JP2023018591A - Slide control mechanism and reel device - Google Patents

Abstract

To suppress occurrence of flexure in an elongated body in a slide control mechanism that controls the movement of a moving object such as a door or curtain by winding the elongated body such as a wire.SOLUTION: A slide control mechanism including reels 21 on a sliding member such as door body 11, a first elongated body 16 bridging the reel 21 and a first fixed part 13, and a second elongated body 17 bridging the reel and a second fixed part 14. The reel 21 of the second elongated body 17 is the same reel as the reel 21 of the first elongated body 16 or a reel that rotates in unison therewith. The first elongated body 16 and the second long body 17 are wound on the reels 21 in opposite directions, and when the door body 11 moves, the winding and unwinding of the first elongated body 16 and the second elongated body 17 on the reels 21 are reversed.SELECTED DRAWING: Figure 1

Description

The present application relates to a slide control mechanism for controlling the moving state of slide members such as doors and curtains, and an invention of a reel device that can be suitably used when implementing the slide control mechanism.

Conventionally, as a slide control mechanism for controlling the moving state of a slide member such as a door or a curtain, as shown in Patent Documents 1 and 2, a reel provided on the slide member and a fixed portion such as the reel are provided. A slide control mechanism is known that includes an elongated body such as a passed wire and uses a spiral spring to control the rotation of the reel. In such a slide control mechanism, a single wire is used, for example, one end of the wire is fixed to either the left or right side of the door frame, and the other end is fixed to the reel, so that the power stored in the spiral spring is fixed. It was configured to move a slide member such as a door by force.

As reels using spiral springs, those disclosed in Patent Documents 3 and 4 are known. In this type of reel, a long body such as a wire is wound around the reel, and while energy is stored in the spiral spring, the long body is pulled out from the reel by the user's hand force, and the force stored in the spiral spring is used to pull the long body out of the reel. The body is wound on a reel. A lock mechanism is provided to control the rotation of the reel. Due to its structure, this lock mechanism is currently in the following operating state. That is, when the long body is pulled out and released, the rotation of the reel stops after the long body is slightly wound on the reel by the action of the spiral spring. Further, when winding the long body from the stopped state by the action of the spiral spring, it is necessary to release the hand after pulling out the long body slightly.

In order to use such a reel using a spiral spring, the slide control mechanisms of Patent Documents 1 and 2 are proposed to be provided with means for preventing slackness of the elongated body. Also, for example, after opening the door from left to right to a predetermined position and stopping it, if you try to close the door by moving the door from right to left with the force of the spiral spring, the door will move slightly from right to left. You will need to move. Thus, requesting the user to move the door in a direction opposite to the direction intended by the user results in asking the user to perform an unnatural motion. As a result, it is not only necessary to explain how to use it, but even if the user who received the explanation needs to confirm it one by one even if he/she understands it in his/her head, it causes confusion and makes it a user-friendly mechanism. hard to say.

Japanese Patent No. 5851058 Japanese Patent No. 4879004 Japanese Patent No. 4108024 Japanese Patent No. 3673177

SUMMARY OF THE INVENTION An object of the present invention is to suppress the occurrence of slackness in a slide control mechanism that controls the movement of a moving body such as a door or curtain by winding up a long body such as a wire.
An object of the present invention is to provide a reel device that can be suitably used for implementing the slide control mechanism described above.

The present invention comprises a reel provided on a slide member and an elongated body passed between the reel and a fixed portion, and a slide control for controlling the movement of the reel by controlling the rotation of the reel. In the mechanism, a double-wire slide control mechanism is provided.

A slide control mechanism according to the present invention comprises a first elongated body and a second elongated body. The first elongated body is passed between one fixing portion and the reel, and the second elongated body is the same reel as the reel to which the first elongated body is passed. Alternatively, it is provided between a reel that rotates together and the other fixed portion. Further, when the slide member is moved, winding and feeding of the first elongated body and the second elongated body on the reel are reversed.

