JP2013049553A - Elevator door system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an elevator door system capable of performing a smooth door opening/closing operation even if engaging devices are not properly assembled by a simple structure.SOLUTION: The elevator door system includes an engager provided at a riding door panel, a pair of engaging blades that are engaged with the engager when an elevator sits on a floor and are mutually provided in parallel with passenger car door panels, further includes an engaging member fixed to one engaging blade, an engaging blade roller that guides a displacement in the elevating direction of one engaging blade while moving in the opening or closing direction, an engaging blade roller guide member that defines the position in the elevating direction of the engaging blade roller, a displacement transmission mechanism that transmits the displacement of the engaging blade roller to the engaging member, and the displacement transmission mechanism includes an elastic body that expands and contracts in the elevating direction.

Description

  An embodiment of the present invention relates to an elevator door including an engagement device for engaging a car door and a landing door when the car is landing and transmitting the opening / closing driving force of the car door to the landing door. Relates to the device.

  In the elevator hall of the building, an entrance for getting in and out of the elevator car is provided, and a sliding door type door is installed at this entrance. The landing door is normally closed, and opens and closes in response to a driving force from the door of the car when the car that moves up and down the hoistway reaches the elevator hall and stops. Further, the landing door is provided with a lock mechanism, which locks the landing door when the car door is closed and unlocks the landing door when the car door starts to open. The landing door lock mechanism includes an engagement element.

  An engagement portion is provided between the car door and the landing door for transmitting the driving force of the car door to the landing door. An engaging device for an elevator door device is constituted by the engaging portion and the engaging member for the landing door. When the car reaches the landing floor and stops, the engaging portion of the car door and the engaging element of the landing door engage to transmit the driving force of the car door to the landing door. The engaging part may also have a function of operating the lock mechanism. The engaging portion includes a pair of engaging blades that are provided on the car door, are supported by a pair of parallel link members, and extend in the vertical direction so as to change the interval width while maintaining parallelism. ing.

  On the other hand, when installing the elevator, the dimensions between the engaging blades when the car door is closed, the distance between the engaging blades and the engaging element at that time, and the dimensions between the engaging blades when the car door is opened are predetermined. Adjust to the value of. When the engagement device is not properly assembled, for example, when the dimension between the engagement blades when the car door is opened is adjusted to be narrower than the diameter of the engagement element on the landing, a pair of engagement devices. A force for closing the engagement blade is applied to the engagement blade roller included in the mechanism for changing the interval between the combination blades. This force causes distortion in members included in the engagement device such as the engagement blade and the engagement element. Such an excessive force acting on the engaging device may cause a bending moment to act on the bearing used in the connecting portion between the link member and the engaging blade, and the bearing may be damaged. When such a situation occurs, the smooth opening / closing operation of the door is hindered.

  Patent Document 1 discloses an elevator door device for solving such problems. The landing door of this device is operated with a roller-shaped first engaging element that transmits the driving force of the car door to the landing door and a lock mechanism that is displaced relative to the roller-shaped first engaging element. A roller-like second engaging element is provided. The car door has first and second engaging blades that move in parallel in an opening and closing direction that contact and separate from each other via a parallel link member provided with a bearing, and the pair of engaging blades approach each other. By closing the two engagement blades, the two engagement elements are clamped between the two engagement blades, the position of the second engagement element is held at the position where the lock mechanism is released, and the lock mechanism is operated by releasing the clamp. An engagement mechanism is provided. The device further includes a support member interposed between the engagement blade and the link member or between the link member and the car door, and the support member allows the bearing interposed in the connecting portion of the parallel link member. On the other hand, the bending moment is prevented from acting. However, the configuration of the disclosed apparatus is complicated, and there are concerns about durability because many sliding support members are used.

JP 2010-137958 A

  The present invention has been made in view of the above-described background, and has a simple structure and smooth door opening and closing operation without damaging members used for the door even when the engagement device is not properly assembled. It is an object of the present invention to provide an elevator door device that enables the above.

  An elevator door device according to an embodiment of the present invention includes at least one landing door panel that opens and closes an entrance of an elevator landing, and a first engagement member that is provided on any of the landing door panels so as to protrude toward the hoistway. The elevator car doorway is opened and closed, and the same number of car door panels as the car door panel, and the car door panel facing the car door panel provided with the first engagement element, are substantially mutually connected so as to protrude toward the car side. A link member mounting member is provided on a first door and a second blade that are provided in parallel and extend in the ascending / descending direction, and a car door panel provided with the first blade and the second blade. A pair of link members attached and connecting the first engagement blade and the second engagement blade are substantially parallel to each other. An elevator door device includes a linkage member fixed to one of a first engagement blade and a second engagement blade, an opening / closing direction of the engagement blade to which the linkage member is fixed, and moves together with the linkage member. An engagement blade roller that guides the displacement in the up and down direction, an engagement blade roller guide member that is provided on the car door panel and defines the position of the engagement blade roller in the up and down direction, and the displacement of the engagement blade roller is a linkage member A displacement transmission mechanism for transmitting, and a drive mechanism for interlockingly opening and closing the car door panel and the landing door panel when the car reaches the elevator hall and stops are further provided. The engaging blade roller guide member, the link member, the first engaging blade, and the second engaging blade are engaged with each other when the car stops on the elevator landing and stops and the landing door panel begins to open. The gap between the side plate portions of the blade and the second engagement blade is narrowed so that the blade contacts the first engagement element and moves in the engagement direction. The displacement transmission mechanism includes an elastic body that expands and contracts in the hoistway direction, and the elastic body is compressed by a predetermined amount in the elevating direction when the car door panel is completely closed.

It is the figure which looked at an example of the car door to which the embodiment of the door device which has the engagement device using the member included in the landing door lock mechanism is applied from the landing side outside the hoistway. FIG. 2 is an enlarged view of a portion including a car door side engaging portion of an example of the car door shown in FIG. 1. It is the figure which looked at an example of the landing door corresponding to an example of the car door shown in FIG. 1 from the hoistway side. It is a figure for demonstrating an example of the lock mechanism provided in a landing door. It is a figure showing the state which the car door side engaging part engaged with the landing door apparatus in embodiment of this invention. It is a figure for demonstrating an example of operation | movement of the locking mechanism provided in the landing door in embodiment of this invention. It is a figure which shows the relationship between the displacement amount of the raising / lowering direction of an engagement blade roller, and the clearance gap between engagement blades. It is a figure for demonstrating opening / closing operation | movement of a landing door. It is the figure which looked at an example of the landing door to which embodiment of the door apparatus which has an engaging device which does not use the member contained in a landing door lock mechanism is applied from the hoistway side. FIG. 10 is an enlarged view of a portion including an engagement member of an example of the landing door shown in FIG. 9. It is a perspective view for demonstrating the displacement transmission mechanism by 1st Embodiment provided in a passenger car door. It is a perspective view for demonstrating the displacement transmission mechanism by 2nd Embodiment provided in a passenger car door. It is a perspective view for demonstrating the displacement transmission mechanism by 3rd Embodiment provided in a passenger car door. It is a figure for demonstrating other embodiment.

  Hereinafter, an exemplary embodiment of the present invention will be described as appropriate with reference to the drawings. In the respective drawings, the same reference numerals are assigned to the same or corresponding parts, and redundant description is omitted.

