JP7138910B2 - Slide rail with automatic retraction device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slide rail with an automatic retraction device, which is particularly used as a slide rail for drawers, grill cookers, and the like.

Conventionally, a number of devices have been provided as the automatic retraction device.
In the automatic retraction device, in addition to the retraction mechanism, an air damper or an oil damper is combined to add a brake function to the retraction operation (for example, Patent Document 1).
In Patent Document 1, a retaining plate 4 that is urged in a retracting direction by a retracting spring to perform a retracting operation is directly connected to an air damper 2, and the air damper 2 is pushed by the retaining plate 4 when the retaining plate 4 is retracted. , a braking action is generated, and the air damper is restored by directly extending the air damper with the retaining plate 4 at the time of pulling out.
Then, such an automatic retraction device is combined with the slide rail composed of the outer rail A and the inner rail B so that the slide rail is automatically retracted.

However, in the configuration of Patent Document 1, the automatic retraction device is combined with the slide rail in a state close to the slide rail, so in actual use, the automatic retraction device must be installed in addition to the slide rail. I needed to secure a place.
Therefore, an automatic retraction device with a brake function that is integrally combined with a slide rail has been provided (for example, Patent Document 2).
In addition, in Patent Document 2, an automatic pull-in device is installed on the outer rail of a three-rail type slide rail consisting of an outer rail, an intermediate rail, and an inner rail, and the automatic pull-in device engages with the inner rail side, thereby automatically It is configured to be able to perform a pull-in operation and an operation to restore from the pull-in to the state before the pull-in (pull-in standby state).

More specifically, the slide plate 3 is mounted on the track so as to be slidable in the sliding direction of the slide rail, and the slide plate 3 is biased toward the retraction side of the slide rail by a tension coil spring (anti-tension element set) 6. When the slide plate 3 is pulled out, the slide plate 3 is maintained in the pulled out state by the positioning rod 5, and the guide portion 81 provided on the inner rail engages with the positioning rod 5, The holding state of the positioning rod 5 is released, and the slide plate 3 is drawn in while the guide portion 81 of the inner rail (slide guide plate) 8 is engaged with the positioning rod 5 by the biasing force while pulling the inner rail 8. is.

At this time, since the slide plate 3 moves while pushing the shock absorber 4, the shock absorber 4 is braked and retracted.
When the inner rail 8 is pulled out from the fully retracted state, the guide part 81 is engaged with the positioning rod 5, so that the slide plate 3 is pulled out in conjunction with the pulling out operation of the inner rail 8.例文帳に追加At this time, since the slide plate 3 and the tip of the shock absorber 4 on the sliding side are connected, the shock absorber 4 is pulled out according to the movement of the slide plate 3 .

When the slide plate 3 moves to the set end of the track, the slide plate 3 cannot move from there, and the engagement load between the positioning rod 5 and the guide portion 81 increases. When the inner rail 8 is pulled out further, the engagement load increases, and the positioning rod 5 moves along the slide groove 221 due to the groove shape of the guide portion 81 in a direction perpendicular to the sliding direction of the slide rail (the width direction of the slide rail). As a result, the engagement state between the positioning rod 5 and the guide portion 81 is released.
The positioning rod 5 is inserted into the lock opening 2211 of the slide groove 221 to prevent the slide plate 3 from moving toward the retraction side due to the force of the tension coil spring 6 .
In this way, the pull-in waiting state is restored.
In the retraction standby state, the positioning rod 5 enters the locking opening 2211, the positioning rod 5 is pressed against the side surface of the locking opening 2211 on the retraction side by the biasing force of the tension coil spring 6, and the pressing frictional force causes the positioning rod 5 to move. is prevented from moving.

In this way, the retraction device is configured to operate by parts on the outer rail side and the inner rail side, but in the case of a three-rail type slide rail, there is an intermediate rail, Above, in the contraction process of the rail, the intermediate rail does not always have the same amount of movement with respect to the sliding movement of the outer rail and the inner rail. Before the guide portion 81 of the intermediate rail is engaged, the intermediate rail may first move to the retraction side, and the leading end surface of the intermediate rail in the contracting direction may collide with the slide plate 3 .
In this state, contraction movement of the intermediate rail is restricted, but sliding movement of the outer rail and the inner rail is not hindered.
Then, when the retracting device is operated, the slide plate 3 is moved, so that the intermediate rail can be moved only for the movement of the slide plate 3.例文帳に追加

However, in the retraction standby state, the positioning rod 5 enters the locking opening 2211, and the positioning rod 5 is prevented from moving only by the contact friction force of the positioning rod 5, so that the retraction device slides in the retraction standby state. When the intermediate rail collides with the plate 3, the positioning rod 5 may be disengaged from the locking opening 2211 due to the vibration at the time of collision, and the retraction operation may start.

U.S. Pat. No. 6,736,471 Tomi No. 3152183

An object of the present invention is to provide a slide rail with an automatic retraction device that does not easily malfunction.