In carrying out the present invention, the first elongated body and the second elongated body may be wound on separate reels. are wound around the reel grooves of the single reel in opposite directions, the number of parts can be reduced and downsizing can be achieved.

Further, the present invention provides a reel device that can be suitably applied to the implementation of the slide control mechanism using the double wire system. The reel device of the present invention includes a reel for winding a long body, a support for rotatably supporting the reel, one end connected to the reel and the other end connected to the support, and the A spiral spring that accumulates rotational energy as it rotates and rotates the reel with the accumulated rotational energy; The present invention relates to a reel device comprising a stop lever provided on one of the reel and the guide portion provided on the other of the reel and the support portion for guiding the stop lever. The guide section includes a temporary stop mechanism that temporarily fixes the stop lever with a force exceeding the rotational force of the spiral spring, and the force of the temporary stop mechanism moves the stop lever at a predetermined position of the guide section. By stopping, the rotation of the reel is temporarily stopped, and the reel is allowed to rotate when a force exceeding the force of the temporary stop mechanism is applied to the reel. be.

INDUSTRIAL APPLICABILITY The present invention can provide a slide control mechanism capable of suppressing the occurrence of slackness in a long body.
The present invention is able to provide a reel device capable of suppressing wasteful movement when a long body such as a wire is wound on a reel, stopped, and then moved again.

It is an explanatory view of the slide control mechanism according to the embodiment of the present invention seen from the front, (A) is a state in which the door body is closed, (B) is a state in which the door body is partially open, (C) is a door The door body is further opened, and (D) shows the door body closed again. It is an explanatory view of the double wire system of the same slide control mechanism, (A) is a state in which the door is partially opened, (B) is a state in which the door is slightly closed, and (C) is a state in which the door is slightly closed. This shows a state in which slackening of the elongated body is suppressed. 1 shows a winding device used in the same slide control mechanism, where (A) is a front view and (B) is a cross-sectional view taken along the line BB of (A). It is the perspective view which looked at the stop lever and reel of the winding device from the back side. 5A is a rear view of another lock mechanism that can be applied to the winding device of the same slide control mechanism, and FIG. 5B is a rear view of a guide portion in the lock mechanism of the winding device shown in FIG. 4. FIG. FIG. 5 is an explanatory view seen from the rear side showing the positional relationship between the guide portion and the guided portion in the locking mechanism of the winding device shown in FIG. 4 ;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(Overview of slide control mechanism)
The slide control mechanism according to this embodiment, as shown in FIGS. 1 and 2, semi-automatically moves a door body 11 as a slide member. In this example, three door bodies 11 are slidable in the left-right direction within the door frame 12, which is a fixed part, but two or one body may be used. Moreover, the sliding member is not limited to the door body 11, and the present invention can be applied to a window, a screen, a curtain, a gate, a carriage guiding member, and the like, which slide indoors and outdoors.

A reel device 15 is attached to the door body 11 . A first elongated body 16 such as a wire is passed between the reel device 15 and the first fixed portion 13 (vertical frame on the left side in FIG. 1). A second elongated body 17 such as a wire is passed between the reel device 15 and the second fixing portion 14 (right vertical frame). One end sides of the first elongated body 16 and the second elongated body 17 are fixed to the first fixing portion 13 and the second fixing portion 14, respectively. The other end side of each of the first elongated body 16 and the second elongated body 17 is wound around a reel 21 in the reel device 15 and the tip thereof is fixed to the reel 21 .

As the reel device 15, a device using a spiral spring 24 as shown in FIGS. 3 to 6 can be preferably used, but a device using another drive source such as an elastic body or an electric motor may be used. can also

The lengths of the first elongated body 16 and the second elongated body 17 can be variously changed according to the amount of movement required by the door body 11 and the reel device 15. For example, the lengths are shown in FIG. Thus, when the reel device 15 moves over the entire length (A+B) between the first fixed portion 13 and the second fixed portion 14, the lengths of the first elongated body 16 and the second elongated body 17 are The length (a+b) can be approximately equal to this.