(Outline of door device having an engagement device using members included in landing door lock mechanism)
First, some members of the landing door lock mechanism, which is provided at the landing door of the elevator landing floor and keeps the landing door closed when the car is not stopped on the landing floor, are connected to the elevator door. An outline of the configuration and operation of the door when used in an embodiment of the combined apparatus will be described with reference to FIGS. FIG. 1 shows an example of a door of a passenger compartment (car door) to which an embodiment of a door device having an engagement device using members included in a landing door lock mechanism is applied. It is the figure seen from the landing side outside a hoistway. FIG. 1 shows car door panels 102 and 104 of a so-called two-door double door type. However, the present invention does not depend on the double-opening method or the single-opening method, and does not depend on the number of doors. When it is confirmed that the car has arrived at the landing floor and stopped, the car door panels 102 and 104 are interlocked by the power of the car door motor 108 provided on the car via the car door belt 106. And open. The car door motor 108 and the car door belt 106 constitute a part of a drive mechanism that interlocks and opens and closes the car door panel and the hall door panel described later when the car reaches the elevator hall and stops. The car door panel 102 is provided with a car door side engaging portion 110 that transmits the movement of the car door panel 102 to a landing door provided on the landing floor. The car door side engaging portion 110 may be provided on either the car door panel 102 or the car door panel 104. However, in this specification and the accompanying drawings, the car door side engaging portion 110 is It is assumed that the car door panel 102 is provided.

  FIG. 2A is an enlarged view of FIG. 1 showing a portion including a car door side engaging portion 110 as an example of the car door shown in FIG. The car door side engaging portion 110 includes a pair of link members 202 and 204. The link members 202 and 204 are pivotably attached to the plate 206 fixed to the car door panel 102 by link portion attachment members 208 and 210, respectively. The link portion attachment members 208 and 210 are arranged so that their centers are on a straight line in the ascending / descending direction. The two link members 202 and 204 are respectively connected to doorcase side engaging blades (first engaging blades) 216 extending in the up-and-down direction at connecting portions 212a and 212b on the opening direction side of the car door panel 102, that is, the doorcase side. Connected to the door-side engagement blades (second engagement blades) 218 extending in the ascending / descending direction at the connecting portions 214a and 214b on the closing direction side of the car door panel 102, that is, the door contact side. . A bearing (not shown) is provided in each of the link member connecting portions 212a, 212b, 214a, and 214b, and the cab includes the link members 202 and 204, the first engagement blade 216, and the second engagement blade 218. The engagement device is operated smoothly. The first engagement blade 216 and the second engagement blade 218 are disposed in parallel with the elevator raising / lowering direction while projecting to the landing side. Further, as shown in FIG. 2A, the two link members 202 and 204 are in a plane parallel to the car door panel 102, and are in relation to the first engagement blade 216 and the second engagement blade 218. Are disposed obliquely. In the form shown in FIG. 2A, the right end portion of the link members 202 and 204 is located below the left end portion. When four points of the link member connecting portions 212a, 212b, 214b, and 214a are connected, a parallelogram is formed. Since the first engagement blade 216 and the second engagement blade 218 and the link members 202 and 204 are connected as described above, in the form shown in FIG. When a force for pushing up the blade 216 is applied, the connecting portions 212a and 212b move upward, and the connecting portions 214a and 214b move downward via the link members 202 and 204, so the second engaging blade 218 moves downward. Move to. In this case, since the first engagement blade 216, the second engagement blade 218, and the link members 202 and 204 are connected, the car door panel of the first engagement blade 216 and the second engagement blade 218 is connected. The interval in the opening / closing direction of 102 changes. This interval is narrowed when connected in the form as shown in FIG.

  As described above, the car door panel 102 is opened and closed by the power of the car door motor 108 provided on the car via the car door belt 106. A hanger rail 222 is fixed to the upper panel 220 of the car door above the car door panel 102 in parallel with the opening / closing direction of the car door. Car door suspension members 224a and 224b are fixed above the car door panel 102, and car door rollers 226a and 226b are provided above the car door suspension members 224a and 224b, respectively. The car door rollers 226 a and 226 b roll on the hanger rail 222. That is, the car door panel 102 opens and closes while being hung on the hanger rail 222 via the car door rollers 226a and 226b and the car door suspension members 224a and 224b. Similarly, the car door panel 104 opens and closes in conjunction with the car door panel 102 while being hung on the hanger rail 222 via the corresponding car door roller and the car door suspension member.

  On the upper part of the first engagement blade 216, an arm-like linkage member 228 extending to the door pocket side is fixed. An engagement blade roller guide member 230 is fixed to the upper panel 220 of the car door substantially in parallel with the opening / closing direction of the car door panel 102. The engaging blade roller 232 is provided such that the roller side surface is in contact with the engaging blade roller guide member 230. Accordingly, the position of the engagement blade roller 232 in the up-down direction is defined by the engagement blade roller guide member 230. The engagement blade roller 232 is connected to the linkage member 228 via a displacement transmission mechanism 234 symbolized by a spring in FIG. The displacement transmission mechanism 234 includes a fluid spring such as a coil spring or an air spring or an elastic body such as a synthetic resin or rubber having appropriate elasticity, which expands and contracts in the hoistway direction. The elastic body is compressed by a predetermined amount in the ascending / descending direction from the natural length in a state where the car door panel is completely closed. The amount of compression of the elastic body will be described in detail later in the description of the first embodiment of the displacement transmission mechanism. The displacement transmission mechanism 234 transmits the displacement in the opening / closing direction of the first engagement blade 216 to the engagement blade roller 232 as it is through the linkage member 228. That is, the engaging blade roller 232 moves in the opening / closing direction together with the linkage member 228. Further, the displacement transmission mechanism 234 transmits the displacement of the engagement blade roller 232 in the up-and-down direction to the linkage member 228 and thus the first engagement blade 216. That is, the engagement blade roller 232 guides the displacement in the up-and-down direction of the first engagement blade 216 to which the linkage member 228 is fixed via the displacement transmission mechanism 234. Here, as described above, since the displacement transmission mechanism 234 includes an elastic body, the displacement amount of the engagement blade roller 232 in the up-and-down direction is not necessarily transmitted as it is to the linkage member 228 and the first engagement blade 216. I don't mean. In the embodiment shown in FIG. 2 (a), the linkage member 228 extending to the door pocket side is fixed to the first engagement blade 216, but the linkage member extending to the door stop side is the first. A form fixed to the two engaging blades 218 is also possible. In this case, the link members 202 and 204 are disposed not to rise left as shown in FIG. In the embodiment shown in FIG. 2A, the engaging blade roller 232 is disposed below the linkage member 228, but the engaging blade roller 232 is disposed above the linkage member 228. Forms are also possible.

  The end portion 230a of the engagement blade roller guide member 230 with which the engagement blade roller 232 contacts when the car door panel 102 is in a completely closed state is bent downward in one embodiment. Therefore, when the car door panel 102 moves slightly from the fully closed state, that is, toward the door pocket side, the engagement blade roller 232 is displaced upward along the engagement blade roller guide member 230. When the engagement blade roller 232 is displaced upward, this displacement is transmitted to the first engagement blade 216 via the displacement transmission mechanism 234 and the linkage member 228, and the first engagement blade 216 is pushed up. As described above, in the case shown in FIG. 2A, when the first engagement blade 216 is pushed up, the car door panel of the first engagement blade 216 and the second engagement blade 218. The interval in the opening / closing direction of 102 becomes narrow. When the engagement device of the door device is normally assembled, the displacement transmission mechanism 234 is not excessively loaded, and the length of the elastic body included in the displacement transmission mechanism 234 is hardly changed. . However, when the engagement device of the door device is not normally assembled, a load greater than a predetermined value is applied to the displacement transmission mechanism 234, the elastic body included in the displacement transmission mechanism 234 is compressed, and the elastic body is moved in the up-and-down direction. The length is shorter than the length when the car door panel is completely closed. By such an action of the displacement transmission mechanism 234, it is possible to prevent an excessive moment from being applied to the bearings and the like provided in the connecting portions 212a, 212b, 214a, and 214b of the link member described above. In the embodiment shown in FIG. 2A, the end portion 230a of the engaging blade roller guide member 230 is bent downward, but a form in which the end portion 230a is bent upward is also possible. In this case, the link members 202 and 204 are disposed not to rise left as shown in FIG. In the embodiment shown in FIG. 2A, the engaging blade roller 232 rolls while contacting on the engaging blade roller guide member 230, but the engaging blade roller 232 is engaged with the engaging blade roller guide. A form of rolling while contacting under the member 230 is also possible. The action of changing the distance in the opening / closing direction of the car door panel 102 between the first engagement blade 216 and the second engagement blade 218 can be related to the operation of the landing door interlock described later.

