the car door 25 side, that is, the positions where the operation pins 59 are installed, are the front and rear openings 24 of the car 4 that is opened and closed by the car door 25. Outside.

  In the above-described embodiment, each of the drive mechanisms 41 is configured to mechanically drive the door opening / closing force by converting the door opening / closing force into the moving force of the member 35. It is not limited to such a mechanical drive mechanism. For example, a drive mechanism that electrically detects that the door has reached a predetermined open or closed position, operates an actuator such as a motor, and moves the closing member may be used.

  In the above embodiment, the drive mechanism 41 slides the closing member 35 from the retracted position to the closing position. However, the present invention supports the closing member that closes the gap between the sill on the landing side and the sill on the car side so as to be slidable in the interval direction of the gap, so that even if there is a variation in the clearance dimension, an appropriate dimensional shape is obtained. It is an object to accurately close with a closing member, and this can be applied to, for example, a moving operation by moving the closing member in the lateral direction while raising the closing member from the retracted position below. Therefore, the drive mechanism may be configured to move not only by sliding the closing member but also in combination with vertical movement and horizontal movement.

  Although several embodiments of the present invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Elevator apparatus 2 ... Platform door 3 ... Hoistway 4 ... Car 25 ... Car door 27 ... Door opening / closing mechanism 31 ... Car side threshold 32 ... Platform side threshold 35 ... Blocking member 41 ... Drive mechanism 42, 72 ... Operation Member 51 ... Bracket 52 ... Elastic member 56 ... Return spring 59 ... Actuating pin 61 ... Stopper 62 ... Buffer material 63 ... Abutting member 65 ... Torsion spring 66 ... Actuating spring

  An embodiment of the present invention relates to an elevator apparatus having a structure for closing a gap formed between a landing side and a sill on a car side provided at an entrance to a car.

  In an elevator system in which a car installed in the hoistway of a building moves up and down between floors to carry people and luggage, there is a constant distance between the landings on each floor and the car in order to raise and lower the car. The gap is provided. For this reason, when the car stops landing at the landing and the door of the entrance is opened, a gap is generated between the landing side sill and the car side sill. The gap between the sills is dangerous because it causes a person to stumble or a wheel such as a wheelchair or a bogie falls. In addition, small articles such as keys and cards may fall into the pit from the sill gap, making recovery difficult.

  In view of this, there has conventionally been proposed a member that is provided with a closing member for closing the gap between the sills and is operated so as to close the sill gap when the door is opened (see, for example, Patent Document 1).

JP 2009-286504 A

  In such a mechanism that closes the running clearance when the door is opened, the clearance dimension is not necessarily a constant value but varies depending on the installation error of each floor. Also, the clearance dimension varies depending on the back and forth of the car guide device and the car vertical deviation when getting on and off. For this reason, it is necessary for the conventional blocking member to be arranged with a gap corresponding to this variation, and it has not been possible to apply a blocking member having an appropriate size and shape.

The present invention, multiplication Ri member closing close the gap between the field side of the sill and the car side of the sill, by oscillating rotatably supported in the spacing direction of the gap, even if there is variation in the clearance dimension, suitable dimensions It is an object of the present invention to provide an elevator apparatus that can be accurately closed by the closing member.

The elevator apparatus according to an embodiment of the present invention includes a car-side sill that guides a car door provided at an entrance of a car along its opening and closing direction, and each floor on which the car can land, the landing door provided the entrance to the car, closing the sill ride Ri field side guides along the opening and closing direction, the gap formed between the threshold of the threshold and ride Ri field side of the cage-side it has a shape which is Ru can, a plugging member movably configured between a closing position and a retracted position closes the gap, is coupled to the closing member, with the opening operation of the car door, A driving mechanism that moves the closing member from the retracted position to the closing position, and moves the closing member from the closing position to the retracted position in accordance with the closing operation of the car door; and the closing member, provided on the driving mechanism side. The bracket is connected to Characterized by comprising an elastic member for oscillating supporting the timber in the interval direction of the sill of the car side and the ride Ri field side.