In FIG. 2, the reel 21 on which the first elongated body 16 is wound and the reel 21 on which the second elongated body 17 is wound are shown separately. The elongated body 16 and the second elongated body 17 may be wound in opposite directions (to be wound in mutually opposite directions).
If it is implemented with separate reels 21, it is necessary to connect them so that they rotate together.
When a single reel 21 is used, the first elongated body 16 and the second elongated body 17 may have different reel grooves, but as shown in FIG. The width of the reel groove 34 can be reduced by making the groove 34 common. As will be described later, the sum (b+a) of the length b of the first elongated body 16 wound around the reel 21 and the length a of the second elongated body 17 wound around the reel 21 is It is always constant regardless of the position of the reel 21. Therefore, by matching the width of the reel groove 34 with the length of the first elongated body 16 and the second elongated body 17 wound thereon (preferably, the width of the reel groove 34 is 3B), when one elongated body is pulled out and a space becomes available, the other elongated body is wound up, thereby Since the space is filled, the state of regular winding can be maintained.

(Description of the double wire method)
Next, the double wire method employed in this slide control mechanism will be described. The double wire system comprises a first elongated body and a second elongated body, the first elongated body is passed between one fixing part and the reel, and the second elongated body is , is passed between the same reel as the reel to which the first elongated body is passed or a reel that rotates together with the reel, and the other fixed part, and the first elongated body and the second elongated body means a movement control method by means of a structure wound on the reel in the opposite direction. According to this method, when the slide member to which the reel is attached is moved, winding and unwinding of the first elongated body and the second elongated body on the reel are reversed.

(Concrete example)
This double wire system will be specifically described with reference to FIG.
In FIG. 2A, when the distance between the reel device 15 attached to the door body 11 and the first fixing portion 13 is A, and the distance between the reel device 15 and the second fixing portion 14 is B, , the length of the elongated body is as follows.
Length of first elongated body 16 pulled out from reel 21: a (A=a)
Length of first elongated body 16 wound around reel 21: b (B=b)
Length of second elongated body 17 pulled out from reel 21: b (B=b)
Length of second elongated body 17 wound around reel 21: a (A=a)

(move state)
FIG. 2(B) shows a state in which the door body 11 is moved to the left by a distance (X).
The distance between the reel device 15 and the first fixing portion 13: A-(X),
Distance between second fixing portion 14 and reel device 15: B+(X),
becomes.
Assuming that the reel 21 of the reel device 15 rotates correctly along with the movement of the door body 11,
The length of the first elongated body 16 pulled out from the reel 21: a-(X),
the length of the first elongated body 16 wound around the reel 21: b+(X);
length of the second elongated body 17 pulled out from the reel 21: b+(X);
length of the second elongated body 17 wound around the reel 21: a-(X);
becomes.

(Conventional cause of slackness)
FIG. 2(C) shows a state in which the first elongated body 16 is loosened when the door body 11 is moved to the left by the distance (X). Such slackness means that even if the door body 11 moves, the reel 21 of the reel device 15 cannot keep up with the movement, so that it does not rotate properly, rotates with a delay, or conversely rotates too much due to inertia. caused by FIG. 2C shows a state in which the reel 21 of the reel device 15 does not rotate at all as a representative example. In this state,
length of the first elongated body 16 pulled out from the reel 21: a;
length of the first elongated body 16 wound around the reel 21: b;
remains
(Distance between reel device 15 and first fixed portion 13: A−(X))<(Length of first elongated body 16 pulled out from reel 21: a)
becomes. As a result, slack for the length (X) is generated.
In the conventional structures shown in Patent Documents 1 and 2, such slack occurs because the second elongated body 17 does not exist.