  FIG. 2B is a schematic diagram when the car door side engaging portion 110 is viewed from above. The opposing surfaces 216a and 218a of the first engagement blade 216 and the second engagement blade 218 are, for example, portions that are perpendicular to the car door panel 102 and parallel to the ascending / descending direction (direction perpendicular to FIG. 2B). including. In the embodiment shown in FIG. 2B, the first engagement blade 216 and the second engagement blade 218 are L-shaped. In the present application, the plate-like portion including the surface 216a of the first engagement blade 216 and the plate-like portion including 218a of the second engagement blade 218 are referred to as a side plate portion 217 and a side plate portion 219, respectively.

  FIG. 3 is a view of an example of a landing door corresponding to the example of the car door shown in FIG. 1 as viewed from the hoistway side. Here, the number of landing door panels is the same as the number of car door panels. The landing door panels 302 and 304 shown in FIG. 3 respectively oppose the passenger door panels 102 and 104 shown in FIG. 1 when the car is landing on the landing floor. The landing door panels 302 and 304 open and close in conjunction with the car door panels 102 and 104 shown in FIG. 1, respectively. However, in a normal elevator system, an error occurs when the car is not stopped on the landing floor. Since it is dangerous if the landing door panels 302 and 304 are opened by the operation, the landing side is not provided with a power unit for opening and closing the landing door panels 302 and 304. In addition, the landing door panels 302 and 304 are provided with a lock mechanism 306 that prevents the landing door panels 302 and 304 from opening when the car is not stopped on the landing floor. The lock mechanism 306 according to the present embodiment includes a landing door side engagement portion. The landing door side engaging portion is provided on the landing door panel 302 facing the passenger door panel 102 provided with the passenger door side engaging portion 110. When the car arrives at the landing floor and stops at a predetermined position, the landing door side engaging part provided on the landing door panel 302 and the car door side engaging part 110 provided on the car door panel 102 are engaged. The landing door is opened and closed by the car door. FIG. 3 also shows a landing door upper panel 308 provided above the landing door, to which members for opening and closing the landing door panel 304 in conjunction with the landing door panel 302 are attached.

  Next, a lock mechanism 306 provided on a landing door according to an embodiment will be described with reference to FIG. On the hoistway side of the landing door panel 302, a latching member (first interlock member) 402 having a claw-like latching portion 404 formed at the tip thereof so that the latching portion 404 can swing freely. It is attached. On the hoistway side of the landing upper panel above the landing door panel 304, a hooked member (second interlock member) 406 having a hooked portion of a recess is fixed. FIG. 4 shows a state in which the latch member 402 and the latch member 406 are latched. That is, in FIG. 4, the landing door panels 302 and 304 are locked and held in a closed state by the hooking member 402 and the hooked member 406. The hooking member 402 and the hooked member 406 have shapes and strengths that prevent the landing door panels 302 and 304 from opening even when a force in the opening direction is applied to at least one of the landing door panels 302 and 304 in the hooked state. It is formed with. The locked state of the landing door shown in the figure is maintained until the car arrives at the landing floor where the landing door is installed, stops at a predetermined position, and the car door starts to open, ensuring safety. The

  In addition, the latching member 402 in the present embodiment is pivotally supported at an intermediate portion of the shaft 408 by a first mounting shaft 408 attached so as to protrude toward the hoistway side. The first mounting shaft 408 is attached to a base plate 410, and the base plate 410 is fixed to a landing door upper panel 308 provided above the landing door by, for example, two mounting screws 412a and 412b. A first roller 414 is pivotally supported on a hoistway side end portion of the first mounting shaft 408 via a bearing (not shown). Further, as shown in the drawing, the latch member 402 has a second mounting shaft 416 provided on the landing door panel 304 side, that is, on the door stop side with respect to the first mounting shaft 408 in the interlocked state. It is provided so as to protrude to the hoistway side. A second roller 418 is pivotally supported on the end of the second mounting shaft 416 on the hoistway side via a bearing (not shown). The diameter of the first roller 414 and the diameter of the second roller 418 are usually designed to be the same value. In the door engagement device, the first roller 414 and the second roller 418 function as a first engagement element and a second engagement element, respectively. The operation of the landing door locking mechanism 306 will be described later with reference to FIG.

  FIG. 5 shows a state where the car door side engaging portion 110 is engaged with the landing door device. That is, when the car arrives at the landing floor where the landing door panels 302 and 304 are provided and stops at a predetermined position, the members of the lock mechanism 306 provided on the landing door panel 302 and the car door side engaging portion 110 shows an engaged state.

  Fig.5 (a) is the figure which looked at the engagement state from the hoistway side. In order to clarify the engagement state, the car door members other than the car door side engaging portion 110 including the first engaging blade 216 and the second engaging blade 218 are shown in the figure. It is not shown in 5 (a). When the car arrives on the landing floor where the landing door panels 302 and 304 are provided and stops at a predetermined position, the first roller 414 and the second roller 418 of the lock mechanism 306 are on the car door side. It is located between the first engagement blade 216 and the second engagement blade 218 of the engagement portion 110. At this time, the latch member 402 and the latch member 406 of the lock mechanism 306 are latched.

  FIG. 5B is a schematic view of the portion indicated by I-I ′ in FIG. FIG. 5B also shows a car door panel 102 corresponding to the landing door panel 302.

  An example of the operation of the locking mechanism in the embodiment shown in FIG. 5 will be described with reference to FIG. 6A is an enlarged view of the lock mechanism 306 shown in FIG. 5A, and the car door member includes a first engagement blade 216, a second engagement blade 218, and the like. The parts other than the car door side engaging portion 110 are not shown in FIG. In the state shown in FIG. 6A, the latching portion 404 of the latching member is latched to the latching member 406 in which the concave latching portion is formed, and the latching member 402 and the latching member are latched. The member 406 is in a hooked state. In this state, the value of the gap in the opening / closing direction of the car door panel 102 between the first engagement blade 216 and the second engagement blade 218 is A0.

  In the state shown in FIG. 6B, the first engagement blade 216 is displaced upward and the second engagement blade 218 is displaced downward, whereby the second roller 418 is displaced by the second engagement blade 218. The side plate portion 219 is pushed rightward in the figure (door pocket direction). As a result, the latching member 402 swings about the axis of the first roller 414, whereby the latching portion 404 of the latching member moves upward, and the latching portion in which the concave latching portion is formed is formed. The latched state with the member 406 is released. That is, FIG. 6B shows a state in which the locking by the hooking member 402 and the hooked member 406 is released. As described above with reference to FIG. 2, when the car door panel 102 moves slightly from the fully closed state in the opening direction, the first engagement blade 216 is pushed up and the second engagement blade 218 is pushed down. Thus, the gap in the opening / closing direction of the car door panel 102 between the first engagement blade 216 and the second engagement blade 218 is reduced to a value A1 (A1 <A0). The gap in the opening / closing direction of the car door panel 102 between the first engagement blade 216 and the second engagement blade 218 when the car door is opened is, for example, the first roller 414 and the second roller 418. It is designed to be approximately equal to the diameter of.

  As described above with reference to FIG. 2, the linkage member 228 is fixed to the first engagement blade 216 and moves in the opening / closing direction together with the first engagement blade 216. A displacement transmission mechanism 234 (not shown) that transmits the displacement of the engaging blade roller 232 (not shown) to the linkage member 228 is attached to the linkage member 228. In the state shown in FIG. 6B, the engagement blade roller 232 (not shown) is displaced upward in the up-and-down direction as compared with the state shown in FIG. In accordance with the displacement of the engagement blade roller 232 (not shown), the linkage member 228 and the first engagement blade 216 are compared in the state shown in FIG. 6B with the state shown in FIG. Then, it is displaced upward. As described above, in the embodiment that has been described, when the first engagement blade 216 is displaced upward, the gap between the first engagement blade 216 and the second engagement blade 218 is reduced.