According to the configuration described above, closing position even in the event of a change in the clearance dimension of the gap, which projects to the Ri field side multiplied by the closing member which occurs between the sill and the car side of the sill of the door opening during the ride Ri play side and swingable spacing direction of the gap in the biases in the Ri field direction multiplication by the elastic member, retraction and pushed to the car direction, pressing force is removed, since the structure returns to the original closing position, When the running clearance is narrower than usual, it is pushed back to the car side, and when it is wide, it projects to the closing position, so that a closed state with a higher degree of sealing can be obtained.

It is a figure showing the whole elevator device composition concerning one embodiment of the present invention. It is the front view which looked at the door part of the car in one embodiment of the present invention from the landing side. It is a perspective view which shows the relationship between the operation member by the side of the car door in one Embodiment of this invention, and a drive mechanism. It is a top view which shows the relationship between the closing member in a retracted position, and a drive mechanism. It is a top view which shows the relationship between the closing member in a closing position, and a drive mechanism. It is a side view which shows the relationship between the closing member in a closing position, and the sill on the car side and the landing side. It is a side view which shows the relationship between the blocking member in a retracted position, and the sill on the car side and the landing side. FIG. 8 is a side view in which some components are removed from FIG. It is a figure which takes out and shows a stopper part. It is a figure which shows an example of the bending part provided in the leaf | plate spring. It is a figure which shows the other example of the bending part provided in the leaf | plate spring. It is the front view which looked at the door part of the cage | basket | car in other embodiment of this invention from the landing side. It is a perspective view which shows the relationship between the operation member by the side of the car door in another embodiment of this invention, and a drive mechanism.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  First, the overall configuration of the elevator apparatus will be described with reference to FIG. As shown in FIG. 1, the elevator apparatus 1 includes a passenger car 4 and a counterweight 5 disposed in a hoistway 3. Above the hoistway 3 is provided a machine room 6 in which a hoisting machine 7 for driving a main rope 9 and a control device 8 are installed. The control device 8 controls the entire elevator device 1 and controls the hoisting machine 7 in accordance with a landing call or a car call so that the car 4 is landed on the floor where the call was made.

  A so-called machine room-less elevator device in which the hoisting machine 7 and the control device 8 are downsized and provided in the upper part in the hoistway 3 without providing the machine room 6 may be used.

  In this elevator apparatus 1, an entrance 12 that leads to a car 4 in the hoistway 3 is provided at a landing 11 provided on each floor of the building, and a landing door 2 is provided at the entrance 12. The landing door 2 is engaged with the side of the car door 25 provided at the entrance / exit 24 of the car 4 via an interlock mechanism (not shown) when the car 4 is landed, and interlocks with the opening and closing of the car door 25. Opens and closes.

FIG. 2 is a front view of the car door 25 provided at the entrance of the car 4 as seen from the landing 11 side. The car door 25 is a so-called double-opening method in which two door panels 25a and 25b (only the door contact portions are shown, and the other portions are not shown) are opened to the left and right in the drawing different from each other. These two doors panels 25a, 25b are connected to the door opening and closing Organization constructed on both sides of the doorway 24 of the car 4, more driven in the drawing the left-right direction in the door opening and closing Organization, and is opened and closed .

Incidentally, the door opening and closing Organization are well known and does not relate directly to the present invention is the structure description is omitted, the power of the motor (not shown), two doors panels 25a, 25b and in conjunction with each other, It is driven in the left-right direction along the guide rail to open and close.

  A car-side sill 31 is provided at the entrance / exit part of the car 4, and the two door panels 25a and 25b constituting the car door 25 described above are slidably guided along the opening and closing direction thereof. . This car-side sill 31 is provided at the lower side of the car doorway 24, and the guide grooves formed on the upper surface thereof engage with the lower ends of the two door panels 25a and 25b, respectively. Guide in the opening and closing direction.

  As shown in FIGS. 6 to 8, a sill 32 is provided on the platform 11 side with respect to the sill 31 on the car side. The platform side sill 32 is disposed opposite to one side surface (the left side surface in FIGS. 6 to 8) of the car side sill 31 with a predetermined distance. A guide groove is also formed on the upper surface of the threshold 32 on the landing side, and guides the landing door 2 shown in FIG. 1 so as to be slidable along the opening and closing direction.

