JP4383774B2 - Elevator door shielding device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an elevator door shielding device that shields a gap between an elevator door and a sill that guides the elevator door.
[0002]
[Prior art]
The elevator hall wall of the building is provided with an elevator entrance / exit that leads into the elevator hoistway. The entrance / exit hold door (elevator door) is provided at the entrance / exit, and the entrance / exit is normally closed by this hold door. Has been.
[0003]
At the bottom of the entrance, a sill is installed almost flush with the floor of the elevator hall, a guide groove is formed on the top surface of the sill, and a guide shoe that engages with the guide groove is provided below the hold door. When the hold door is driven by the driving device to open and close, the guide shoe slides along the guide groove of the sill.
[0004]
A certain amount of clearance is provided between the hold door and the sill to allow the hold door to operate smoothly. For this reason, when a fire occurs in the building, the entrance is closed by the hold door. Nonetheless, smoke from the fire flows into the hoistway through the gap between the holder and the sill, the hoistway becomes a chimney, and the fire may develop.
[0005]
Also, in elevator cars traveling in hoistways, if there is a gap between the car doorway and the car door, smoke from the fire flows into the car through the gap, There is a risk of danger to passengers.
[0006]
Therefore, in the prior art, as a means for shielding the gap between the lower part of the holder and the sill, a plurality of guide shoes provided at the lower part of the holder and engaged in the guide groove of the sill are closed. A plate is attached, and a packing such as rubber is attached as a shielding member to the plate surface of the closing plate to shield the gap between the lower part of the hold door and the sill.
[0007]
[Problems to be solved by the invention]
However, if the shielding member provided at the lower part of the hold door makes strong contact with the guide groove of the sill, the opening and closing operation of the hold door will be hindered, and the shielding member will be worn out at an early stage, and the shielding member will be relatively frequently worn. Will have to be replaced. Further, if the contact pressure between the shielding member and the guide groove is weakened, the airtightness is lowered, and the initial purpose cannot be achieved.
[0008]
The present invention has been made paying attention to such points, and an object of the invention is to provide an elevator door that can smoothly open and close the door and prevent wear of the shielding member over a long period of time. It is to provide a shielding device.
[0009]
[Means for Solving the Problems]
The present invention includes an elevator door that opens and closes along a sill, a shielding member that is provided on the elevator door and that can contact the sill, and the shielding member and the sill are not connected during the opening and closing operation of the elevator door. A link mechanism that keeps a contact state and shields the gap between the elevator door and the sill by bringing the shielding member into contact with the sill when the elevator door is disposed at the closed position, The elevator door has a plurality of link bars rotatably provided, the shielding member is installed between one end portions of the link bars, and each link bar is elastically moved in one rotation direction by an elastic member. Immediately before the elevator door moves in the door closing direction and reaches the closing position. The link mechanism is in contact with a stopper provided on the sill, and the link bar is rotated against the elastic member by this contact, so that the shielding member is displaced downward to contact the sill, The link mechanism is provided at a lower portion on the back side of the elevator door, and operates within a range that does not protrude outward from the door contact edge of the elevator door, and the elastic member is disposed at the closing position of the elevator door. In this case, the elastic force acts in the direction of urging the elevator door in the door closing direction .
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
1 and 2 show a first embodiment. FIG. 1 is a front view of a hold door 1 as an elevator door provided at an entrance of an elevator hall as seen from a hoistway side, FIG. 2 is a sectional view thereof, and the hold door 1 is disposed on a sill 2, The entrance / exit is opened and closed by moving along the longitudinal direction of the sill 2.
[0013]
1A shows a state in which the hold door 1 is moving in the door closing direction, and FIG. 1B shows a state immediately before the hold door 1 reaches a predetermined closing position H. FIG. Shows the state when the hold door 1 reaches a predetermined closing position H.
[0014]
The upper portion of the hold door 1 is suspended movably on a hanger rail (not shown) provided at the upper portion of the entrance. Guide shoes 4 are attached to a lower portion of the hold door 1 at a plurality of positions in the left-right direction, and these guide shoes 4 are slidably fitted into guide grooves 5 formed in the sill 2.