  The distance between the first engagement blade 216 and the second engagement blade 218 in the opening / closing direction of the car door panel 102 is designed not to be less than a predetermined value. However, for example, the surface 216a of the side plate portion 217 of the first engagement blade 216 facing the second engagement blade 218 when the car door is opened, and the side plate portion 219 of the second engagement blade 218 It may be erroneously assembled so that the gap with the surface 218 a facing the first engagement blade 216 is smaller than the diameter of the first roller 414 or the second roller 418. In such a case, an excessive moment acts on the bearings used for the connecting portions 212a, 212b, 214a, and 214b of the link member, so that the engagement device does not operate normally, and the door opening / closing operation is hindered. . In order to at least reduce the occurrence of such a situation, the displacement transmission mechanism 234 is provided with an elastic body that expands and contracts in the hoistway direction, and by the displacement of the engaging blade roller 232 (not shown) in the elevating direction, The gap between the surface 216a of the side plate portion 217 of the first engagement blade 216 and the surface 218a of the side plate portion 219 of the second engagement blade 218 is prevented from becoming excessively small.

  FIG. 7 qualitatively shows an example of the relationship between the amount of displacement of the engagement blade roller 232 in the up and down direction and the gap between the engagement blades 216 and 218. When the car door is completely closed, the value of the gap between the engaging blades 216 and 218 is A0. However, when the car door starts to open, the value of the gap between the engaging blades 216 and 218 decreases linearly. Normally, the value of the gap between the engaging blades 216 and 218 is finally reduced to A1 as indicated by a straight line 702. However, when the engaging device is assembled by mistake, the force that inhibits the gap between the engaging blades 216 and 218 from becoming smaller when the displacement amount of the engaging blade roller 232 in the up-and-down direction becomes P2. This force is applied to the blades 216 and 218, and this force is transmitted to the displacement transmission mechanism 234 via the linkage member 228. When such a force is applied to the displacement transmission mechanism 234, the elastic body provided in the displacement transmission mechanism 234 is further compressed in the up-and-down direction. As a result, as indicated by reference numeral 704 in the figure, the displacement in the up-and-down direction of the engagement blade roller 232 does not change the gap between the engagement blades 216 and 218 as it is, and the value of the gap between the engagement blades 216 and 218 Generally remains at A2. In other words, when an excessive force is applied to the engagement blades 216 and 218 while the gap between the engagement blades 216 and 218 is becoming smaller, the force affects the value of the gap between the engagement blades 216 and 218. The elastic body absorbs. The specific configuration of the displacement transmission mechanism 234 will be described in detail later.

  Next, the opening / closing operation of the landing doors including the landing door panels 302 and 304 will be described with reference to FIG. In this figure, the car door members are not shown except for the car door side engaging portion 110 including the first engaging blade 216, the second engaging blade 218, and the like. In addition, as described above with reference to FIG. 1, the car door including the car door panels 102 and 104 (not shown in the figure) is opened and closed in conjunction with the power of the car door motor 108 provided in the car. To do. Since the car door side engaging portion 110 including the engagement blade 216 and the engagement blade 218 is attached to the car door panel 102, the car door including the car door panel 102 includes the engagement blade 216 and the engagement blade. It moves in the opening / closing direction together with 218. The car door including the car door panel 104 moves in the opening and closing direction in conjunction with the car door including the car door panel 102.

  Next, the opening / closing operation of the landing door will be described. FIG. 8A shows a state in which the locked state of the locking member 402 and the locked member 406 is released, but the landing doors including the landing door panels 302 and 304 are still closed. Since no power source for opening and closing the landing door is provided on the landing side, the landing door is kept closed unless any external force is applied.

  Engagement blades 216 and 218 attached to the car door panel 102 when the car door is moved by the power of the car door motor 108 provided in the car to move in the opening direction, that is, in the door pocket side direction, are also used. At the same time, it moves in the opening direction of the car door including the car door panel 102. Since the first engagement blade 216 and the second engagement blade 218 are engaged with the first roller 414 and the second roller 418 attached to the landing door 302, the first roller 414 and The second roller 418 and the landing door 302 to which these rollers are attached move in the opening direction of the landing door 302 together with the passenger door including the passenger door panel 102. The landing door 304 moves in the opening direction of the landing door 304 in order to open and close in conjunction with the landing door 302. FIG. 8B shows a state where the landing doors 302 and 304 are opened by such an operation. As is apparent from the above description, in the present embodiment, the first roller 414 attached to the landing door 302 has the second engagement blade 218 attached to the door-end side of the car door panel 102 and The landing door is opened by pressing the second roller 418 toward the door pocket. That is, the second engagement blade 218 functions as a door opening engagement blade that moves the landing door in the opening direction.

  When the door shown in FIG. 8B is opened to the door shown in FIG. 8A being closed, the first roller 414 and the second roller 418 attached to the landing door are moved. The landing door is closed by pushing in the closing direction of the door, that is, the door stop side, by the first engagement blade 216 attached to the car door. That is, the first engagement blade 216 has a function of a door closing engagement blade that moves the landing door in the closing direction.

  In the present embodiment, the first roller 414 and the second roller 418 are elements that constitute the lock mechanism 306 and that also function as a landing door side engaging portion of the engaging device. It is also a first engagement element and a second engagement element.

  According to the embodiments described above, an elevator that enables a smooth door opening and closing operation with a simple configuration and without damaging members used in the door even when the engagement device is not properly assembled. A door device is provided.

(Outline of door device having an engagement device that does not use a member included in the landing door lock mechanism)
Next, a description will be given of an outline of a door configuration and operation when a member included in the landing door lock mechanism is not used in an embodiment of an elevator door engagement device with reference to FIGS. 9 to 10. In this case, the embodiment of the car door can be the same as the embodiment described with reference to FIGS. 1 and 2. Therefore, the description of the embodiment of the car door is omitted. Regarding the engagement between the car door and the landing door, in this embodiment, the locking mechanism of the landing door is not directly related, and the engaging member that engages with the engaging blade provided on the car door is not necessarily provided. Since it is the same as the door apparatus which has an engaging apparatus using the member contained in the landing door lock mechanism mentioned above except that it is not necessary to be two rollers, detailed description is omitted. Further, the displacement transmission mechanism 234 that connects one engagement blade and the engagement blade roller 232 is the same as described above, and thus the description thereof is omitted. Further, in the following description, a so-called side-opening two-door double-opening door will be described. It does not depend on it. FIG. 9 shows a view of another example of the landing door corresponding to the example of the car door shown in FIG. 1 as seen from the hoistway side. Here, the number of landing door panels is the same as the number of car door panels. Each of the landing door panels 302 and 304 shown in FIG. 9 faces the car door panels 102 and 104 shown in FIG. 1 when the car reaches the landing floor, respectively. The landing door panels 302 and 304 open and close in conjunction with the car door panels 102 and 104 shown in FIG. There is no power unit for opening and closing the landing door panels 302 and 304 on the landing side. The landing door panel 302 facing the car door panel 102 provided with the car door side engaging portion 110 is provided with an engaging element 902 that is a landing door side engaging portion so as to protrude toward the hoistway side. When the car arrives at the landing floor and stops at a predetermined position, the engagement element 902 provided on the landing door panel 302 and the car door side engaging portion 110 provided on the car door panel 102 are engaged, and the landing The door is opened and closed by a car door. FIG. 9 also shows an upper panel 308 of a landing door provided with a member or the like for opening and closing the landing door panel 304 in conjunction with the landing door panel 302 and provided above the landing door.