The ride Batobira 2 also intended casement system with door panels but the two not shown, as described above, when the car 4 is implanted in landing 11, it engages with the car door 25, the car door 25 opens and closes. That is, the landing door 2 has two door panels locked in a closed state by an interlock mechanism (not shown) when the car 4 is not landing, and when the car 4 is landing, the car 4 The locking state described above is released by engaging with an engaging member (not shown) on the side, and the door is opened and closed together with the car door 25.

When the car 4 is landed to a predetermined floor, as described above, between the field side of the threshold 32 Ri-ride the sill 31 of the car side, a gap (running clearance) shown in FIGS. 6 to 8 occurs. In the embodiment of the present invention, a closing member 35 is provided to close this gap.

As shown in FIG. 2, the closing member 35 is divided into left and right. This divided part is a part where the car-side sill 31 passes over an interlock mechanism (specifically, a roller part engaged with the car side) provided on the landing side when the car 4 is raised and lowered, In order to allow passage of the interlock mechanism, it is divided with a space left and right. In other words, event, even if the lift is car while being fed to a position closing the closing member, the interlocking mechanism of the ride Ri field side, passes through the formed divided portion of the closing member 35 fed out space Therefore, the extended closing member does not collide with the interlock mechanism.

The ride Ri field side of the threshold 32, at the opposite state of the threshold 31 of the car side, blocks loosely fitted is provided to protrude to the divided space portions. This block, multiplication Ri field side of the sill 32, opposed to the sill 31 of the car side and is integrally provided at the portion facing the divided spatial portion of the blocking member 35. Therefore, the car 4 is landed, ride Ri when the threshold 32 and the car side of the sill 31 of the field side faces protrudes ride Ri field side of the sill 32 in a space portion provided block is divided into Will be loosely fitted. For this reason, the space generated in the divided portion is substantially blocked by the block that is loosely fitted in the divided portion, and it is possible to prevent small items from falling from the space of the divided portion.

The upper surface of the closing member 35, as shown in FIGS. 6 to 8, positioned below the upper surface of the car side of the sill 31 and ride Ri field side of the threshold 32. Further, its shape of the gap between the threshold 31 and 32 are formed in a geometry that can be closed as shown in Figure 6. That is, a somewhat greater length than the frontage of the car side of the doorway 24 as shown in FIG. 2, ing and a slightly larger width than the gap threshold 31 and 32 shown in FIGS. 6 to 8.

  Moreover, the cross section is made into a vertically long shape, and the recessed part 35a is formed in the opposing part with the illustration right side surface of the threshold 32 on the landing side. The recess 35a is provided to avoid the head of a screw 36a provided on the right side of the sill 32 on the landing side. The screw 36a is for attaching the plate 36 that partitions the space between the lower floors. Further, a chamfer 35 b is applied to the upper corner portion of the closing member 35.

  The closing member 35 may be made of metal or resin, but a resin material may be used in consideration of workability and buffering properties with other components.

  The closing member 35 is slidable between a closing position where the gap between the sills 31 and 32 shown in FIG. 6 is closed and a retreat position where the sill 31 is retracted to the lower part of the car-side sill 31 shown in FIGS. (FIG. 8 is a view in which some parts are removed from FIG. 7 to make it easier to see the state of the closing member 35 in the retracted position). The drive mechanism 41, which will be described later, slides between the closing position and the retracted position as the car door 25 is opened and closed.

The closing member 35 is attached to a bracket 51 provided on the drive mechanism 41 side via a leaf spring-like elastic member (hereinafter referred to as a leaf spring) 52. Therefore closing member 35, the leaf spring 52, is pivotal supported to be able to (also in the longitudinal direction with respect to the slide moving direction) spacing direction of the car side of the sill 31 and ride Ri field side of the threshold 32. The bracket 51 and the leaf spring 52 are also divided at the same portion as the closing member 35, and support the divided corresponding portions of the closing member 35.

  As shown in FIG. 3, the drive mechanism 41 is configured to be able to engage with the operation member 42 on the car door 25 side as the car door 25 opens and closes. Then, the force received from the operating member 42 by the engagement with the operating member 42 is converted into the sliding movement direction of the closing member 35, and the closing member 35 is driven in the sliding movement direction.