(For double wire method)
On the other hand, in the double wire system of the present invention, since the second elongated body 17 exists, it is possible to suppress the occurrence of such slackness.
To move the door body 11 to the left by a distance (X),
length of the second elongated body 17 pulled out from the reel 21: b+(X);
length of the second elongated body 17 wound around the reel 21: a-(X);
must be
However, in order to reach this state, the reel 21 must be rotated by the length (X). resulting in,
The length of the first elongated body 16 pulled out from the reel 21: a-(X),
the length of the second elongated body 17 wound around the reel 21: b+(X);
becomes.
As a result, as mentioned above,
length of the first elongated body 16 pulled out from the reel 21: a;
length of the second elongated body 17 wound around the reel 21: b;
cannot occur.

Therefore, in the double wire system, the presence of the second elongated body 17 can suppress the occurrence of slackness. In other words, in the double wire method, the sum of the length of the first elongated body 16 and the length of the second elongated body 17 is the distance between the first fixing portion 13 and the second fixing portion 14. The position and rotation of the reel 21 of the reel device 15 are controlled so as to be equal, and the door body 11 is moved according to the control.

In order to reliably suppress the occurrence of slackness as described above, the first elongated body 16 and the second elongated body 17 are not slackened in advance, preferably in a state in which tension is applied. It is preferably provided between the first fixing portion 13 and the second fixing portion 14 and the reel 21 . In addition, in order to cope with fine adjustment at the time of installation and occurrence of slack due to aging, It is also preferred that the connection between is made through a tension adjustment means such as a screw or feed screw that advances and retreats.

(Reel device applicable to double reel system)
In the embodiment of the double reel system described above, the reel device 15 shown in FIGS. 3 to 6 can be used as a device for winding the first elongated body 16 and the second elongated body 17 .
The reel device 15 has a reel 21 and a spiral spring 24 housed inside a casing 22 consisting of a case body 22a and a case lid 22b, which are fixed to the door 11. As shown in FIG. The reel 21 is rotatably supported by the casing 22 by rotatably inserting a shaft 23 provided in the casing 22 into a shaft hole 27 in the center of the reel 21 . The spiral spring 24 has its base end fixed to the shaft 23 and its tip end fixed to the reel 21 . One end sides of the first elongated body 16 and the second elongated body 17 are fixed to the reel 21 , and the other end sides thereof are drawn out from the first outlet 25 and the second outlet 26 . there is

The first elongated body 16 and the second elongated body 17 are wound around a single reel groove 34 of the reel 21 in opposite directions. In this example, the counterclockwise direction, which is the direction of the arrow in FIG. 3A, is the direction in which the first elongated body 16 is wound (in other words, the direction in which the second elongated body 17 is fed out), and the reel is reeled in this direction. As 21 rotates, spiral spring 24 is wound up to store rotational energy. When the spiral spring 24 is released, the stored rotational energy causes the reel 21 to rotate in the reverse direction (clockwise direction), the first elongated body 16 is paid out, and the second elongated body 17 is wound around the reel 21. be taken.
Regarding the technical contents of the 2-wire wire winding for one wire groove,
If the wire winding number on the drum and the width of the drum groove are the same,
When there is a space for one wire, the next wire to be wound fits into it and becomes a line winding technology.

(lock mechanism)
Furthermore, in this example, the reel device 15 has a lock mechanism 31 . The lock mechanism 31 includes a stop lever 32 shown in FIGS. 3 to 5 and a guide portion 33 that guides the stop lever 32. As shown in FIG. In this example, as shown in FIG. 3B, the guide portion 33 is provided on the end surface of the reel 21 on the back side, and the stop lever 32 is arranged on the back side thereof.
Although the stop lever 32 is attached to the casing 22 in this example, it can also be attached to the reel 21 . On the other hand, the guide part 33 is provided on the reel 21 in this example, but can also be provided on the casing 22 .

The stop lever 32 is rotatably attached to the casing 22 at an attachment portion 35 on the base end side, and a guided portion 36 is provided on the tip end side of the stop lever 32 so as to protrude toward the guide portion 33 of the reel 21 . there is An elastic portion may be provided at the tip of the stop lever 32 or the like to bias the guided portion 36 so that it is reliably guided to the guide groove of the guide portion 33 .