Therefore, in order to solve the above problems, the present invention is configured as a first means by installing an automatic retraction member on the outer rail of a three-rail type slide rail consisting of an outer rail, an intermediate rail, and an inner rail, and an inner rail. An engaging portion that engages the automatic retraction member is installed on the rail, and the automatic retraction member mainly includes a main body fixed to the outer rail, a slide member movable in the sliding direction of the slide rail, and a slide member. It is composed of an engaging member that is installed inside and moves together with the sliding member, and biasing means that biases the sliding member in the retracting direction of the slide rail, and the sliding member pushes the engaging member to move it toward the retraction side. The engaging member presses the slide member to move it to the drawer side against the urging force, and abuts on the lock receiving portion provided on the main body side, thereby maintaining the slide member in the drawn out state. The inner rail is moved to the retracted side by engaging with the engaging portion of the inner rail, and the engaging portion engages with the retracted engaging member to pull out the engaging member. The automatic retraction member and the engaging portion constitute an automatic retraction device. In the automatic retraction type slide rail equipped with the automatic retraction device, the engagement member is provided on the main body side. It moves in a slide groove formed long in the slide direction of the slide rail and is movably installed in the slide member, and rotates along the slide groove near the slide end that slides in the pull-out direction. With the rotation, the engaging member comes into contact with the lock receiving portion provided on the main body side, and the contact prevents the movement of the slide member in the retracting direction of the slide rail, thereby preventing the automatic retraction member from moving. When the retraction standby state is maintained, and the engagement member is rotated in the returning direction with respect to the rotation direction from the retraction standby state, the contact between the engagement member and the lock receiving portion is released. When the slide member moves to the retraction side in the retraction standby state, the pressing portion provided on the slide member is pressed against the engagement member in the direction in which the contact between the engagement member and the lock receiving portion is released. It applies a pressing force to rotate in the opposite engagement direction . is provided in the pull-in standby portion of the slide groove formed by slant to the side .

Next, in order to solve the above problems, the second means of the present invention is, in addition to the first means, that the engaging member is bent on the drawer side near the end on the drawer side. Then, along the slide groove formed in a substantially L shape, the tip rotates in a direction orthogonal to the sliding direction . The pressing portion of the riding member is provided at a portion facing the locking receiving portion with the engaging member therebetween.

According to the first means of the present invention, in the process of contracting the slide rail from the extended state, the intermediate rail first moves to the retraction side, and the end surface of the retraction side of the intermediate rail comes into contact with the slide member. is pressed toward the retraction side, the movement of the slide member presses the engaging member in the direction in which the engaging member engages with the lock receiving portion.
In particular, since the lock receiving portion is inclined toward the pull-in side as it separates from the straight portion, when the pressure receiving portion of the engaging member is pressed, the engaging member abuts against the locking receiving portion. Furthermore, since the engagement member bites into the lock receiving portion like a wedge, the standby state of the engagement member is not released.
Further, the slide member is biased toward the retraction side by the biasing means in the standby state for retraction, and the biasing force keeps the engaging member in the retraction standby state constantly engaged with the engaging member by the pressing portion of the slide member. Since the engaging member is pressed in the direction in which the receiving portion engages, the pull-in waiting state is not easily released due to vibration or impact.

According to the second means of the present invention, the leading end of the engaging member rotates in the width direction of the slide rail along the L-shaped slide groove with respect to the slide direction, A contact portion is provided on the retracted side in the rotated state, and by contacting the lock receiving portion, the engaging member is prevented from moving to the retracted side, and the pressing portion of the slide member presses the engaging member. Since it is provided at a portion facing the pinching lock receiving portion, when a force acts on the slide member to move it toward the retraction side, the engaging member is reliably pressed against the locking receiving portion, and the engaging member and the locking receiving portion are separated. Pressing in the engaging direction is possible with a simple structure.

1 is a perspective view of a slide rail with the present invention in an extended state; FIG. 1 is a retracted perspective view of a slide rail with the present invention; FIG. 1 is an exploded perspective view of a slide rail with the present invention; FIG. It is a basic sectional view of a slide rail. 1 is an exploded perspective view of an automatic retraction member; FIG. 1 is a perspective view of an automatic retraction member; FIG. Six-sided view of slide member Six views of the engaging member Six views of the engaging body FIG. 4 is an explanatory view showing the relationship between the automatic retracting member and the engaging body when the automatic retracting member is retracted; FIG. 5 is an explanatory view showing the relationship between the automatic retracting member and the engaging body while the automatic retracting member is being pulled out. FIG. 5 is an explanatory view showing the relationship between the automatic retracting member and the engaging body when the automatic retracting member is pulled out; Explanatory drawing which shows an engaging member, an engaging part, and the extraction process in a slide groove. Explanatory drawing which shows an engaging member, an engaging part, and the pulling-in process in a slide groove. FIG. 10 is an explanatory view when the intermediate rail collides with the automatic retraction member being pulled out; FIG. 15 is an enlarged view of part A in FIG. 15; FIG. 13D is an enlarged view of FIG.