[0015]
A link mechanism 10 is provided in the lower part of the back side of the hold door 1, and the link mechanism 10 includes a pair of link bars 11, a shielding member 12 horizontally installed between one end portions of the link bars 11, and the link bar 11. And a connecting plate 13 provided between the other end portions.
[0016]
As shown in FIG. 2, each link bar 11 is supported by a bracket 15 attached to the back surface of the holder 1 via a pin 16 so as to be rotatable around a horizontal axis. The shielding member 12 is rotatably attached to the lower end of each link bar 11 via a pin 17 and is supported in a horizontal state parallel to the sill 2.
[0017]
The connecting plate 13 is rotatably attached to the upper end portion of each link bar 11 via a pin 18 and supported in a horizontal state parallel to the shielding member 12. The shielding member 12 and the connecting plate 13 are connected to each other. Are displaced up and down while maintaining the parallelism according to the rotation of the link bar 11.
[0018]
The shielding member 12 has the same length as the width of the hold door 1, the connecting plate 13 is slightly longer than the width of the hold door 1, and an abutment body 20 made of a rotatable roller is provided at one end of the connecting plate 13. A stopper 21 that is provided and capable of contacting the contact body 20 is provided in the middle of the sill 2. The stopper comes into contact with the stopper 21 according to the movement of the hold door 1 in the door closing direction.
[0019]
A spring 22 as an elastic member is stretched between each link bar 11 and the hold door 1, and each link bar 11 is elastic in the clockwise direction in FIG. 1, that is, in the direction in which the shielding member 12 moves upward. Is energized. In addition, the clockwise rotation range of each link bar 11 is regulated by a regulation mechanism (not shown), and each link bar 11 is inclined to the right upward direction at normal times, and the shielding member 12 is separated from the sill 2 by a predetermined distance. Are kept apart from each other.
[0020]
The shielding member 12 includes a shielding plate 25 having a horizontally long plate shape, and packings 28 and 29 made of an elastic body such as rubber provided at upper and lower edges of the shielding plate 25. That is, as shown in FIG. 2, bent pieces 26 and 27 are formed on the upper and lower edges of the shielding plate 25, and packings 28 and 29 are attached to the lower surfaces of the bent pieces 26 and 27. These packings 28 and 29 have a continuous length over the entire length section of the shielding plate 25 in the longitudinal direction, and are removably attached to the bent pieces 26 and 27, respectively.
[0021]
A receiving member 32 is horizontally attached to the back surface of the hold door 1. The receiving member 32 has the same length as the width of the holder 1, and a receiving member 33 made of an elastic body such as rubber is attached to the side surface of the receiving member 32 so as to face the packing 28. The receiving member 33 has a continuous length over the entire length of the receiving member 32 in the longitudinal direction.
[0022]
Next, the operation will be described.
As shown in FIG. 1A, when the hold door 1 is in the door open state, the packings 28 and 29 of the shielding member 12 are held apart from the receiving member 33 and the sill 2 by the elastic force of the spring 22, respectively. In this state, the hold door 1 moves in the door closing direction.
[0023]
Immediately before the hold door 1 reaches the predetermined closing position H, the contact body 20 contacts the stopper 21 as shown in FIG. Even after this contact, the hold door 1 further moves in the door closing direction against the elastic force of the spring 22, and in response to this movement, each link bar 11 resists the elastic force of the spring 22 around the pin 16. It rotates counterclockwise, and this rotation displaces the shielding member 12 downward and the connecting plate 13 upward.
[0024]
As shown in FIG. 1C, when the hold door 1 reaches the closing position H and stops, the packing 29 of the shielding member 12 comes into contact with the upper surface of the sill 2 due to the downward displacement of the shielding member 12. The packing 28 comes into contact with and closely contacts the receiving material 33 provided on the hold door 1, and the gap G between the hold door 1 and the sill 2 is shielded by the shielding member 12.
[0025]
When the shielding member 12 is displaced downward, it is translated in the right direction along with the displacement, and the entire shielding member 12 is accommodated within the width of the hold door 1 by this parallel movement, and both edges of the shielding member 12 and the hold door 1 are moved. The side edges coincide with each other, so that the entire section in the width direction of the hold door 1 is accurately shielded.