The stop lever 32 controls the rotation of the reel 21 and the casing 22 by being guided by the guide portion 33 and moving with the relative rotation of the reel 21 and the casing 22 .

With this control, the locking mechanism 31 rotates the reel 21 against the force of the flat spiral spring 24 as described above by moving the door 11 by the user, and pulls out the first elongated body 16 (second When the rotation of the reel 21 is stopped by stopping the opening of the door 11 halfway and the hand is released from the door 11, the spiral spring 24 temporarily prevents the reel 21 from rotating. It is intended to stop at The outline of the movement will be sequentially explained with reference to FIG.

(Fig. 1(A): fully closed state)
The door body 11 is in the fully closed state, and the reel device 15 attached to the door body 11 is also in the initial position. In this state, the spiral spring biasing by the reel 21 of the reel device 15 may not be applied. I don't mind.

(Fig. 1(B): half-open state)
The door body 11 is opened halfway by the user. In other words, the reel 21 of the reel device 15 winds up the first elongated body 16 (feeds out the second elongated body 17) against the bias of the spiral spring.
When the user releases the door body 11 in this state, the reel 21 slightly reverses and then temporarily stops.

(Fig. 1(C): further opening the door body 11 from the half-open state)
When the door 11 is to be further opened from the half-open state, the user pulls it in the opening direction (to the right in the drawing). As a result, the door body 11 moves in the same direction, and the first elongated body 16 is fed out from the reel 21 of the reel device 15 while the spiral spring 24 stores rotational energy (the second elongated body 17 is wound up). .

(Fig. 1 (D): Close the door body 11 from the half-open state)
When the door 11 is closed from the half-open state, the user slightly moves the door 11, and the rotational energy stored in the spiral spring winds the first elongated body 16 onto the reel 21 of the reel device 15 (second 2 Unleash the elongated body 17). As a result, the door body 11 moves in the closing direction (leftward direction in the figure).

(Structure of lock mechanism)
An example of this lock mechanism (especially an example of the guide groove of the guide portion 33) will be described with reference to FIG. 5(A). The guide groove shown in FIG. 5A is substantially the same as the guide grooves disclosed in Patent Documents 3 and 4 and Japanese Utility Model Publication No. 4-20860, unlike the other drawings. This guide groove consists of an outer peripheral path 41 around which the guided portion mainly circulates when the first elongated body 16 is wound, and an inner peripheral path 42 around which the guided portion mainly circulates when the first elongated body 16 is pulled out. It has However, contrary to the above, the path along which the guided portion 36 mainly rotates when the first elongated body 16 is pulled out is defined as the outer path 41, and the guided portion 36 mainly travels when the first elongated body 16 is wound. The inner peripheral path 42 may be the path to go around.
As already explained, the elongated body includes the first elongated body 16 and the second elongated body 17 whose rotation directions are opposite to each other. Unless otherwise specified, the rotation direction of the winding and drawing reels 21 will be described with the first elongated body 16 as the center.

In this example, both the outer path 41 and the inner path 42 are circular paths, and the space between the outer path 41 and the inner path 42 is partitioned by a raised wall or the like.
Further, in this example, between the outer peripheral path 41 and the inner peripheral path 42, a connecting path 43 and a connecting path 44 are arranged.
The connecting path 43 serves as a path for guiding the guided portion 36 from the outer peripheral path 41 to the inner peripheral path 42 .
The connecting path 44 serves as a path for guiding the guided portion 36 from the inner peripheral path 42 to the outer peripheral path 41 . The communication path 44 has at least one folded portion 45 . This folded portion 45 is a dead end part of the path of the connecting path 44, and the guided portion 36 entering the connecting path 44 from the inner peripheral path 42 temporarily stops at the folded portion 45 and is reeled in the opposite direction. When 21 rotates, the guided portion 36 advances from the folded portion 45 to the outer peripheral path 41 .
Therefore, the guided portion 36 advances from the inner peripheral path 42 to the outer peripheral path 41 through the communication path 44 in a so-called switchback manner.
In this example, two connecting paths 43 and two connecting paths 44 are provided point-symmetrically.