The present invention is a three-rail type slide rail comprising an outer rail, an intermediate rail and an inner rail. The members mainly include a main body fixed to the outer rail, a slide member movable in the sliding direction of the slide rail, an engaging member installed in the slide member and moving together with the slide member, and the slide member. The sliding member presses the engaging member to move it toward the retracted side, and the engaging member presses the sliding member against the urging force. The sliding member is maintained in the drawn-out state by moving it to the drawer side and coming into contact with the lock receiving portion installed on the main body side, and the inner rail is held by engaging with the engaging portion of the inner rail. The engaging portion engages with the retracted engaging member to move the engaging member to the drawing side, and the automatic retracting member and the engaging portion automatically In the automatic retraction type slide rail equipped with the automatic retraction device, the engaging member is formed elongated in the sliding direction of the slide rail provided on the main body side, and near the end of the drawer side. , the drawer side is bent to move in the slide groove along the slide groove formed in a substantially L shape, and is movably installed in the slide member, and near the slide end that slides in the drawer direction, the tip is and a contact portion is provided on the pull-in side of the rotating state of the engaging member, and the contact portion moves into the slide groove along with the rotation. The automatic retraction member maintains a retraction standby state by contacting with a locking receiving portion provided at the substantially L-shaped bent portion and preventing movement of the slide member in the retraction direction of the slide rail by the contact, and When the engaging member is rotated in the returning direction from the retraction standby state, the contact between the engagement member and the lock receiving portion is released. Then, when the slide member moves to the retracted side, a pressing portion provided at a portion of the slide member facing the locking receiving portion across the engaging member pushes the engaging member into contact between the engaging member and the locking receiving portion. A pressing force is applied to rotate in the engagement direction opposite to the direction in which contact is released.

The first embodiment will be described in detail below with reference to the accompanying drawings.
In FIG. 1, the left oblique downward direction is the pull-in side, the right oblique upward direction is the drawer side, and both the pull-in side and the drawer side are the slide directions.
1 to 4, reference numeral 1 indicates an outer rail, reference numeral 2 indicates an inner rail, reference numeral 3 indicates an intermediate rail, reference numeral 4 indicates a ball holding plate of the outer rail 1, and reference numeral 5 indicates an inner rail 2. Ball holding plates 400 . 100 are configured.
Reference numeral 7 indicates an automatic retraction member provided on the inner surface of the retraction side end of the outer rail 1, and reference numeral 8 indicates an engaging member provided on the retraction side inner surface of the inner rail 2 corresponding to the automatic retraction member 7. showing.

The outer rail 1 consists of upper and lower bent edges 11, 11 having ball guide grooves in the longitudinal direction of the inner surface formed by bending both short ends of a metal thin strip into an inward circular arc shape, and a main body (fixed body) of furniture or the like. ), the substrate 12 is formed in a substantially channel shape.
An opening 121 is provided in a part of the drawing-in side of the substrate 12 (slightly on the drawing-out side of the automatic retracting member 7). A fixed-side moving stopper (not shown) is formed with which the drawer-side end of 4 abuts.
An automatic retraction member 7 is attached near the retraction side end of the outer rail 1 thus formed.

The intermediate rail 3 has a size that can be inserted into the outer rail 1, and the length from the outer rail 1 to the drawn end of the outer rail 1 from the drawn end of the slide member 71 in the retracted state of the automatic retracting member 7 described later. , the substrate 30 and the upper and lower bent edges 31, 31 form a substantially channel shape in the same direction as the outer rail 1, and the balls 400 are formed on the outer surfaces of the upper and lower bent edges 31, 31 in the sliding direction. It has outer surface side ball sliding grooves that roll, and inner surface side ball sliding grooves in which the balls 500 roll in the sliding direction are provided on the inner surfaces of the upper and lower bent edges 31, 31. .
At the upper and lower ends of the board 30 on the lead-in side, there are ball holding plates 4 whose lead-side ends abut on retainer front stoppers (not shown) of the outer rail 1 when the intermediate rail 3 is fully drawn. A ball holding plate rear stopper (not shown) is formed in contact with the pull-in side end to regulate the maximum pull-out amount of the intermediate rail 3 , and the inner rail 2 extends maximally on the inner surface of the pull-out side end of the base plate 30 . When the inner rail 2 is retracted to the shortest contracted state, the inner rail front end stopper formed at the drawer side end of the inner rail 2 contacts with the drawer side end of the ball holding plate 5. (not shown) is detachably provided.

A plurality of balls 400 . It is formed

The inner rail 2 is formed to have substantially the same length as the outer rail 1, and is sized so as to be slidable on the intermediate rail 3 via the balls 500 held by the ball holding plate 5, and is made of metal. are formed by bending both ends of the short side outward in an arc shape, and the upper and lower bent edges 21, 21 having ball sliding grooves for the balls 500 in the longitudinal direction of the outer surface and the substrate 20 form a substantially C-shaped cross section. is formed in
Further, the base plate 20 is provided with a rear stopper member (not shown) that abuts against the front stopper member of the intermediate rail 3 when the inner rail 2 is fully extended to limit the maximum extension amount of the inner rail 2 . ing.
The engaging member 8 is attached to the lead-in side of the outer rail side surface of the substrate 20 of the inner rail 2 formed in this way.

