JPS6214307Y2 - - Google Patents

Description

[Detailed description of the invention] (1) Technical field of the invention The invention consists of a pair of central retractable guide grooves that intersect in a substantially V-shape at the approximate center of a single linear horizontal guide groove, and A pair of end retraction guide grooves are provided at both ends of the groove and intersect with the central retraction guide groove at an angle on the same side, and these grooves guide a guide member provided on the stile surface of the door to open the door. The present invention relates to a guide structure for a sliding door device in which the sliding door is slid apart when opening and is flush with the sliding door when closed.

(2) Prior art and its problems Conventionally, in this type of sliding door device,
As described in Japanese Patent Application Laid-Open No. 57-9975, an L-shaped guide member is rotatably provided at the intersection of the horizontal guide groove and the central retraction guide groove, and the guide pin is placed within the corner of the L-shaped guide member. A structure has been proposed in which the L-shaped guide member closes the central retraction guide groove when positioned.
However, in this structure, an L-shaped guide member must be provided at each intersection of the horizontal guide groove and the central retraction guide groove, which complicates the structure and makes it impossible to provide the sliding door device at a low cost.

Furthermore, a structure described in Japanese Patent Application Laid-open No. 16557/1983 has been proposed. This guide structure is shown in Figure 1a.
As shown, a pair of guide grooves E and F with different depths and groove widths intersect in a substantially V-shape on the mating sides of doors A and B, and the diameter and length guided by this pair of guide grooves are Two cylindrical protrusions C and D with different values are provided on the mating side and the outer stile side of the doors A and B, respectively. However, in this structure, Fig. 1b
As shown, a short, thick-diameter cylindrical protrusion D located on the outer stile side of door A and the mating side of door B passes through intersections G and H of guide grooves E and F. There are some inconveniences such as: That is, when the cylindrical protrusion D of the door B moves between the lateral guide groove e ₁ and the central retraction guide groove e ₂ of the guide groove E, the cylindrical protrusion D is guided by the outer surface I ₁ of the guide groove E. Therefore, when the cylindrical projection D passes through the intersection H, a part of the circumferential surface of the cylindrical projection D protrudes into the horizontal guide groove _f1 of the narrow guide groove F and forms the intersection corners h, h. collide. In addition, since a part of the inner surface _I2 of the guide groove E is opened by the central retracting guide groove _f2 of the guide groove F, the cylindrical projection D of the door A or door B can be inserted into the lateral guide groove e of the guide groove E. ₁ , when passing through an intersection G, a part of the circumferential surface of the cylindrical projection D may protrude into the central retraction guide groove _f2 and collide with the intersection corners g, g. As a result, there is a drawback that doors A and B cannot be opened and closed smoothly.

(3) Purpose of the invention The purpose of the invention is to:
To provide a guide structure for a sliding door device having a simple structure and allowing smooth passage through an intersection between a horizontal guide groove and a central retracting guide groove.

(4) Structure of the invention In order to achieve the above purpose, the structure of the invention is as follows:
On the top surface of one of the central retraction guide groove and the horizontal guide groove, a plurality of narrow pin guide grooves are arranged in parallel from the inclination direction to the sliding direction, each protruding along the side surface of the groove. It is characterized by the fact that it is

(5) An embodiment of the invention An embodiment of the guide structure of the invention will be explained in detail with reference to FIGS. 2 to 16. In this embodiment, a case will be described in which a pair of left and right doors are implemented in a hanging structure.

As shown in the second figure, this guide structure includes a guide member 4 fixed to a lintel 3 on which a pair of left and right doors 1 and 2 are attached. A guide groove 5 is formed in the guide member 4. Runners 6 and 7 as guided members are provided on the mating side and the outer frame side of the doors 1 and 2.
is fixed. The runners 6 are arranged on the mating side of the door 1 and the outer stile side of the door 2, and the runners 7 are arranged on the outer stile side of the door 1 and the mating side of the door 2. These runners 6 and 7 run within the guide groove 5 as the doors 1 and 2 are opened and closed. Further, a guide member 9 is fixed to a sill 8 on which the doors 1 and 2 are attached, and a guide groove 10 is formed in the guide member 9. A guide pin 11 for stabilizing the doors 1 and 2 is fixed to substantially the center in the left-right direction of the lower frame surfaces of the doors 1 and 2. Each guide pin 11 is guided within the guide groove 10 by opening and closing the doors 1 and 2.

The guide member 4 includes a central member 40, linear members 41, 41 arranged on the left and right sides of the central member 40,
Terminal members 42 arranged on the left and right sides of each linear member 41,
It consists of 43. Each member 40, 41, 4
By making the guide grooves 2 and 43 continue in a horizontal line, the guide groove 5 has a general shape as shown in the fourth figure.

The guide groove 5 includes a linear horizontal guide groove 50, a pair of central retraction guide grooves 51 and 52 that intersect in a substantially V-shape at the center of the horizontal guide groove 50, and a central retraction guide at both ends of the horizontal guide groove 50. A pair of terminal retraction guide grooves 53 and 54 are provided which are inclined to the same side as the grooves 51 and 52 and intersect with each other. The above same side is
The pair of terminal retraction guide grooves 53 and 54 are located on the same side of the horizontal guide groove 50 in the groove width direction.

As shown in FIG. 3 and FIGS. 10a, b to 12, the central member 40 has a central portion 50a of the horizontal guide groove 50, and central retracting guide grooves 51, 5.
2 is formed into a character shape when viewed in cross section. These horizontal guide grooves 50a and central retraction guide grooves 51, 5
Rail surfaces 40a, 40a constituting the running surfaces of the runners 6, 7 protrude from the lower opening of 2, forming a cross-sectional shape. An opening 40b is formed between the rail surfaces 40a, 40a to allow suspension bolts 63 of the runners 6, 7 to pass therethrough. On the top surfaces of the horizontal guide groove 50a and the central retraction guide grooves 51, 52, there are outer, inner, and inner guide grooves 80, 8 for pins.
1,82 are formed.