  FIG. 10 shows an enlarged view of the vicinity of the engaging element 902 corresponding to the car door 102 and being the landing door side engaging portion of the landing door 302 shown in FIG. 9. Fig.10 (a) is the figure which looked at the landing door 302 from the hoistway side. FIG. 10B is a view of the landing door 302 as viewed from above in a state where the engaging element 902 is engaged with the car door side engaging portion 110. An engaging element 902 is provided on the hoistway side of the landing door panel 302 so as to protrude toward the hoistway side. In one embodiment, the engagement element 902 is attached to one end side of the engagement element attachment shaft 1004. In one embodiment, the other end of the engagement shaft 1004 is fixed to a base plate 1006. The base plate 1006 is, for example, a landing door upper panel 308 or a landing door panel 302 provided above the landing door by a mounting screw. Fixed to. In another embodiment, the other end of the engagement attachment shaft 1004 is fixed directly to the landing door upper panel 308 landing door panel 302. In a further embodiment, the engagement element 902 is secured directly to the landing door top panel 308 landing door panel 302. The engaging element 902 does not need to be a roller, and can have any shape that can be engaged with the engaging blades 216 and 218 provided on the car. Therefore, the outer shape of the engagement element 902 can be made, for example, a quadrangular prism. The material of the engagement element 902 can be any material that is suitable for engagement with the engagement blades 216 and 218 provided on the car. The size of the engagement element 902 in the door opening / closing direction (lateral direction in the figure) is adapted to the gap between the first engagement blade 216 and the second engagement blade 218 provided in the car door side engagement portion 110. Value. That is, the dimension of the engagement element 902 in the door opening / closing direction (lateral direction in the figure) is smaller than the gap between the first engagement blade 216 and the second engagement blade 218 while the car is traveling, and the car is at the floor. It is set to a value that contacts at least one of the first engagement blade 216 and the second engagement blade 218 when the car door is stopped after stopping on the floor. Further, the position of the engagement element 902 in the door opening / closing direction is such that the engagement element 902 can enter the gap between the first engagement blade 216 and the second engagement blade 218 provided in the car door side engagement portion 110. Therefore, a position corresponding to the middle between the first engagement blade 216 and the second engagement blade 218 is set.

  When the car lands on the floor where the platform is located, stops at a predetermined position, and the car door 102 moves in the opening direction (the right direction in FIG. 10B), the engagement provided in the car The blades 216 and 218 move in the opening direction together with the car door 102. Usually, the engagement blades 216 and 218 and the engagement element 902 are engaged, and the engagement element 902 moves in the opening direction in conjunction with the car door 102. Since the engaging element 902 is attached to the landing door 302, the landing door 302 also moves in the opening direction in conjunction with the car door 102. When the door is opened, it is the second engagement blade 218 that pushes the engagement element 902 in the opening direction, and the second engagement blade 218 can be said to be an engagement blade for door opening. When the car door 102 moves in the closing direction (leftward in FIG. 10B), the first engaging blade 216 pushes the engaging element 902 in the closing direction, so that the landing door 302 becomes the car door 102. Move in the closing direction in conjunction. As described above, the car door 104 opens and closes in conjunction with the car door 102, and the landing door 102 opens and closes in conjunction with the landing door 302.

  A plurality of engagement elements 902 may be provided. In this case, the side surfaces of the engagement elements 902 in the door opening / closing direction are made to coincide with each other in the ascending / descending direction.

  Also according to the above-described embodiments, the door of an elevator that enables a smooth door opening / closing operation with a simple configuration and without damaging members used in the door even when the engagement device is not properly assembled. An apparatus is provided.

  The outline of the elevator door device has been described above with reference to the drawings. Next, an embodiment of a displacement transmission mechanism provided in the car door will be described in detail. All the embodiments described below can be used in the elevator door device described above.

(First embodiment of displacement transmission mechanism)
FIG. 11 is a perspective view for explaining the displacement transmission mechanism according to the first embodiment. The displacement transmission mechanism 234 includes a first support member 1102 that supports the engagement blade roller 232, a second support member 1104 that supports an elastic body, and an elastic body.

  The first support member 1102 includes an engagement blade roller shaft 1106 that is orthogonal to the surface including the side surface of the linkage member 228 and that is disposed in the horizontal direction and pivotally supports the engagement blade roller 232. The engaging blade roller shaft 1106 is attached to, for example, the side plate 1108a and the side plate 1108b disposed so as to face each other. The engaging blade roller shaft 1106 may be attached to one of the side plate 1108a or the side plate 1108b. Further, one side plate may be provided. When only the side plate 1108a is provided, one end side of the engaging blade roller shaft 1106 is attached to the side plate 1108a, and when only the side plate 1108b is provided, one end side of the engaging blade roller shaft 1106 is provided. It is attached to the side plate 1108b. The first support member 1102 also includes a first horizontal plate 1110 that is substantially parallel to the engagement blade roller shaft 1106 and coupled to the side plate 1108. The first horizontal plate 1110 may be formed integrally with the side plate 1108a, the side plate 1108b, or the side plate 1108a and the side plate 1108b. The first horizontal plate 1110 has a first guide opening formed in a part thereof. In FIG. 11, the first guide opening is formed substantially at the center of the first horizontal plate 1110.

  The second support member 1104 includes a second horizontal plate 1112 coupled to the linkage member 228 and substantially parallel to the first horizontal plate 1110 of the first support member 1102. Note that the side surface on one end side (left side in the drawing) of the linkage member 228 is fixed to, for example, the first engagement blade 216 as described above. The second horizontal plate 1112 may be formed integrally with the linkage member 228. One end side of the first guide shaft 1114 is fixed to the second horizontal plate 1112 so as to be substantially orthogonal to the second horizontal plate 1112. The other end of the first guide shaft 1114 is inserted into a first guide opening formed in the first horizontal plate 1110 of the first support member 1102. The cross-sectional dimension of the first guide shaft 1114 is smaller by, for example, about 0.05 mm to 1 mm than the cross-sectional dimension of the first guide opening. A terminal member 1116 having a cross-sectional dimension larger than that of the first guide opening is fixed to the other end of the first guide shaft 1114 that has passed through the first guide opening. A first guide shaft 1114 having one end fixed to the second horizontal plate 1112 and the end member 1116 fixed to the other end is inserted into a first guide opening formed in the first horizontal plate 1110. Accordingly, the first support member 1102 and the second support member 1104 are connected. Therefore, the engagement blade roller 232 supported by the engagement blade roller shaft 1106 attached to the first support member 1102 is displaced together with the second support member 1104 coupled to the linkage member 228. Since the cross-sectional dimension of the first guide shaft 1114 is substantially equal to the cross-sectional dimension of the first guide opening, the displacement in the opening / closing direction of the car door panel is caused by the engagement blade, the linkage member 228, the first guide shaft 1114, the first guide shaft 1114, and the like. 1 is transmitted as it is to the engaging blade roller 232 via the one horizontal plate 1110 or the like. That is, the displacement amount of the engagement blade roller 232 in the door opening / closing direction is substantially equal to the displacement amount of the engagement blade to which the linkage member 228 is fixed in the door opening / closing direction. However, the displacement amount of the engagement blade roller 232 in the up-and-down direction is not necessarily equal to the displacement amount of the engagement blade to which the linkage member 228 is fixed in the up-and-down direction.