The ball holding plate 5 is a belt-shaped metal plate having a length about half that of the intermediate rail 3. The upper and lower protruding edges 51, 51 protrude from the upper and lower ends of the substrate 50 in an L shape, and are located between the upper and lower bent edges 31, 31, 21, 21 of the intermediate rail 3 and the inner rail 2, respectively. , a plurality of balls 500 are rotatably held in the sliding direction of the upper and lower projecting edges 51, 51. As shown in FIG.

The slide rail 100 is constructed as described above, and the sliding of the intermediate rail 3 with respect to the outer rail 1 in the drawing (extending) direction and the sliding of the inner rail 2 with respect to the intermediate rail 3 in the drawing (extending) direction are performed as follows. become.
When the intermediate rail 3 slides with respect to the outer rail 1 in the pull-out direction, the ball retaining plate 4 also moves toward the pull-out side by half the amount of movement of the intermediate rail 3. The end of the outer rail 1 comes into contact with the retainer front stopper (not shown) and is stopped. ), and stops by contacting the end of the ball holding plate 4 on the pull-in side.

When the inner rail 2 slides on the intermediate rail 3 in the pull-out direction, the ball holding plate 5 also moves in the pull-out direction by half the movement of the inner rail 2, and eventually the ball holding plate 5 is pulled out. At the same time, the inner rail 2 is stopped by the rear stopper member of the inner rail 2 coming into contact with the retracting side end of the ball holding plate 5 . do.

On the other hand, the sliding of the intermediate rail 3 with respect to the outer rail 1 in the retracting (contracting) direction and the sliding of the inner rail 2 with respect to the intermediate rail 3 in the retracting (contracting) direction are as follows. When the intermediate rail 3 slides relative to the outer rail 1 in the retracting direction, the stationary ball retainer 3 also moves in the retracting direction by a movement amount that is half the amount of movement of the intermediate rail 3. portion collides with the buffer portion 714 of the slide member 71, and the sliding of the intermediate rail 3 stops.

On the other hand, when the inner rail 2 slides to the retracted side with respect to the intermediate rail 3, the ball holding plate 5 also moves in the contraction direction by a movement amount that is half the movement amount of the inner rail 2, and eventually moves to the retracted side of the inner rail 2. The engaging portion 81 of the provided engaging body 8 is linked to the automatic retracting member 7 attached to the outer rail 1, the inner rail 2 is automatically retracted to the retracting side, and the slide rail 100 is retracted (contracted) to the shortest distance. state.

As shown in FIGS. 5 and 6, the automatic retracting member 7 of the automatic retracting device includes a main body 70, a slide member 71 slidably attached to the main body 70, and a slide member 71 slidable relative to the main body 70. An engaging member 72 attached so as to be included in the member 71, extension coil springs 73, 73 as biasing devices for biasing the slide member 71 toward the retraction side, and speed adjustment when the slide member 71 moves in the retraction direction. It consists of a buffer 74 that performs

The main body 70 is integrally molded of synthetic resin, and as shown in FIGS. It is composed of a bottom plate portion 701 in contact with the bottom plate portion 701, a slide base 702 extending in the drawer direction from the end of the bottom plate portion 701, and a concave slide groove 703 provided on the surface of the slide base 702 on the inner rail 2 side.

The bottom plate portion 701 has mounting pieces 701a which protrude from the bottom plate portion 701 to the upper and lower bent edges 11, 11 of the outer rail 1, respectively, and abut along the inner surfaces of the upper and lower bent edges 11, 11, and A U-shaped brake mounting portion 701b is provided at the center in the sliding direction, and spring hooks 701c and 701c project from the bottom plate portion 701 toward the inner rail 2 and face each other across the brake mounting portion 701b. It is

The slide base 702 has a narrow plate shape and is formed along the inner surface of the base plate 12 of the outer rail 1 . A slide groove 703 is formed in a concave shape from the surface of the slide base 702, that is, the inner rail 2 side, toward the bottom surface, that is, the substrate 12 side of the outer rail 1. As shown in FIG.

The slide groove 703 is formed in an L shape by a pull-in standby portion 703b that bends toward the upper and lower bent edges 11 of the outer rail 1 (lower side in FIG. 10) at the pull-out side end of a straight portion 703a that extends in the sliding direction. Further, a rotation guide portion 703c is formed that bulges in an arc shape from the inner corner of the L shape formed by the straight portion 703a and the pull-in standby portion 703b toward the groove.
Then, as shown in FIG. 10, a vertical surface to the bottom surface of the recessed groove that is connected to the rotation guide portion 703c of the pull-in waiting portion 703b serves as a lock receiving portion 704. As shown in FIG.
As shown in FIG. 13, the lock receiving portion 704 is inclined toward the retraction side as it separates from the linear portion 703a.