(Relationship with movement of door body 11)
(From closed (Fig. 1(A)) to open (Fig. 1(B))
In use, the closed door 11 is first opened to the right by the user's hand as shown in FIG. 1(A). At that time, the reel 21 rotates clockwise against the biasing force of the flat spiral spring 24, and the first elongated body 16 is pulled out from the reel 21 (the second elongated body 17 is wound on the reel 21).

At this time, since the guided portion 36 of the stop lever 32 is provided in the casing 22, it moves along the path of the guide portion 33 of the reel 21 in the direction opposite to the apparent rotational direction of the reel 21. , and as shown in FIG. Here, in the following description, the rotation direction of the reel 21 will be described as viewed from the front side according to FIG. will be described with reference to FIG. 4 and subsequent drawings showing the state viewed from the rear side, and the rotational movement direction and the like as viewed from the rear side. Therefore, the rotational direction of the reel 21 and the rotational direction of movement of the guided portion 36 are the same.
That is, when the reel 21 rotates in the direction in which the first elongated body 16 is pulled out from the reel 21, the guided portion 36 moves so as to rotate clockwise (right rotation R in FIG. 5(A)). From the road 41, it enters the inner peripheral path 42 through the connecting path 43, and circulates in the inner peripheral path 42 with a clockwise rotation R. In order to prevent the guided portion 36 from entering the communication path 44 by mistake, a structure for preventing erroneous intrusion is adopted, such as providing a height difference or an inclination between the inner peripheral path 42 and the communication path 44 . In addition, in order to realize the movement as intended by the designer (that is, the movement of the guided portion 36 described below), a structure is adopted to prevent erroneous intrusion, such as providing steps and inclinations between other paths. there is

(Open (Fig. 1(B))
Next, when the door body 11 is released and the external force acting on the reel 21 is removed, the biasing force of the spiral spring 24 causes the reel 21 to rotate counterclockwise (counterclockwise rotation L). As a result, the guided portion 36 enters the communication path 44 from the inner circumferential path 42, reaches the folded portion 45, and stops at the end thereof. As a result, the rotation of the reel is stopped, and the first elongated body 16 is kept pulled out by a predetermined length. Therefore, when the user releases the door body 11, the door body 11 slightly moves in the closing direction and stops.
In order to prevent the guided portion 36 from accidentally entering the connecting path 43, a structure is adopted to prevent erroneous intrusion, such as providing a height difference between the outer peripheral path 41 and the connecting path 44. FIG.

(Further open (Fig. 1(C))
When the door body 11 is further opened by the user's hand, the reel 21 rotates clockwise (clockwise rotation R) against the biasing force of the spiral spring 24 . At this time, the guided portion 36 enters the outer path 41 from the latter half of the communication path 44 from the folded portion 45 . Furthermore, the guided portion 36 moves clockwise (right rotation R) in the outer path 41, enters the inner path 42 from the outer path 41 via the connecting path 43, and circles in the inner path 42 in the same direction.
In this way, when the user releases the door body 11 in the further opened state, the door body 11 moves in the same manner as described above (opening (FIG. 1B)), and the door body 11 is folded back at the folded portion 45. Stop.

(Close movement (Fig. 1(D))
Finally, in order to close the door body 11 from the state shown in FIG. 1B where the door body 11 is open and stopped, the door body 11 is moved to the left if it is a normal door. However, in this embodiment, the guided portion 36 is positioned at the folded portion 45, resulting in a dead end state (switchback structure).
Therefore, it is necessary for the user to slightly move the door 11 in the opening direction (to the right). As a result, the reel 21 rotates clockwise (right rotation R), and the guided portion 36 enters the outer path 41 from the latter half of the communication path 44 from the folded portion 45 . When the door body 11 is released in this state, the reel 21 rotates counterclockwise (counterclockwise rotation L) due to the biasing force of the spiral spring 24, the guided portion 36 rotates in the outer peripheral path 41, and finally The door body 11 is closed by returning to the state of FIG. 1(A).