  Regarding the displacement in the up-and-down direction, the first guide shaft 1114 having one end fixed to the second horizontal plate 1112 and the end member 1116 fixed to the other end is the first horizontal plate 1110 of the first support member 1102. And the maximum value of the gap between the second support member 1104 and the second horizontal plate 1112. In other words, the terminal member 1116 of the first guide shaft 1114 is fixed to the first guide shaft 1114 so as to determine the maximum value of the gap between the first horizontal plate 1110 and the second horizontal plate 1112. The However, the gap between the first horizontal plate 1110 and the second horizontal plate 1112 can change within a predetermined range smaller than the maximum value. Here, the elastic body 1118 surrounds the first guide shaft 1114 between the first horizontal plate 1110 of the first support member 1102 and the second horizontal plate 1112 of the second support member 1104. It is intervened. As described above, the elastic body 1118 may be a fluid spring such as a coil spring or an air spring, or a synthetic resin or rubber having appropriate elasticity. When a columnar synthetic resin, rubber, or the like is used as the elastic body 1118, for example, a hollow portion is provided in the axial direction so that the first guide shaft 1114 can pass therethrough. As described above, the elastic body 1118 is compressed by a predetermined amount in the ascending / descending direction from the natural length in a state where the car door panel is completely closed. Since the position of the engaging blade roller 232 in the ascending / descending direction is defined by the engaging blade roller guide member 230, the position of the first support member in the ascending / descending direction of the first horizontal plate 1110 is defined by the engaging blade roller guide member 230. Is done. When the elastic body 1118 is placed on the first horizontal plate 1110 and the second horizontal plate 1112 connected to the engaging blade via the linkage member 228 is placed on the other end of the elastic body 1118, the second horizontal plate A compressive force in the vertical direction is applied to the elastic body 1118 via the plate 1112. When the car door panel is completely closed, the engaging device is not engaged. Therefore, the second horizontal plate 1112 and the compression force based on the weight of the members connected to the second horizontal plate 1112 are not used. The force is not applied to the elastic body 1118. The elastic body 1118 is compressed in the ascending / descending direction from the natural length by a length corresponding to such a compressive force. In order to compress the elastic body 1118 by a predetermined amount in the ascending / descending direction, it can be performed by appropriately setting the position of the terminal member 1116 of the first guide shaft along the axis of the first guide shaft 1114. Thus, if the elastic body 1118 is compressed by a predetermined amount in the ascending / descending direction, an additional force is applied to the elastic body 1118 when the car door panel opens and closes when the engagement device is properly assembled. Therefore, the length of the elastic body 1118 in the up-and-down direction does not change, and the displacement in the up-and-down direction of the engagement blade roller 232 is transmitted as it is to the engagement blade to which the linkage member 228 is attached. However, if the engagement device is not properly assembled, an additional force is applied to the elastic body 1118 when the car door panel opens and closes, and the elastic body 1118 is compressed and its length in the up-and-down direction is shortened. . Therefore, even if the engagement blade roller 232 is displaced in the up-and-down direction so as to further narrow the gap between the engagement blades, further displacement of the engagement blade roller 232 in the up-and-down direction is caused by the engagement blade to which the linkage member 228 is attached. The gap between the engaging blades does not become smaller than a predetermined value. As a result, excessive force is not applied to the members constituting the engagement device, and damage to the members used for the door is avoided.

  By using the displacement transmission mechanism according to the present embodiment, it is possible to perform a smooth door opening / closing operation with a simple configuration without damaging members used for the door even when the engagement device is not properly assembled. An elevator door device is provided.

  Subsequently, another embodiment of the displacement transmission mechanism based on the present embodiment will be described. However, the description given regarding the present embodiment also applies to the embodiment described below, and therefore will be described below. In the description of the embodiment, the description of the same content as the description given regarding the present embodiment is omitted. In the elevator door device in the embodiment described below, when the engagement blade roller 232 rolls in the opening / closing direction of the car door along the engagement blade roller guide member 230, the engagement blade roller 232 is in the horizontal direction. An engaging blade roller guide mechanism that restricts the swinging of the engaging blade is provided. First, the embodiment will be described sequentially from the embodiment in which the engagement blade roller guide mechanism is mounted on the displacement transmission mechanism.

(Second Embodiment of Displacement Transmission Mechanism)
In the present embodiment, the engagement blade roller guide mechanism is provided in the displacement transmission mechanism. As described above, the engagement blade roller 232 is displaced in the opening / closing direction along the engagement blade roller guide member 230, and is also displaced in the up / down direction (up / down direction). The side surface of the engagement blade roller 232 is essentially parallel to the engagement blade roller guide member 230, and if the engagement blade roller 232 swings in the horizontal direction, the engagement device may not operate normally. In order to solve this problem, in the displacement transmission mechanism according to the present embodiment, in addition to the configuration of the displacement transmission mechanism 234 according to the first embodiment, the engagement blade roller 232 rides along the engagement blade roller guide member 230. An engagement blade roller guide mechanism that restricts the engagement blade roller 232 from swinging in the horizontal direction when it rolls in the opening / closing direction of the car door and is displaced in the up-and-down direction is further provided.

  An example of the displacement transmission mechanism according to this embodiment is shown in FIG. The displacement transmission mechanism 234 shown in FIG. 12 is provided so as to be substantially orthogonal to the second horizontal plate 1112 of the second support member 1104 in the displacement transmission mechanism according to the first embodiment shown in FIG. The second guide shaft 1202 thus formed and a second guide opening 1204 formed in the first horizontal plate 1110 of the first support member 1102 are added. For the second guide shaft 1202, for example, a bolt can be used. One end side of the second guide shaft 1202 is fixed to the second horizontal plate 1112. The cross-sectional dimension of the second guide opening 1204 is, for example, 0.05 mm to 1 mm larger than the cross-sectional dimension of the second guide shaft 1202, and the other end side of the second guide shaft 1202 is It is inserted into the guide opening 1204. With such a configuration, even when the engaging blade roller 232 is displaced in the up-and-down direction along the engaging blade roller guide member 230, the second guide shaft 1202 is displaced in the horizontal direction of the second guide opening 1204. Limit. When the horizontal displacement of the second guide opening 1204 is limited, the horizontal displacement of the first support member 1102 including the first horizontal plate 1110 in which the second guide opening 1204 is formed is limited. Thus, the engagement blade roller 232 attached to the first support member 1102 is restricted from swinging in the horizontal direction. Further, when the engaging blade roller 232 is displaced in the up-and-down direction along the engaging blade roller guide member 230, the relative position of the second support member 1104 relative to the first support member 1102 varies in the horizontal direction. Limited. Due to these effects, the engagement device operates normally.

  By using the displacement transmission mechanism according to the present embodiment, in addition to the effects obtained when the displacement transmission mechanism according to the first embodiment is used, a smooth door can be achieved by restricting the swing of the engagement blade roller in the horizontal direction. Provided is an elevator door device that can more reliably open and close.

(Third embodiment of displacement transmission mechanism)
Also in this embodiment, the engagement blade roller guide mechanism is provided in the displacement transmission mechanism. The displacement transmission mechanism in the present embodiment is a second support member that faces the first side plate 1108 provided on the first support member 1102 in the displacement transmission mechanism according to the first embodiment shown in FIG. A second side plate coupled to 1104 second horizontal plate 1112 is added. The first side plate 1108 and the second side plate, or the engagement blade roller shaft 1106 and the second side plate are provided with a mechanism for limiting relative displacement in the door opening / closing direction.

  An example of a displacement transmission mechanism according to this embodiment is shown in FIG. A second side plate 1302 is coupled to the second horizontal plate 1112 of the second support member 1104. The second side plate 1302 is disposed to face the first side plate 1108 of the first support member 1102. In the figure, the second side plate 1302 is provided at a position facing the first side plate 1108b. However, the second side plate 1302 may be provided at a position facing the first side plate 1108a. The second horizontal plate 1112 and the second side plate 1302 may be integrally formed. Furthermore, in the form shown in the drawing, the second horizontal plate 1112, the second side plate 1302, and the linkage member 228 may be integrally formed. The first side plate 1108 and the second side plate 1302 or the engagement blade roller shaft 1106 and the second side plate 1302 are provided with a mechanism for restricting relative displacement in the door opening / closing direction.

  This embodiment includes various embodiments.