Slit holes 702a, 702a are provided on the slide base 702 corresponding to the lead-in side of the slide groove 703, and slit holes 702b are provided on the bottom surface of the slide groove 703 corresponding to the slit hole 702a. is provided.
These slit holes 702a, 702a, and 702b create flexibility in the vertical surface with respect to the bottom surface in the sliding direction of the straight portion 703a of the slide groove 703, which facilitates the attachment of the slide member 71 and also facilitates the attachment of the slide member 71. It is possible to reset the joining member 72 .

The slide member 71 is integrally molded of synthetic resin, and as shown in FIG. holding holes 712 are provided, holding pieces 713 are provided on the rear surface, buffer portions 714, 714 are provided in a substantially S-shape projecting from the drawer side end face of the base portion 711, and the base portion Spring hooks 715 , 715 are provided so as to protrude from the portion 711 toward the inner rail 2 and face each other with the top portion of the base portion 711 interposed therebetween.
The cushioning portion 714 absorbs the impact force by elastically deforming when the intermediate rail 3 collides.
Reference numeral 716 in FIG. 7 denotes a reinforcing piece that enters a hole provided at the lead-out end of the slide groove 703 of the slide base 702 in the waiting state for drawing of the automatic drawing member 7 and prevents the slide member 71 from rising in the waiting state for drawing. is.

As shown in FIG. 8, the engaging member 72 is integrally molded of synthetic resin, and is composed of a plate-like base body 721 and a trunk portion 722 projecting from the slide base body 721. A notch engagement groove 723 is formed in the top portion, and a notch contact groove 724 is formed in the rear surface of the slide base body 721 .

The tension coil spring 73 is a coil-shaped spring that exerts a biasing force on the pulling side, and ring-shaped hooks 731, 731 are provided at both ends thereof.

The damper 74 consists of a cylinder 741, a piston rod 742, and a piston. Oil is sealed in the cylinder 741. The damper 74 is a well-known oil damper that utilizes the viscosity of the oil. The shock absorber 74 in the embodiment has a coil spring in the cylinder 741 and always biases the piston rod 742 in a direction to push it toward the expansion side. The biasing force causes the piston rod 742 to extend to its original state.

Each member of the automatic retraction member 7 constructed in this way is assembled as follows.
First, the slide base body 721 of the engaging member 72 is inserted into the linear portion a of the slide groove 703 of the slit holes 702 a , 702 a , 702 b of the main body 70 .
In this state, the slide base body 721 is formed to have substantially the same width as the width of the linear portion a of the slide groove 703, so that it can move linearly in the slide groove 703 in the sliding direction.
Next, the sliding member 71 is pushed into the holding hole 712 so that the holding pieces 713 . . .
At this time, as described above, the vertical surface of the slide groove 703 is flexible due to the slit holes 702a, 702a, and 702b. is restored by elastic force, the attached slide member 71 cannot be easily removed.
In this state, the slide base 702 is included in the space formed between the base portion 711 and the holding piece 713 , and the slide member 71 can slide along the slide base 702 together with the engaging member 72 in the sliding direction.

Next, slide member 71 is slid to the drawer side. Then, the cylinder 741 of the shock absorber 74 is inserted into the brake mounting portion 701b from the rear surface side of the bottom plate portion 701 . At this time, the piston rod 742 is passed through the through-hole provided in the pull-out side end surface of the brake mounting portion 701 b and is positioned on the slide base 702 . abut.
In this state, the biasing force of the coil spring of the shock absorber 74 pushes the slide member 71 toward the drawer side.
Hooking portions 731, 731 at both ends of the tension coil spring 73 are hooked on the spring hooks 701c of the bottom plate portion 701 and the spring hooks 715 of the slide member 71, respectively.
When the tension coil springs 73, 73 are attached, the biasing force of the coil spring of the shock absorber 74 is set to be weaker than the biasing force of the tension coil springs 73, 73. slide to the side.

The automatic retraction member 7 is assembled in this way, and the attachment pieces 701a of the automatic retraction member 7 are fitted between the upper and lower bent edges 11, 11 of the outer rail 1 so as not to come off the outer rail 1 easily. Attached to the lead-in end.
The opening 121 of the outer rail 1 is provided in alignment with the position of the slide base 702 to prevent the board 12 and the slide member 71 from interfering with each other when the slide member 71 slides.
Protrusions are appropriately provided on the rear surface of the main body 70, and through holes are provided in the base plate 12 of the outer rail 1 corresponding to the protrusions. It is applied so that it does not move in the sliding direction with respect to

Next, the engaging body 8 will be described in detail.
The engaging body 8 is shown in FIG. 9, but for the sake of convenience, the vertical direction in the front view of FIG. 9 is called the vertical direction as it is.
The engaging member 8 is integrally molded of synthetic resin, and is an L-shaped member provided with a projecting portion toward the retracting side from the upper retracting side of a vertically elongated rectangular portion in which the through round hole 80a is provided. and a wedge-shaped engaging portion 81 extending downward from the protruding portion of the base 80, and a disk-shaped holding portion 82 connecting the engaging portion 81 and the protruding portion of the base 80 is provided.