(Structure of FIG. 5(B))
On the other hand, with the structures of FIGS. 4 and 5B, the door can be closed by moving the door body 11 to the left like a normal door.
A temporary stopping mechanism 46 is provided in the connecting path 44 of the guide portion 33 in FIG. 5B in place of the folding portion 45 of the previous example. The temporary stopping mechanism 46 has a blocking portion 47 with a tip protruding into the communication path 44 to block the path of the communication path 44 and temporarily stop the movement of the guided portion 36 . As a result, the connecting path 44 can be extended in one direction without being switched back as in the previous example.

Therefore, when the reel 21 attempts to rotate counterclockwise (counterclockwise rotation L) due to the urging force of the flat spiral spring 24 , the guided portion 36 traveling along the communication path 44 is temporarily stopped by the blocking portion 47 . In this example, the temporary stop mechanism 46 is composed of a leaf spring made of metal or synthetic resin, and has a force exceeding the biasing force of the flat spiral spring 24 to project the blocking portion 47 into the path of the communication path 44 . It should be noted that the force exceeding the biasing force of the spiral spring 24 is not a direct comparison of the forces of the springs, but counteracts the force that causes the guided portion 36 to move in the communication path 44 by the rotational force of the biasing force of the spiral spring 24. It is sufficient if the force is capable of stopping the movement.
The temporary stop mechanism 46 is composed of a leaf spring made of metal or synthetic resin, and has a force exceeding the biasing force of the flat spiral spring 24 to project the blocking portion 47 into the path of the communication path 44 . It should be noted that the force exceeding the biasing force of the spiral spring 24 is not a direct comparison of the forces of the springs, but counteracts the force that causes the guided portion 36 to move in the communication path 44 by the rotational force of the biasing force of the spiral spring 24. It is sufficient if the force is capable of stopping the movement.

The temporary stop mechanism 46 using the plate spring body is provided with a deceleration section 49 in front of the blocking section 47 (base end side). The deceleration part 49 is configured to gradually narrow the path of the communication path 44 by gradually tilting and protruding into the path of the communication path 44 . As a result, the guided portion 36 continues to move while receiving the elastic force of the plate spring body by abutting the decelerating portion 49 at the delivery of the blocking portion 47 . As a result, a braking force is applied to the guided portion 36 to gradually decelerate and finally stop at the blocking portion 47 . The angle of the guided portion 36 with respect to the advancing direction is larger in the intercepting portion 47 than in the decelerating portion 49, but various structures can be employed as long as the above-mentioned effects are exhibited.

(Movement when temporary stop mechanism 46 is employed)
(Fig. 1 (A) → (B))
As in the previous example, when the door body 11 is opened, the guided portion 36 of the stop lever 32 rotates clockwise (clockwise rotation R in FIG. It enters the inner peripheral path 42 and circulates in the inner peripheral path 42 with a clockwise rotation R (FIG. 6(A)).

(Fig. 1(B))
When the door body 11 is released and the external force acting on the reel 21 disappears, the biasing force of the spiral spring 24 causes the reel 21 to rotate counterclockwise (counterclockwise rotation L). As a result, the guided portion 36 enters the communication path 44 from the inner peripheral path 42, reaches the temporary stop mechanism 46, and is temporarily stopped by the blocking portion 47 (FIG. 6B). As a result, the rotation of the reel is stopped, and the first elongated body 16 is kept pulled out by a predetermined length.
Therefore, when the user releases the door body 11, the door body 11 slightly moves in the closing direction and stops.