  In this embodiment, as shown in FIGS. 4 and 5, the drive mechanism 41 is rotatable through four links 46, 47, 48, 49 and one end of each of these links and a connecting shaft 50. And a bracket 51 connected thereto. The four links 46, 47, 48, and 49 are rotatably supported via a pivot shaft 45 on a support member 44 provided on the car 4 side.

  Out of these four links, the inner links 47 and 48 are for connection driving, and the other end thereof is connected to a connection rod 55 via a connection shaft 54. The inner links 47 and 48 and the connecting rod 55 interlock the closing member 35 with the left and right parts of the bracket 51 and the leaf spring 52 associated therewith. To do. A tension spring 56 is stretched between the right end of the connecting rod 55 in the figure and the support member 44, and applies a force in a direction to translate the bracket 51 toward the support member 44 to the drive mechanism 41.

  A base end portion of a lever 58 is integrally attached to the pivot shaft 45 of the link 46 constituting the drive mechanism 41. An operating pin 59 is erected at the tip of the lever 58. As shown in FIG. 3, the upper side surface of the operation pin 59 is disposed so as to be engageable with an operation member 42 provided integrally on the door panel 25 a side of the car door 25. That is, the operating pin 59 abuts and engages with the operating member 42 by opening the car door 25 to a predetermined open position, and the lever 58 and the pivot shaft 45 integral therewith are rotated counterclockwise in the drawing. Let

  Due to this rotation, the link 46 integral with the pivot shaft 45 and the other links 47, 48, 49 connected via the bracket 51 also rotate counterclockwise in the figure against the tension of the tension spring 56. Move. By the operation of the drive mechanism 41, the closing member 35 supported on the bracket 51 and the upper portion thereof via the leaf spring 52 is moved from the retracted position shown in FIGS. 4, 7, and 8 to the closing member shown in FIGS. It is drawn out to the position.

Here, the tension spring 56 described above is finally connected to the closing member 35 via the drive mechanism 41, the bracket 51, and the like. The tension spring 56 applies a force in a direction to return the closing member 35 to the retracted position shown in FIGS. 4, 7, and 8 via the drive mechanism 41. Accordingly, the tension spring 56 functions as a return spring that returns the closing member 35 to the retracted position (hereinafter referred to as the return spring 56).
In this way, the drive mechanism 41 opens the car door 25 to a predetermined open position, so that the operating pin 59 is engaged with the operating member 42 on the car door 25 side as shown in FIG. In response to the movement force in the opening direction of 25, the closing member 35 in the retracted position is slid to the closing position against the spring force of the return spring 56.

  For the above-described sliding movement of the closing member 35, a stopper 61 for stopping the closing member 35 at the closing position and the retracted position is provided on the support member 44 as shown in FIGS. FIG. 9 shows the stopper 61 taken out. The stopper 61 has a U-shaped member fixedly installed on the support member 44, and is provided with a cushioning material 62 such as rubber on both inner side surfaces thereof, and is extended from the bracket 51 on the closing member 35 side therebetween. A contact member 63 having an L-shaped cross section is disposed.

  With this configuration, the abutting member 63 extended from the bracket 51 abuts on both inner side surfaces of the U-shaped member of the stopper 61, so that the sliding movement of the closing member 35 is correctly stopped at the closing position and the retracted position. be able to. The cushioning material 62 such as rubber may be provided on one or both of the stopper 61 and the contact member 63.

  Among the pivot shafts 45 constituting the drive mechanism 41, the one integrated with the lever 58 disposed at the right end of FIGS. 2 and 3 is provided with an operation pin 59 provided upright on the lever 58 on the side of the car door 25. This is a rotating shaft that rotates by abutting engagement with the member 42. As shown in FIGS. 6 to 8, a torsion spring 65 is provided on the rotation shaft, and a rotational force is provided against the rotation direction due to the engagement with the operation member 42.

  With this configuration, the operating pin can always be returned to the correct position when the operating pin 59 is not engaged with the operating member 42.

  In the above configuration, when the car door 25 is in the closed state, the operation member 42 on the car door 25 side shown in FIG. 3 is not in contact with and engaged with the operation pin 59 on the drive mechanism 41 side. 41 does not receive the acting force from the car door 25 side. Therefore, the closing member 35 and the bracket 51 supporting the closing member 35 are pulled back to the support member 44 side by the tension of the return spring 56 shown in FIG. 4, and the closing member 35 is moved to the car side sill as shown in FIGS. It is in the retracted position below 31.