The engaging member 8 inserts the holding portion 82 from the inner surface side of the C-shaped inner rail 2 into the holding hole 20a provided on the inner rail 2 on the lead-in side of the substrate 20, and the circular through hole 80a of the base 80 is inserted. and screwed to the inner rail 2 using the screw holes 20b of the substrate 20. As shown in FIG.
The holding portion 82 prevents the engaging member 8 from rotating with respect to the inner rail 2 in a state where the engaging member 8 is attached to the inner rail 2. In addition, by connecting the engaging portion 81 and the projecting portion of the base 80, This is to reinforce the engaging portion 81 so that it is not damaged.

The automatic retraction function of the slide rail 100 to which the automatic retraction device consisting of the automatic retraction member 7 and the engaging member 8 is attached will be described.
When the inner rail 2 is pulled into the outer rail 1 (the state shown in FIGS. 2 and 10) and the slide rail 100 is in the most contracted state, the engaging member 8 is engaged with the notch engaging groove 723 of the engaging member 72. The joint portion 81 is engaged, and the sliding member 71 and the engaging member 72 are pulled in by the tension coil spring 73 while applying a pulling force.

When the inner rail 2 is pulled out from this state, the engagement portion 81 is engaged with the notch engagement groove 723 (the state shown in FIG. While being pulled, it moves in the slide groove 703 to the drawer side. At this time, since the trunk portion 722 of the engaging member 72 is contained in the holding hole 712 of the slide member 71 , the slide member 71 forms the holding hole 712 by the drawer side surface of the trunk portion 722 of the engaging member 72 . While being pressed against the drawer-side surface and extending the tension coil spring 73 against the urging force of the tension coil spring 73, it moves to the drawer side along the slide base 702 like the engaging member 72 (FIG. 13). state shown in (a)).
At this time, the piston rod 742 of the shock absorber 74 is extended by the built-in coil spring (state shown in FIG. 11).
The shock absorber 74 may connect the tip of the piston rod 742 to the slide member 71 without incorporating the coil spring, and extend and contract the piston rod 742 by sliding movement of the slide member 71 .

Then, when the engaging member 72 approaches the pull-in standby portion 703b of the slide groove 703, the pull-in side surface of the notch contact groove 724 comes into contact with the rotation guide portion 703c of the slide groove 703 (state shown in FIG. 13(b)). .
In this state, as shown in FIGS. 13(b) and 13(c), the engaging member 72 is moved to the notch contact groove with the intersection 703d, which is the intersection of the straight portion 703a of the slide groove 703 and the rotation guide portion 703c, as a base point. 724 rotates in the pull-in waiting portion 703b along the outer peripheral surface of the rotation guide portion 703c.
Then, the engaging member 72 rotates, and a part of the notch contact groove 724 (the part that becomes the lower surface in FIG. 13(d)) comes into contact with the lower end of the pull-in waiting portion 703b in FIG. 13(d), Rotation stops (state shown in FIG. 12).
At this time, as the engaging member 72 rotates, the angle of the notch engaging groove 723 changes, and the opening of the notch engaging groove 723 becomes on the pull-out orbit of the engaging portion 81, and the engaging portion 81 deviates from the notch engaging groove 723, the inner rail 2 is pulled out as it is, the intermediate rail 3 is also pulled out, and the slide rail 100 is in the longest extended state.
The holding hole 712 of the slide member 71 is formed in an L-shape along the locus of rotation of the engaging member 72 so that the engaging member 72 can be rotated.
A portion of the notch contact groove 724 is formed as a contact surface 724a, and faces the lock receiving portion 704 of the slide groove.

In this state, the slide member 71 is urged toward the retraction side by the tension coil spring 73, so the slide member 71 is about to move toward the retraction side.
At this time, due to the biasing force of the tension coil spring 73, the pressure receiving portion 722a on the drawer side surface of the leading end of the engaging member 72 after the rotation is moved to the surface of the holding hole 712 (see FIG. 7) in contact with the pressure receiving portion 722a. ) is pressed to the retraction side by the pressing portion 71a.
When the pressure receiving portion 722a is pressed by the pressing portion 71, the contact surface 724a of the notch contact groove 724 facing the locking receiving portion 704 of the slide groove contacts the locking receiving portion 704 and is pressed. do.

In this way, in a state where the contact surface 724a presses against the lock receiving portion 704, the engaging member 72 is applied with a force in the rotating direction. However, the state in which the engagement receiving portion 704 abuts against the contact surface 724a is maintained, and the engaging member 72 cannot move in the retraction direction. Since the engaging member 72 cannot move in the retraction direction, the slide member 71 cannot move in the retraction direction either. This state is the pull-in standby state.