  In one embodiment, a first protrusion 1304 that protrudes toward the second side plate 1302 is fixed to the end of the first side plate 1108 or the engaging blade roller shaft 1106. In the embodiment shown in FIG. 13, the first protrusion 1304 is fixed to the end of the engagement blade roller shaft 1106 (not shown). The first protrusion 1304 may be fixed to the first side plate 1108. On the other hand, at least a part of the first protrusion 1304 is engaged with the second side plate 1302, and the first protrusion 1304 and the second side plate 1302 limit the relative displacement in the door opening / closing direction. The guide mechanism is formed. In FIG. 13, the first guide mechanism formed on the second side plate 1302 has an effective length in the ascending / descending direction larger than the amount of change in the gap between the first horizontal plate 1110 and the second horizontal plate 1112. , An embodiment of a notch 1306 formed in the second side plate 1302 is shown. The first guide mechanism formed on the second side plate 1302 is not necessarily a notch as shown in FIG. 13, and the effective length in the ascending / descending direction is the first horizontal plate 1110 and the second horizontal plate. It may be larger than the amount of change in the gap between the second side plate 1302 and the first opening formed in the second side plate 1302 or a groove formed on the first side plate 1108 side of the second side plate 1302.

  By using the displacement transmission mechanism described above, in addition to the effects of using the displacement transmission mechanism according to the first embodiment, smooth opening and closing of the door can be achieved by limiting the horizontal swing of the engagement blade roller. Provided is an elevator door device that can operate more reliably.

  In the embodiment described above, the second guide shaft 1202 provided so as to be substantially perpendicular to the second horizontal plate 1112 of the second support member 1104 included in the displacement transmission mechanism of the second embodiment; A configuration in which a second guide opening 1204 formed in the first horizontal plate 1110 of the first support member 1102 is added can also be implemented, and the engagement blade roller 232 is more reliably rocked in the horizontal direction. It is possible to restrict the movement and to operate the engagement device normally.

(Fourth Embodiment of Displacement Transmission Mechanism)
Also in this embodiment, the engagement blade roller guide mechanism is provided in the displacement transmission mechanism, and the displacement transmission mechanism according to this embodiment is a modification of the displacement transmission mechanism according to the third embodiment described above. A second protrusion (not shown) that protrudes toward the first side plate 1108 is fixed to the second side plate 1302. On the other hand, the first side plate 1108 engages with at least a part of the second protrusion, and the second guide restricts the relative displacement of the second protrusion and the first side plate 1108 in the door opening / closing direction. A mechanism (not shown) is formed.

  In one embodiment, the second guide mechanism formed on the first side plate 1108 has an effective length in the ascending / descending direction larger than the amount of change in the gap between the first horizontal plate and the second horizontal plate, A notch or a second opening formed in one side plate 1108 or a groove formed on the second side plate 1302 side of the first side plate 1108.

  By using the displacement transmission mechanism according to the present embodiment, in addition to the effects obtained when the displacement transmission mechanism according to the first embodiment is used, a smooth door can be achieved by restricting the swing of the engagement blade roller in the horizontal direction. Provided is an elevator door device that can more reliably open and close.

  Further, similarly to the case of using the displacement transmission mechanism of the third embodiment, the second support plate 1104 included in the displacement transmission mechanism of the second embodiment is substantially orthogonal to the second horizontal plate 1112. The second guide shaft 1202 provided on the first support member 1102 and the second guide opening 1204 formed on the first horizontal plate 1110 of the first support member 1102 can be added, and the embodiment can be implemented more reliably. The engagement blade roller 232 is restricted from swinging in the horizontal direction, and the engagement device can be operated normally.

(Other embodiments)
The embodiment using the displacement transmission mechanism as the engaging blade roller guide mechanism has been described above. In the embodiment described below, an engaging blade roller guide member, or both an engaging blade roller and an engaging blade roller guide member are used as an engaging blade roller guide mechanism instead of a displacement transmission mechanism. However, the present embodiment can be applied to the elevator door device using the displacement transmission mechanism according to the first embodiment described above, and the elevator using the displacement transmission mechanism according to the second to fourth embodiments. It can also be applied to other door devices.

  Hereinafter, the three modes will be described with reference to FIG. FIG. 14A shows an example of the engaging blade roller guide mechanism. 14 including this figure is a view of the engagement blade roller 232 and the engagement blade roller guide member 230 as viewed in the door opening / closing direction. In the form shown in FIG. 14A, the large-diameter portion 1402 is formed coaxially on the outer peripheral surface of the engagement blade roller 232 whose outer shape is cylindrical. In the engagement blade roller guide member 230, a groove 1404 having a width substantially equal to the axial dimension of the large diameter portion 1402 formed in the engagement blade roller 232 is formed in the door opening / closing direction. The engaging blade roller 232 is guided along the engaging blade roller guide member 230 while the side surface of the large diameter portion 1402 is guided while being engaged with the side surface of the groove 1404 formed in the engaging blade roller guide member 230. Rolling. Therefore, in the form shown in FIG. 14A, the engaging blade roller guide mechanism is composed of both the engaging blade roller 232 and the engaging blade roller guide member 230.

  FIG. 14B shows another example of the engaging blade roller guide mechanism. In the configuration shown in FIG. 14B, a groove (small diameter portion) 1406 is coaxially formed on the outer peripheral surface of the engagement blade roller 232 whose outer shape is cylindrical, contrary to the configuration shown in FIG. Is formed. On the engagement blade roller guide member 230, a convex portion 1408 having a width substantially equal to the axial dimension of the groove 1406 formed in the engagement blade roller 232 is formed in the door opening / closing direction. The engaging blade roller 232 is guided along the engaging blade roller guide member 230 while the side surface of the groove 1406 is guided while engaging the side surface of the convex portion 1408 formed on the engaging blade roller guide member 230. Roll. Therefore, in the form shown in FIG. 14B, the engaging blade roller guide mechanism is composed of both the engaging blade roller 232 and the engaging blade roller guide member 230.

  FIG. 14C shows another example of the engaging blade roller guide mechanism. In the form shown in FIG. 14C, the engagement blade roller 232 is neither formed with a large diameter portion nor a groove. The engaging blade roller guide member 230 is formed with a groove 1410 having a width substantially equal to the axial width of the engaging blade roller 232. In other words, the engagement blade roller guide member 230 is formed with a pair of side plates 1412 in which the interval between the opposing surfaces is substantially equal to the axial width of the engagement blade roller 232. The engaging blade roller 232 is guided along the engaging blade roller guide member 230 while the outer peripheral side surface thereof is guided while being engaged with the side surface of the groove 1410 formed in the engaging blade roller guide member 230. Roll. Therefore, in the form shown in FIG. 14C, the engaging blade roller guide mechanism is constituted by the engaging blade roller guide member 230. In other embodiments, the engagement blade roller shown in FIG. 14A or 14B can be used.

  By using the engaging blade roller guide mechanism according to the present embodiment, an elevator door device is provided that can more smoothly perform a smooth door opening and closing operation by restricting the swing of the engaging blade roller in the horizontal direction. The

  According to the embodiments described above, an elevator that enables a smooth door opening and closing operation with a simple configuration and without damaging members used in the door even when the engagement device is not properly assembled. A door device is provided.

  Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the disclosed components without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

102, 104 ... car door panel, 106 ... car door belt,
108: Car door motor 110: Car door side engagement part,
202, 204 ... link member, 206 ... plate,
208, 210 ... link part attachment member,
212a, 212b, 214a, 214b ... connecting portions of link members,
216 ... 1st engagement blade, 217 ... Side plate part of 1st engagement blade,
218, 218 '... the second engagement blade, 219, 219' ... the side plate portion of the second engagement blade,
220 ... Upper panel of the car door, 222 ... Hanger rail,
224a, 224b ... car door suspension member,
226a, 226b ... car door rollers,
228 ... linkage member, 230 ... engagement blade roller guide member,
230a, 230b ... end of the engaging blade roller guide member, 232 ... engaging blade roller,
234 ... Displacement transmission mechanism 302, 304 ... landing door panel, 306 ... locking mechanism 308 ... upper panel of landing door, 402 ... latching member, first interlocking member,
404 ... Hook part of the hook member; 406 ... Hook member, second interlock member;
408, 416 ... Roller mounting shaft, 410 ... Base plate,
412a, 412b ... Base plate mounting screws,
414, 414 ', 418, 418' ... roller,
902 ... Engagement element 1004 ... Engagement attachment shaft 1006 ... Base plate,
1102 ... First support member of the displacement transmission mechanism,
1104 ... a second support member of the displacement transmission mechanism,
1106 ... engaging blade roller shaft,
1108, 1108a, 1108b ... the first side plate of the first support member,
1110: a first horizontal plate of the first support member;
1112 ... the second horizontal plate of the second support member,
1114 ... 1st guide shaft, 1116 ... Termination member of 1st guide shaft, 1118 ... Elastic body,
1202 ... Second guide shaft, 1204 ... Second guide opening, 1302 ... Second side plate,
1304 ... 1st projection part, 1306 ... Notch, 1st guide mechanism,
1402 ... Large diameter portion formed on the engaging blade roller,
1404 ... Groove formed in the engaging blade roller guide member,
1406 ... Groove formed in the engaging blade roller,
1408 ... convex portions formed on the engaging blade roller guide member,
1410 ... Groove formed in the engaging blade roller guide member,
1412 ... Side plate formed on the engaging blade roller guide member

Claims (14)

At least one landing door panel that opens and closes the entrance of the elevator landing;
A first engagement element provided on any one of the landing door panels so as to protrude toward the hoistway;
Open and close the elevator car doorway, and the same number of car door panels as the landing door panels,
A first engagement blade and a second engagement blade, which are provided substantially parallel to each other so as to protrude toward the landing side and extend in the ascending / descending direction, to the car door panel facing the landing door panel provided with the first engagement element. An engaging blade of
It is attached to a car door panel provided with the first engagement blade and the second engagement blade by a link member attachment member, and connects the first engagement blade and the second engagement blade. A pair of link members that are substantially parallel to each other; a linkage member that is fixed to one of the first engagement blade and the second engagement blade;
An engagement blade roller that moves in the opening and closing direction together with the linkage member, and that guides the displacement in the up-down direction of the engagement blade to which the linkage member is fixed;
An engagement blade roller guide member provided on the car door panel and defining a position of the engagement blade roller in the ascending / descending direction;
A displacement transmission mechanism for transmitting the displacement of the engagement blade roller to the linkage member;
A drive mechanism that interlocks and opens and closes the car door panel and the landing door panel when the car reaches the elevator hall and stops.
The engaging blade roller guide member, the link member, the first engaging blade and the second engaging blade are stopped when the car reaches the elevator landing and stops, and the landing door panel begins to open. The gap between the side plates of the first engagement blade and the second engagement blade is narrowed and arranged to contact and engage the first engagement element.
The displacement transmission mechanism includes an elastic body that expands and contracts in the hoistway direction,
This elastic body is compressed by a predetermined amount in the ascending / descending direction when the car door panel is completely closed. The elevator door device comprises:
A first mounting member for rotatably mounting the first engagement element on the landing door panel provided with the first engagement element;
A latching member pivotally supported by the first attachment member at an intermediate portion between the landing door panel and the first engaging member and having a latching portion at one end;
A second attachment member attached to the retaining member so as to protrude toward the hoistway side;
A second engagement member rotatably attached to the second attachment member;
Provided on a landing upper panel above the landing door panel, and when the car is not stopped at the elevator landing, the hooking portion of the hooking member is hooked and the landing door panel is closed. And a hooked portion to keep,
The first engagement element and the second engagement element are rollers;
In the second engagement element, when the car stops at the elevator landing, a gap between the side plates of the first engagement blade and the second engagement blade is narrowed, and the first engagement blade Alternatively, the latching member is swung by being displaced relative to the first engaging element by being pushed by the side plate part of the second engaging blade, and the latching part of the latching member The elevator door device according to claim 1, wherein the hooked state between the hooked portion and the hooked portion is released.   The elevator door device according to claim 1, wherein the elastic body includes a spring, a synthetic resin, or rubber. The displacement transmission mechanism is
A first support member for supporting the engagement blade roller;
A second support member for supporting the elastic body;
Comprising the elastic body,
The first support member is
An engagement blade roller shaft that is orthogonal to a surface including a side surface of the linkage member and that is disposed in a horizontal direction and pivotally supports the engagement blade roller;
A first side plate to which the engagement blade roller shaft is attached;
A first horizontal plate that is substantially parallel to the engaging blade roller shaft and is coupled to the side plate and has a first guide opening formed in a part thereof;
The second support member is
A second horizontal plate coupled to the linkage member and substantially parallel to the first horizontal plate of the first support member;
One end side is fixed so as to be substantially orthogonal to the second horizontal plate, and the other end side is inserted into the first guide opening formed in the first horizontal plate of the first support member, An end member having a cross-sectional dimension larger than the cross-sectional dimension of the first guide opening is fixed to the other end that has passed through the first guide opening, and the first horizontal plate and the second horizontal plate A first guide shaft defining a maximum value of the gap between and
The elastic body is interposed between the first horizontal plate and the second horizontal plate so as to surround the first guide shaft, and is lifted and lowered in a state where the car door panel is completely closed. The elevator door device according to claim 1 or 2, wherein the elevator door device is compressed in a direction by a predetermined amount.   In the elevator door device, the engagement blade roller swings in a horizontal direction when the engagement blade roller rolls in the opening / closing direction of the car door along the engagement blade roller guide member. The elevator door device according to claim 4, further comprising an engaging blade roller guide mechanism for limiting.   The elevator door device according to claim 5, wherein the engagement blade roller guide mechanism is provided in the displacement transmission mechanism. The second support member further includes a second guide shaft having one end fixed so as to be substantially orthogonal to the second horizontal plate,
The first horizontal plate of the first support member is further formed with a second guide opening,
The elevator door device according to claim 6, wherein the other end side of the second guide shaft is inserted into the second guide opening. The displacement transmission mechanism is
A second side plate facing the first side plate provided on the first support member and coupled to the second horizontal plate of the second support member;
The first side plate or the engaging blade roller shaft and the second side plate are provided with a mechanism for restricting relative displacement in the door opening / closing direction. Elevator door equipment. A first protrusion that protrudes toward the second side plate is fixed to an end of the first side plate or the engagement blade roller shaft,
A first guide that engages at least a part of the first projecting portion with the second side plate and limits relative displacement of the first projecting portion and the second side plate in the door opening / closing direction. The elevator door device according to claim 8, wherein a mechanism is formed.   The first guide mechanism has a notch formed in the second side plate, the effective length in the ascending / descending direction being larger than the amount of change in the gap between the first horizontal plate and the second horizontal plate, The elevator door device according to claim 9, wherein the door device is a first opening or a groove formed on the first side plate side. The second support member further includes a second guide shaft having one end fixed so as to be substantially orthogonal to the second horizontal plate,
The first horizontal plate of the first support member is further formed with a second guide opening,
The elevator door device according to claim 10, wherein the other end side of the second guide shaft is inserted into the second guide opening. A second protrusion that protrudes toward the first side plate is fixed to the second side plate,
A second guide that engages at least a part of the second projecting portion with the first side plate and restricts relative displacement of the second projecting portion and the first side plate in the door opening / closing direction. The elevator door device according to claim 8, wherein a mechanism is formed.   The second guide mechanism has an effective length in the ascending / descending direction larger than a change amount of a gap between the first horizontal plate and the second horizontal plate, and a cutout formed in the first side plate or The elevator door device according to claim 12, wherein the elevator door device is a groove formed on the second opening or the second side plate side.   6. The elevator according to claim 5, wherein the engagement blade roller guide mechanism includes the engagement blade roller guide member or both the engagement blade roller and the engagement blade roller guide member. Door device.

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