[0026]
On the other hand, when the hold door 1 moves from the closing position H in the door opening direction, each link bar 11 rotates clockwise around the pin 16 by the elastic force of the spring 22 according to the start of the movement, and the shielding member. 12 is displaced upward and translated in the left direction.
[0027]
And the packing 29 leaves | separates from the upper surface of the sill 2 by the upward displacement of the shielding member 12, and the packing 28 leaves | separates from the receiving material 33 of the hold door 1, and the hold door 1 moves to the door opening direction in this state.
[0028]
Thus, when the hold door 1 is opened and closed, the contact state between the shielding member 12 and the sill 2 is released and kept in a non-contact state, and therefore the opening and closing operation of the hold door 1 is not hindered by the shielding member 12. It is performed smoothly and wear of the packing 29 of the shielding member 12 is prevented.
[0029]
Under the door-closed state in which the hold door 1 is stopped at the closing position H, the shielding member 12 is in close contact with the upper surface of the sill 2 through the packing 29 and is in close contact with the receiving member 33 of the hold door 1 through the packing 28. The shielding member 12 shields the gap G between the hold door 1 and the sill 2, so that when a fire occurs in the building, the inflow of smoke from the elevator hall into the hoistway is suppressed, and The road does not become a chimney, thus preventing the development of a fire and preventing the spread of smoke to other floors.
[0030]
In addition, when the packings 28 and 29 deteriorate due to secular change or the like, the packings 28 and 29 are removed from the shielding plate 25 and replaced with new packings 28 and 29.
[0031]
3 and 4 show a second embodiment. In this embodiment, one end of each link bar 11 constituting the link mechanism 10 is rotatable to the hold door 1 via a pin 18. The shield member 12 is horizontally installed between the other end portions of the link bars 11 via pins 17.
[0032]
Each link bar 11 is elastically urged counterclockwise in FIG. In addition, the rotation range of each link bar 11 in the counterclockwise direction is regulated by a regulation mechanism (not shown). In normal times, each link bar 11 is inclined to the right downward direction, and the shielding member 12 is connected to the threshold 2 with a predetermined value. It is held in a state separated by a distance.
[0033]
A pin-shaped contact body 42 is attached to a side surface on one end side of the shielding member 12, and a stopper 43 that can contact the contact body 42 is attached to the sill 2.
[0034]
The shielding member 12 has packings 28 and 29 at the upper and lower edge portions, and these packings 28 and 29 are displaced with respect to the upper surface of the receiving member 32 and the sill 2 provided on the back surface of the hold door 1 by the vertical displacement of the shielding member 12. The gap G between the hold door 1 and the sill 2 is shielded at the time of contact.
[0035]
In this embodiment, as shown in FIG. 1A, when the hold door 1 is in the door open state, the packings 28 and 29 of the shielding member 12 are removed from the receiving member 32 and the sill 2 by the elastic force of the spring 22, respectively. In this state, the holder 1 moves in the door closing direction.
[0036]
Immediately before the hold door 1 reaches the predetermined closing position H, the contact body 42 contacts the stopper 43 as shown in FIG. Even after this contact, the hold door 1 further moves in the door closing direction, and in response to this movement, each link bar 11 rotates clockwise around the pin 17 against the elastic force of the spring 22. When the posture of each link bar 11 changes from an inclined state to a substantially vertical state due to the movement, the shielding member 12 translates downward due to the change of the orientation, and the holder 1 reaches the closing position H and stops by this translation. Further, the packing 29 comes into contact with and closely contacts the upper surface of the sill 2, and the packing 28 comes into contact with and comes into close contact with the receiving member 32 provided on the hold door 1. A gap G between the two is shielded.
[0037]
On the other hand, when the hold door 1 moves from the closing position H in the door opening direction, each link bar 11 rotates counterclockwise around the pin 17 in accordance with the start of the movement. 11 changes from a substantially vertical state to an inclined state, and the change in the posture causes the shielding member 12 to translate upward, and the parallel movement causes the packings 28 and 29 to move away from the receiving member 32 and the sill 2, and in this state the hole The door 1 moves in the door opening direction.
[0038]
Thus, when the hold door 1 is opened and closed, the contact state between the shielding member 12 and the sill 2 is released and kept in a non-contact state, and therefore the opening and closing operation of the hold door 1 is not hindered by the shielding member 12. It is performed smoothly and wear of the packing 29 of the shielding member 12 is prevented.