(Fig. 1 (B) → (C))
Next, when the door body 11 is further opened by the user's hand, the reel 21 rotates clockwise (clockwise rotation R) against the biasing force of the spiral spring 24 . As a result, the guided portion 36 reaches the outer path 41 through the branch path 48 connecting the outer path 41 and the front side of the temporary stop mechanism 46 of the communication path 44 . Furthermore, the guided portion 36 enters the inner peripheral path 42 from the outer peripheral path 41 via the connecting path 43, and circulates in the inner peripheral path 42 with the clockwise rotation R (FIG. 6(C)).
Then, when the door body 11 is released, the reel 21 is rotated counterclockwise (counterclockwise rotation L) by the urging force of the spiral spring 24 in the same manner as described above. As a result, the guided portion 36 enters the communication path 44 from the inner peripheral path 42, reaches the temporary stop mechanism 46, and is temporarily stopped by the blocking portion 47 (FIG. 6B).

(Fig. 1 (C) → (D))
Finally, to close the door body 11, the door body 11 should be moved to the left in the same manner as a normal door. As a result, the reel 21 rotates counterclockwise (counterclockwise rotation L). The guided portion 36 retracts the blocking portion 47 of the temporary stop mechanism 46 against its elasticity by the force of the user's hand in addition to the biasing force of the spiral spring 24 . In this way, the guided portion 36 moves forward while pushing away the blocking portion 47 and enters the outer peripheral passage 41 from the latter half of the connecting passage 44 (FIG. 6(D)). Once the guided portion 36 has passed through the blocking portion 47 of the temporary stop mechanism 46, even if the door body 11 is released, the biasing force of the spiral spring 24 causes the reel 21 to rotate counterclockwise (counterclockwise rotation L). As a result, the guided portion 36 rotates in the outer path 41 (FIG. 6(E)), so that the door body 11 automatically closes to the end (FIG. 1(A)).

(Example of modification of temporary stop mechanism 46, etc.)
The temporary stop mechanism 46 may be implemented by a leaf spring body made of metal or synthetic resin, or may be configured by a plurality of members, or may be implemented by using an urging structure with other structure such as a helical spring. Alternatively, magnetic resistance may be used. In addition, the reel using the temporary stop mechanism 46 can be suitably applied to the implementation of the double-wire slide mechanism, but it may be applied to other mechanisms and structures.

11 Door body 12 Door frame 13 First fixing part 14 Second fixing part 15 Reel device 16 First elongated body 17 Second elongated body 21 Reel 22 Casing 23 Shaft 24 Spiral spring 25 First outlet 26 Second outlet 27 Shaft hole 31 Lock mechanism 32 Stop lever 34 Reel groove 33 Guide part 35 Mounting part 36 Guided part 41 Outer path 42 Inner path 43 Transfer path 44 Connecting path 45 Folding part 46 Temporary stop mechanism 47 Blocking part 48 Branch path 49 Reduction part

Claims (3)

A slide control mechanism comprising a reel provided on a slide member and an elongated body passed between the reel and a fixed portion, wherein the slide control mechanism controls the movement of the reel by controlling the rotation of the reel,
comprising a first elongated body and a second elongated body,
The first elongated body is passed between one fixing portion and the reel,
The second elongated body is passed between the same reel as the reel to which the first elongated body is passed or a reel that rotates together with the reel and the other fixed part,
A slide control mechanism, wherein the winding and unwinding of the first elongated body and the second elongated body on the reel are reversed when the slide member is moved. 2. The slide according to claim 1, wherein said first elongated body and said second elongated body are wound together in said reel groove of said single reel in opposite directions. control mechanism. a reel for winding the elongate body;
a support portion that rotatably supports the reel;
a spiral spring, one end of which is connected to the reel and the other end of which is connected to the support portion, for accumulating rotational energy as the reel rotates and for rotating the reel with the accumulated rotational energy;
A lock mechanism for stopping rotation of the reel,
The lock mechanism includes a stop lever provided on one of the reel and the support portion, and a guide portion provided on the other of the reel and the support portion for guiding the stop lever. In the reel device with
The guide portion includes a temporary stop mechanism that temporarily fixes the stop lever with a force exceeding the rotational force of the spiral spring,
Temporarily stopping the rotation of the reel by stopping the stop lever at a predetermined position of the guide portion by the force of the temporary stop mechanism;
A reel device configured to allow the reel to rotate when a force exceeding the force of the pause mechanism is applied to the reel.

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