  When the car 4 reaches the landing and the car door 25 opens and moves to a predetermined open position, the actuating member 42 provided on the door panel 25a side becomes an actuating pin 59 constituting the drive mechanism 41. The lever 58 provided with the operating pin 59 is rotated counterclockwise around the pivot shaft 45 by the opening engagement force of the door panel 25a.

By this operation, the drive mechanism 41 rotates in the same direction against the tension of the return spring 56, and the bracket 51 and the closing member 35 supported by the bracket 51 are extended from the state of FIG. 4 to the state of FIG. Accordingly, the closing member 35 slides to the left in the drawing from the retracted position below the car-side sill 31 shown in FIGS. 7 and 8 , and reaches the closing position shown in FIGS . Then, the front end (shown left end) of the closing member 35 is in contact with the right side surface of the sill 32 of squared Ri field side, close the gap between the sill 31.

  Here, the gap interval between the sills 31 and 32, that is, the clearance dimension is not a constant value as described above, but differs depending on the installation error of each floor. Also, the dimensions fluctuate due to the back and forth play of the car guide device and the car vertical displacement when getting on and off.

  In the embodiment of the present invention, the closing member 35 is attached to the bracket 51 via the leaf spring 52 so as to be swingable back and forth in the slide movement direction. That is, the closing member 35 can swing back and forth at the protruding position (closing position). Moreover, it is urged | biased by the board | plate spring 52 (illustration left), and when it pushes in a cage | basket | car direction (illustration right), it will retract, and when the pushing force is removed, it will return to the original closing position. .

  With this structure, when the running clearance is narrower than usual, it can be pushed back to the car side (right side in the figure), and when it is wide, it can protrude to the closing position, so it is possible to obtain a closed state with a higher degree of sealing. Become.

  Thus, when the closing member 35 is in the closing position, it closes the gap between the sills 31 and 32, so that small items do not fall into the pit from this gap and can be easily collected. Moreover, since the upper surface of the closing member 35 is located below the upper surfaces of the sills 31 and 32, the load of the object located on the sills 31 and 32 is not applied to the closing member 35, and the load is applied. Damage to the support portion of the closing member 35 can be prevented.

  When the load on the car 4 changes greatly in the state where the gap is closed by the closing member 35, the car 4 may temporarily rise slightly. Even if such a temporary raising of the car 4 occurs, the chamfer 35b is applied to the upper corner portion of the closing member 35 and the closing member 35 is supported by the leaf spring 52. Does not occur.

  For example, when a passenger who has been in a full state in the car 4 goes down at a time, the car 4 slightly rises temporarily. At this time, the closing member 35 located at the closing position shown in FIG. 6 is also lifted and brought into contact with the lower side portion of the sill 32 on the landing side. However, since the chamfer 35b is applied to the upper corner portion of the closing member 35 facing the lower side portion of the sill 32 on the landing side, the contact force of this portion is weakened, and damage due to contact can be prevented. In addition, since the closing member 35 is supported by the leaf spring 52, the leaf spring 52 is also bent in the vertical direction at the time of contact as described above. Can prevent damage due to contact.

  On the other hand, when the car door 25 is closed and moved to a predetermined door closing position, the operating member 42 provided on the door panel 25 a side is separated from the operating pin 59 constituting the drive mechanism 41. Therefore, the force applied to the drive mechanism 41 via the operating pin 59 is released, and the drive mechanism 41 causes the pivot shaft 45 to rotate in the clockwise direction in the figure by the tension of the return spring 56, so that the bracket 51 and this The closing member 35 supported on the back is pulled back from the state of FIG. 5 to the state of FIG. Accordingly, the closing member 35 slides to the right in the drawing from the closing position shown in FIG. 6 to the retracted position below the car-side sill 31 shown in FIGS.