[0039]
Under the door-closed state in which the hold door 1 is stopped at the closing position H, the packing 29 is in close contact with the upper surface of the sill 2, and the packing 28 is in close contact with the receiving member 32 of the HOLDER 1 and the HOLDER 1 and the sill. Therefore, when a fire occurs in the building, the inflow of smoke from the elevator hall into the hoistway is suppressed and the hoistway does not become a chimney. Can be prevented, and the diffusion of smoke to other floors can be prevented.
[0040]
In the case of the second embodiment, the connecting plate 13 in the first embodiment is unnecessary, and therefore the structure is simple and can be configured at low cost.
[0041]
In the second embodiment, when the hold door 1 is closed, the shielding member 12 is relatively moved toward the opposite side of the door stop edge 1 a of the hold door 1, so that the length of the shielding member 12 is the length of the hold door 1. When both ends of the shielding member 12 are held so as to coincide with both side edges of the hold door 1 when the hold door 1 is opened and closed, the leading edge 12a of the shielding member 12 is closed when the hold door 1 is closed. However, the front end edge 12a of the shielding member 12 is projected in advance from the door contact edge 1a when the hold door 1 is opened and closed. If this is done, the leading edge 12 a of the shielding member 12 can be made to coincide with the door stop edge 1 a of the hold door 1 when the hold door 1 is closed.
[0042]
FIG. 5 shows a third embodiment. In this embodiment, as in the case of the second embodiment, one end of each link bar 11 constituting the link mechanism 10 is connected via a pin 18. Thus, the shield member 12 is mounted horizontally between the other end portions of the link bars 11 via pins 17.
[0043]
Further, a reset pin 45 is provided on the side surface of the shielding member 12, and when the shielding member 12 is displaced downward from a position away from the sill 2, the reset pin 45 is connected to the back side of the stopper 43, that is, the contact body 42. Enters the opposite side surface and faces the side surface of the stopper 43.
[0044]
Each link bar 11 is biased counterclockwise about the pin 18 by the elastic force of the spring 22 during the opening and closing operation of the hold door 1 and is held in a state of being inclined downward to the right.
[0045]
From this state, as shown in FIG. 5A, the hold door 1 moves in the door closing direction, the contact body 42 comes into contact with the stopper 43, the movement of the shielding member 12 stops, and the hold door 1 When moving further to the door closing direction and moving to the closing position H, as shown in FIG. 5B, each link bar 11 rotates clockwise around the pin 18 and tilts downward to the right. The posture is changed from a neutral state standing upright to a left-tilting state.
[0046]
When the inclination angle when the link bar 11 is inclined downward to the right is θ ₁ , and the inclination angle when the link bar 11 is shifted from the downward inclination to the left downward inclination state is θ ₂ , θ located _1> theta ₂ of the relationship, so that when the link bar 11 is shifted from the inclined state of the right-down the inclination of the lower left, that is, when the hall door 1 has reached the closure position H is the shielding member 12 of the original The packing 29 is brought into close contact with the sill 2 by this displacement, and the packing 28 is brought into close contact with the receiving member provided on the back surface of the hold door 1, whereby the gap between the hold door 1 and the sill 2 is moved. G is shielded.
[0047]
The shielding member 12 is displaced most downward when the link bar 11 is in a vertical neutral state, and then slightly displaced upward. The difference in displacement is absorbed by the elastic deformation of the packings 28 and 29. Even when the link bar 11 shifts to the left-downward inclined state, the packings 28 and 29 maintain the contact state with the receiving member and the sill 2.
[0048]
When the link bar 11 is tilted downward to the right, the elastic force of the spring 22 acts in a direction in which the link bar 11 is rotated counterclockwise about the pin 18, and the link bar 11 is in a neutral position where it is vertical. When the slope is tilted to the lower left, the acting direction of the elastic force of the spring 22 is reversed and acts as a force for rotating the link bar 11 clockwise about the pin 18.
[0049]
In the case of the first and second embodiments, the elastic force of the spring 22 is applied to the contact bodies 20 and 42 and the stopper 21 when the holder 1 shown in FIGS. , 43 acts as a force for moving the hold door 1 in the door opening direction through the abutting portion, and therefore a holding means for overcoming the force and holding the hold door 1 at the closed position H is required.