When the inner rail 2 slides to the retraction side in the retraction standby state and retraction (contraction) of the slide rail 100 is started, the intermediate rail 3 slides to the retraction side along with the inner rail 2.例文帳に追加
At this time, due to the movement of the slide rail 100 due to conditions such as the load on the slide rail 100, the retraction side end surface of the intermediate rail 3 may collide with the buffer portion 714 of the slide member 71 in the retraction standby state.

When the intermediate rail 3 collides with the slide member 71, a force is applied to the slide member 71 to move toward the retraction side.
At this time, as in the case described above, the pressing portion 71a of the slide member 71 presses the pressing portion 722a of the engaging member 72, so that the engaging member 72 is further applied with a force in the rotating direction. The joint member 72 maintains a state in which the contact surface 724a abuts the locking receiving portion 704, and the engaging member 72 cannot move in the retraction direction. Since the engaging member 72 cannot move in the retraction direction, the slide member 71 cannot move in the retraction direction (state shown in FIG. 15).
Therefore, even if the intermediate rail 3 collides with the slide member 71, the engaging member 72 is applied with a force in the rotating direction. never

In particular, since the locking receiving portion 704 is inclined toward the retraction side as it separates from the straight portion 703a, when the pressing receiving portion 722a of the engaging member 72 is pressed, the engaging member 72 is moved to the locking receiving portion. Since the contact surface 724a engages with the lock receiving portion 704 like a wedge, the engagement member 72 is released from the standby state. There is no
More specifically, since the engagement state in which the contact surface 724a bites into the lock receiving portion 704 due to the inclination of the lock receiving portion 704 toward the retracted side, the standby state of the engaging member 72 can be released by: It is necessary to push back the engaging member 72 to the drawer side by the inclination. This push-back force is a force in the opposite direction to the collision force of the intermediate rail. The standby state of the member 72 is never released. Therefore, even if the locking receiving portion 704 is perpendicular to the linear portion 703a without being inclined, the engaging member 72 is released from the standby state because a force is applied to the engaging member 72 in the rotating direction. However, it is more reliable to incline as described above.
However, if the angle of inclination is increased, a large force is required to release the retraction standby state.

Further, as shown in FIG. 13(d), the upper end surface of the slide base body 721 of the engaging member 72 in the standby state is in contact with the inner surface of the slide groove 703. As shown in FIG. Therefore, when the engaging member 72 rotates when the intermediate rail 3 collides with the slide member 71, it is possible not only to prevent the engaging member 72 from rotating more than necessary, but also to reduce the contact resistance at the contact surface. is generated, it is possible to prevent the engaging member 72 from moving in the direction in which the standby state is released.

In this manner, the engaging member 72 is rotated in a direction orthogonal to the sliding movement direction, and the rotation causes the drawer-side tip of the engaging member 72 to move orthogonally from the trajectory during the sliding movement. deviate in direction. A locking portion is provided at the deviating portion to prevent the sliding movement of the engaging member 72 toward the retracting side, and the force of moving the sliding member 71 toward the retracting side is engaged with the deviating portion of the engaging member 72. When applied to the member 72, a force can be applied to the engaging member 72 in the direction to rotate it in the orthogonal direction, so that the engaging member 72 can be prevented from sliding. It becomes possible.

In this embodiment, the outer rail 1 is fixed, and the inner rail 2 and the intermediate rail 3 are slidably moved. Since the outer rail 1 can also be used for sliding movement, the slide rail 100 to which the automatic retraction device of this embodiment is attached can also be used in the same way. Of course, even if the method of fixing the inner rail 2 is used, the automatic retraction device functions in the same configuration.

Next, when the pulled-out inner rail 2 is stored, the engaging portion 81 of the inner rail 2 is moved into the notch engagement groove 723 of the slide member 71 in the retraction standby state. 14(b)).
Then, the pull-in side surface of the engaging portion 81 contacts the pull-in side surface forming the notch engagement groove 723 .
Since this contact portion is on the trajectory of the sliding movement of the engaging member 72, the engaging member 72 moves while being pushed toward the retraction side by the engaging portion 81 and rotating toward the retraction side (Fig. 14(c) state).
As described above, the engaging member 72 is pushed to the retracted side on the trajectory during the sliding movement, so that the rotation guide portion 703c of the slide groove 703 between the contact portion and the locking receiving portion 704 and the engaging member 72 The contact portion of the cutout contact groove 724 becomes a rotation base point, and a force is applied to the engagement member 72 in the direction opposite to the direction in which the contact surface 724a of the engagement member 72 contacts the lock receiving portion 704, and the engagement is performed. It is possible to move the member 72 while rotating toward the retraction side.

Then, when the engagement member 72 is in a position in which it can slide on the linear portion 703a of the slide groove 703, the urging force of the tension coil spring 73 moves the slide member 71 to the retracted side and presses the slide member 71. , the engaging member 72 moves to the retracted side (the state of FIG. 14(d)).
At this time, the pull-in side of the slide member 71 moves while pressing the piston rod 742 , so the movement speed is adjusted by the action of the shock absorber 74 .