  In this way, the closing member 35 slides from the retracted position to the closing position by the link mechanism that operates in response to the moving force in the opening direction of the car door, and the spring force of the return spring during the closing operation of the car door To slide from the closing position to the retracted position. In this sliding movement, the stopper 61 can correctly stop the closing member 35 at both the closing position and the retracted position. For this reason, it is possible to reliably prevent the blocking member from overrunning without stopping at the normal position and colliding with other parts to be damaged. Even if an overrun occurs, the closing member 35 is supported by the leaf spring 52, so that an impact caused by a collision with another component can be buffered by the bending of the leaf spring 52, and damage to the component can be prevented. .

  In addition, when the leaf | plate spring 52 bends, a clearance gap may arise in the junction part with the bracket 51, and if dust etc. are pinched | interposed into this clearance gap, it will be considered that it cannot return to an original shape. Therefore, it is advisable to provide guards such as caulking and gabber installation in advance for the portion where this gap may occur.

  Further, the leaf spring 52 has a function of bending in the vertical direction as described above. For this reason, in order to generate the vertical deflection more effectively, at least one bent portion in the horizontal direction is formed in the vertical intermediate portion of the leaf spring 52 to generate a vertical spring force. Also good. As this bending part, as shown in FIG. 10, the leaf | plate spring 52 may be bend | folded in a cross-sectional square shape, or you may curve in a semicircle as shown in FIG. Furthermore, a plurality of square-shaped bends may be made continuous in the vertical direction, or a plurality of semicircles may be made continuous in the vertical direction to form an S-shaped curve.

  If formed in this way, the leaf spring 52 can be effectively deflected also in the longitudinal direction parallel to the plate surface.

  In the above-described embodiment, the drive mechanism 41 is configured to always pull the bracket 51 back to the support member 44 side by the tension of the return spring (tension spring) 56 as shown in FIGS. 4 and 5. Instead of the return spring 56, an operating spring 66 that generates a repulsive force may be provided between the support member 44 and the right end of the link 47 so that a force for feeding the bracket 51 in the direction of FIG. Good. That is, the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 are connected to the operating spring 66 via the drive mechanism 41, and the moving force to the closing position shown in FIGS. Will always be received.

  In this case, when the drive mechanism 41 is in the door closed end position shown in FIG. 12 where the car door 25 is completely closed, as shown in FIG. 13, the operating pin 59 is an operating member provided on the door panel 25a side. 72 is engaged. For this reason, the drive mechanism 41 is held in the state of FIG. 6 in which the repulsive force of the operating spring 66 is stored. That is, the closing member 35 is held at the retracted position shown in FIGS.

  On the other hand, when the car door 25 is opened and the door panel 25a starts the door opening operation from the door closing end in FIG. 12, the operation member 72 on the car door 25 side is moved to the right in the state shown in FIG. Therefore, the engaging force with the operating member 72 is released. For this reason, each link 46, 47, 48, 49 constituting the drive mechanism 41 is rotated counterclockwise in the figure around the pivot shaft 45 by the repulsive force of the operating spring 66. By the operation of the drive mechanism 41, the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 are extended from the state of FIG. 4 to the state of FIG. That is, the closing member 35 slides from the retracted position shown in FIGS. 7 and 8 to the closing position shown in FIG.

  On the other hand, when the car door 25 is closed from the fully open state, the door panel 25a closes to the vicinity of the door closing end, whereby the operation member 72 engages with the operation pin 59 on the drive mechanism 41 side as shown in FIG. For this reason, the lever 58 having the operating pin 59 is driven in the clockwise direction in the drawing by the force in the closing direction of the door panel 25a. That is, the driving mechanism 41 returns the bracket 51 and the closing member 35 supported on the bracket 51 via the leaf spring 52 from the state of FIG. 5 to the state of FIG. 4 by the force in the closing direction of the door panel 25a. That is, the closing member 35 slides from the closing position shown in FIG. 6 to the retracted position shown in FIGS.

  Thus, the drive mechanism 41 is disengaged from the actuating member 72 when the door opening operation starts from the door closing end of the car door 25, so that the closing member 35 is moved to the closing position by the repulsive force of the actuating spring 66. Allow sliding movement. Further, as the car door 25 moves to the door closing end, it engages with the actuating member 72 on the car door 25 side, receives the moving force of the car door 25, and slides the closing member 35 at the closing position to the retracted position. Let

  That is, when the car door 25 starts to open, the closing member 35 immediately moves to the closing position. When the car door 25 is closed, the closing member 35 moves from the closing position to the retracted position immediately before the car door 25 is fully closed. For this reason, even if a passenger or cargo enters and exits while the car door 25 is open or closed, the closing member 35 is in a state of closing the gap between the sills 31 and 32, so that small items may fall from the gap. Can be reliably prevented.