[0050]
On the other hand, in the third embodiment, when the holder 1 shown in FIG. 5B is closed, the elastic force of the spring 22 is transmitted through the contact portion between the contact body 42 and the stopper 43. Acts as a force for moving the door 1 in the door closing direction, and therefore, the holder 1 can be stably held at the closing position H without requiring any holding means to hold the holder 1 closed.
[0051]
In the case of the third embodiment, when the hold door 1 moves from the closing position H in the door opening direction, the shielding member 12 moves integrally with the hold door 1 in the door opening direction. Immediately after that, the reset pin 45 provided on the side surface of the shielding member 12 comes into contact with the stopper 43, and by this contact, each link bar 11 rotates counterclockwise around the pin 18 to the right from the downwardly inclined state to the right. The state is switched to the downward inclined state, whereby the shielding member 12 is displaced upward, away from the sill 2 and the receiving member, and is brought into a non-contact state.
[0052]
Then, the reset pin 45 is disengaged from the upper end of the stopper 43 due to the upward displacement of the shielding member 12 and disposed on the upper side thereof, whereby the shielding member 12 moves together with the hold door 1 in the door opening direction.
[0053]
When the hold door 1 is opened and closed, the contact state between the shielding member 12 and the sill 2 is released and kept in a non-contact state, and therefore the opening and closing operation of the hold door 1 is smoothly performed without being obstructed by the shielding member 12. And wear of the packing 29 of the shielding member 12 is prevented.
[0054]
In each of the above embodiments, the hold door provided at the entrance / exit of the elevator hall is targeted. However, a car door as an elevator door is also provided at the entrance / exit of the elevator car, and this car door is used as a sill. Since it is structured to open and close along, it is possible to provide the car door with a shielding device having the same structure as in each of the above embodiments.
[0055]
【The invention's effect】
As described above, according to the present invention, the door can be smoothly opened and closed, and wear of the shielding member that shields between the door and the sill when the door is closed can be prevented over a long period of time. .
[Brief description of the drawings]
FIG. 1 shows a first embodiment of the present invention, and is a front view of a hold door provided at an entrance / exit of an elevator hall as seen from a hoistway side.
FIG. 2 is a cross-sectional view of the holder.
FIG. 3 shows a second embodiment of the present invention, and is a front view of a hold door provided at an entrance / exit of an elevator hall as seen from a hoistway side.
FIG. 4 is a cross-sectional view of the hold door.
FIG. 5 is a front view of a hold door provided at an entrance / exit of an elevator hall as viewed from a hoistway side according to a third embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Hold door, 2 ... Sill, 4 ... Guide shoe, 5 ... Guide groove, 10 ... Link mechanism, 11 ... Link bar, 12 ... Shield member, 13 ... Connecting plate, 20 ... Contact body, 21 ... Stopper, 22 ... Spring, 25 ... Shielding plate, 28, 29 ... Packing, 32 ... Receiving member, 33 ... Receiving member, 42 ... Abutting body, 43 ... Stopper.

Claims (1)

An elevator door that opens and closes along the threshold,
When the elevator door is provided with a shielding member that can contact the sill, and when the elevator door is opened and closed, the shielding member and the sill are kept in a non-contact state, and the elevator door is disposed at the closed position. A link mechanism that contacts the shielding member with the sill to shield a gap between the elevator door and the sill,
The link mechanism includes a plurality of link bars rotatably provided on the elevator door, the shielding member is installed between one end portions of the link bars, and the link bars are rotated by an elastic member. Immediately before the elevator door is moved in the door closing direction to reach the closing position, the link mechanism is The link mechanism is configured to abut against a stopper provided on the sill, and by the contact, the link bar rotates against the elastic member so that the shielding member is displaced downward to contact the sill. Is provided in the lower part on the back side of the elevator door, and operates within a range that does not protrude outward from the door contact edge of the elevator door,
The said elastic member is the elevator door shielding apparatus characterized by the elastic force acting in the direction which urges | biases the said elevator door to a door closing direction, when the said elevator door has arrange | positioned in the said closing position .

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