In addition, when the engagement member 72 is in a slidable position on the linear portion 703a of the slide groove 703 and starts to slide toward the retraction side, the drawer side surface forming the notch engagement groove 723 in this state and , the pull-out side surface of the engaging portion 81 contacts, and the inner rail 2 is pulled in by the movement of the engaging member 72 while the engaging portion 81 is pressed by the engaging member 72 in the pulling direction.
Then, the engaging member 72 moves to the retracted side end within the slide groove 703, and the slide rail 100 is in the most retracted state shown in FIG.

In the pull-in standby state of the automatic pull-in device, when some force is directly applied to the engaging portion 81 to cancel the pull-in standby state and the automatic pull-in member 7 is pulled in, the slide rail 100 contracts in this state. Then, the pull-out side surface of the engaging member 72 in the retracted state and the pull-in side surface of the engaging portion 81 of the inner rail 2 come into contact with each other. However, the side surface of the engaging member 72 on the drawer side is formed in a wedge shape, and when the engaging portion 81 contacts the side surface, the engaging member 72 is pushed down and rotated by the wedge shape. Then, when the engaging portion 81 rides over the wedge-shaped side surface, the engaging member 72 returns from the rotation, and the engaging portion 81 and the notch engaging groove 723 engage with each other.
At this time, as described above, the slit holes 702a, 702a, and 702b are provided in the slide base 702, and the straight portion 703a of the slide groove 703 has the flexibility of the vertical surface with respect to the bottom surface in the sliding direction. The sliding groove 703 is temporarily widened by the pressing force due to the rotation of the engaging member 72, so that the engaging member 72 can be rotated and the automatic retraction member 7 can be reset.

In the embodiment, the automatic retraction device of the present invention is combined with a three-rail slide rail 100, but it can also be used with a two-rail slide rail consisting of an outer rail and an inner rail.

As described above, the slide rail of the present invention is not limited to drawer-type storage furniture, but can be used in a wide range of applications such as grills on kitchen counters, paper trays in copiers, consoles for automobiles, and the like.

1 outer rail 12 substrate 121 opening 100 slide rail 2 inner rail 20 substrate 3 intermediate rail 30 substrate 7 automatic retraction member 70 main body 701 bottom plate portion 701a attachment piece 701b brake attachment portion 701c spring catch 702 slide base 703 slide groove 703a straight portion 703b Pull-in standby portion 703c Rotation guide portion 704 Lock receiving portion 71 Slide member 71a Pressing portion 711 Base portion 712 Holding hole 713 Holding piece 714 Buffer portion 715 Spring catch 72 Engaging member 721 Slide base body 722 Body portion 722a Press receiving portion 723 Cut Notch engagement groove 724 Notch contact groove 724a Contact surface 73 Extension coil spring 731 Hook portion 74 Shock absorber 8 Engagement body 81 Engagement portion

Claims (2)

An automatic retraction member is installed on the outer rail of a three-rail type slide rail consisting of an outer rail, an intermediate rail, and an inner rail, and an engaging portion that engages with the automatic retraction member is installed on the inner rail. a main body fixed to the outer rail; a slide member movable in the sliding direction of the slide rail; an engaging member installed in the slide member and moving together with the slide member; The slide member presses the engaging member and moves it toward the drawing side, and the engaging member presses the sliding member and moves toward the drawer side against the biasing force. The slide member is maintained in the drawn-out state by abutting on the locking receiving portion installed on the main body side, and the inner rail moves to the retracted side by engaging with the engaging portion of the inner rail. The engaging portion engages with the retracted engaging member to move the engaging member to the drawer side, and the automatic retracting member and the engaging portion constitute an automatic retracting device. In the automatic retraction type slide rail equipped with the automatic retraction device, the engaging member moves in a slide groove elongated in the sliding direction of the slide rail provided on the main body side and slides. A lock receiving portion which is movably installed within the member, rotates along the slide groove near the slide end of the sliding movement in the pull-out direction, and has an engaging member installed on the main body side along with the rotation. and the sliding member is prevented from moving in the contraction direction of the slide rail by the contact, thereby maintaining the retraction standby state of the automatic retraction member. When the slide member is rotated in the direction of return, the abutment between the engaging member and the lock receiving portion is released. The pressed portion applies a pressing force to the engaging member so as to rotate in the engaging direction opposite to the direction in which the contact between the engaging member and the lock receiving portion is released . The receiving portion is provided in a pull-in waiting portion of a slide groove formed by a straight portion extending in the sliding direction and a pull-in waiting portion bent on the drawer side and formed in a substantially L shape, and is arranged from the straight portion of the slide groove. A slide rail with an automatic retraction device, characterized in that it inclines toward the retraction side as it separates . The engaging member rotates near the end on the drawer side so that the tip thereof faces in a direction perpendicular to the sliding direction along the slide groove that is bent on the drawer side and formed into a substantially L shape. 2. The apparatus according to claim 1, wherein a contact portion is provided on the retracted side in the moved state, and the pressing portion of the slide member is provided at a portion facing the locking receiving portion with the engaging member interposed therebetween. Slide rail with automatic retraction device.

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