  Note that the engagement portions of the driving mechanism 41 with the operation members 42 and 72 on the car door 25 side, that is, the positions where the operation pins 59 are installed, are the front and rear openings 24 of the car 4 that is opened and closed by the car door 25. Outside.

  In the above-described embodiment, each of the drive mechanisms 41 is configured to mechanically drive the door opening / closing force by converting the door opening / closing force into the moving force of the member 35. It is not limited to such a mechanical drive mechanism. For example, a drive mechanism that electrically detects that the door has reached a predetermined open or closed position, operates an actuator such as a motor, and moves the closing member may be used.

  In the above embodiment, the drive mechanism 41 slides the closing member 35 from the retracted position to the closing position. However, the present invention supports the closing member that closes the gap between the sill on the landing side and the sill on the car side so as to be slidable in the interval direction of the gap, so that even if there is a variation in the clearance dimension, an appropriate dimensional shape is obtained. It is an object to accurately close with a closing member, and this can be applied to, for example, a moving operation by moving the closing member in the lateral direction while raising the closing member from the retracted position below. Therefore, the drive mechanism may be configured to move not only by sliding the closing member but also in combination with vertical movement and horizontal movement.

  Although several embodiments of the present invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Elevator apparatus 2 ... Platform door 3 ... Hoistway 4 ... Car 25 ... Car door 31 ... Car side sill 32 ... Platform side sill 35 ... Closure member 41 ... Drive mechanism 42, 72 ... Actuation member 51 ... Bracket 52 ... Elastic member 56 ... Return spring 59 ... Operating pin 61 ... Stopper 62 ... Cushioning material 63 ... Abutting member 65 ... Torsion spring 66 ... Operating spring

Claims (9)

A sill on the side of the car that guides the car door provided at the entrance of the car along the opening and closing direction,
A sill on the landing side that guides the landing door provided at the entrance to the passenger car on each floor on which the passenger car can land, along the opening and closing direction thereof,
It has a planar shape that can close the gap generated between the car-side sill and the landing-side sill, and it moves between the closed position that closes the gap and the retreat position of the lower part of the car-side sill. A closing member configured to be possible;
Connected to the closing member, the closing member is moved from the retracted position to the closing position with the opening operation of the car door, and the closing member is moved from the closing position to the retracting position with the closing operation of the car door. A drive mechanism;
An elastic member that connects the closing member and a bracket provided on the drive mechanism side, and supports the closing member so as to be slidable in the direction of the spacing between the car side and the landing side sill,
An elevator apparatus comprising:   The elevator apparatus according to claim 1, wherein the elastic member has a leaf spring shape, and at least one bent portion in the horizontal direction is formed at a middle portion in the vertical direction to generate a vertical elastic force.   The elevator apparatus according to claim 2, wherein the bent portion has a cross-sectional shape or a semicircular shape.   The elevator apparatus according to claim 2 or 3, wherein a cover that covers a gap generated by the curvature of the leaf spring is provided at a joint portion between the leaf spring and the bracket. The elevator apparatus as described in.   The elevator apparatus according to any one of claims 1 to 4, wherein an upper surface of the closing member is positioned below an upper surface of the car-side and landing-side sills.   6. The stopper according to claim 1, further comprising a stopper that stops the movement of the closing member at the closing position and the retracted position by contact with an abutting member provided on the side of the closing member. Elevator device.   The elevator apparatus according to claim 6, wherein a cushioning material is provided on either the stopper or the contact member.   The elevator apparatus according to any one of claims 1 to 7, wherein an upper corner portion of the closing member is chamfered.   The recessed part which avoids the head of the screw for plate attachment which partitions off the space between the lower floors provided in this side surface is formed in the part of the said closing member facing the side surface of the said sill on the landing side. The elevator apparatus of any one of Claim 8.

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