The outer and inner guide grooves 80 and 81 are arranged in parallel from the left end of the horizontal guide groove 50a to the right central retraction guide groove 51, as shown in the fourth figure. The outer guide groove 80 has a horizontal portion 80a and a horizontal portion 80a.
and a continuous sloped portion 80b at the right end. The lateral portion 80a is formed from the left end of the central member 40 to the intersection of the lateral guide groove 50a and the right central retraction guide groove 51, along the outer surface of the lateral guide groove 50a. The inclined portion 80b is formed from the right end of the horizontal portion 80a to the end of the right central retracting guide groove 51 while extending along the outer surface of the right central retracting guide groove 51. The inner guide groove 81 has a horizontal portion 81a.
and an inclined portion 81b continuous to the right end of this horizontal portion 81a. These horizontal portions 81a and inclined portions 81b extend along the inner surfaces of the horizontal guide grooves 50a and the right central retraction guide groove 51, and
a and is formed substantially parallel to the inclined portion 80b.
Further, the middle guide groove 82 is provided from the right end of the horizontal guide groove 50a to the left center retraction guide groove 52, and the depth of the middle guide groove 82 is deeper than the outer and inner guide grooves 80 and 81. . The middle guide groove 82 consists of a horizontal portion 82a and an inclined portion 82b continuous to the left end of the horizontal portion 82a. Horizontal part 8
2a is a horizontal guide groove 50a from the right end of the central member 40.
It passes through the center in the width direction of the groove and is formed across the intersection of the horizontal guide groove 50a and the left center retraction guide groove 52. This horizontal portion 82a crosses a part of the inclined portion 80b of the outer guide groove 80. The inclined portion 82b is formed from the left end of the horizontal portion 82a, passing through the center portion of the left center retraction guide groove 52 in the groove width direction, and extending to the end of the left center retraction guide groove 52. This inclined portion 82b crosses a part of the horizontal portion 81a of the inner guide groove 81. In addition, at the corner formed by the top surface and the inner and outer surfaces of the horizontal guide groove 50a of the central member 40 and the central retraction guide grooves 51 and 52, there is a protrusion that guides the guide surface portions 60c of the runners 6 and 7, which will be described later. A section 90 is provided.

The linear member 41 is shown in FIGS. 3, 4, and 1.
As shown in Figure 3, it has a horizontally long cross-sectional shape that allows the passage of runners 6 and 7. Straight member 4
In the lower opening of 1, rail surfaces 41a, 41a that constitute running surfaces of runners 6, 7 are connected to front and rear wall surfaces 41b,
It protrudes from the lower edge of 41b and has a cross-sectional shape. An opening 41c is formed between the rail surfaces 41a, 41a to allow suspension bolts 63 of the runners 6, 7 to pass therethrough. Top surface 4 of straight member 41
A guide piece 41e is provided between 1d and the rail surface 41a,
41e protrudes from the front and rear wall surfaces 41b, 41b and has a cross-sectional shape. Guide piece 41e, 4
A gap 41f is formed between 1e and guides the guide surface portions 60c of the runners 6 and 7. This gap 41f becomes horizontal guide grooves 50b located on the left and right sides of the central member 40.

As shown in FIGS. 3 and 4, the right end member 42 is formed with a terminal portion 50c of the horizontal guide groove 50 and a terminal retraction guide groove 53 in a character shape in cross-section. Rail surfaces 42a, 42a constituting the running surfaces of the runners 6, 7 protrude from the lower openings of the horizontal guide groove 50c and the terminal retraction guide groove 53, forming a cross-sectional shape (as shown in FIG. 12). have the same cross-sectional shape). An opening 42b is formed between the rail surfaces 42a, 42a to allow suspension bolts 63 of the runners 6, 7 to pass therethrough. Further, the right end member 42 is provided with an inner guide groove 83 for a pin. This inner guide groove 83 has a horizontal portion 83a,
Slanted portion 83 continuous to the right end of this horizontal portion 83a
It consists of b. The lateral portion 83a is formed from the left end of the right end member 42 to the center of the lateral guide groove 50c in the groove width direction and the intersection with the terminal retraction guide groove 53. The inclined portion 83b is formed from the right end of the horizontal portion 83a to the center portion of the terminal retraction guide groove 53 in the groove width direction to the end of the terminal retraction guide groove 53. In addition, the horizontal guide groove 50 of the right end member 42
A protrusion 91 for guiding the guide surface portion 60c of the runner 7 is provided at a corner formed by the top surface and side surface of the terminal retraction guide groove 53 and the guide surface portion 60c of the runner 7.
The protrusion 91 is arranged on the left end side in contact with the linear member 61 and on the end side of the terminal retraction guide groove 53.

In the left end member 43, as shown in FIGS. 3 and 4, an end portion 50d of the horizontal guide groove 50 and a terminal retraction guide groove 54 are formed in a letter-like cross-sectional shape (as shown in FIG. 11). have the same cross-sectional shape). Rail surfaces 43a, 43a constituting the running surfaces of the runners 6, 7 protrude from the lower openings of the horizontal guide groove 50 and the terminal retraction guide groove 54, forming a cross-sectional shape. An opening 43b is formed between the rail surfaces 43a, 43a to allow the suspension bolts 63 of the runners 6, 7 to pass therethrough.

Furthermore, outer and inner guide grooves 84 and 85 for pins are arranged in parallel on the left end member 43. Outside of this
The spacing between the inner guide grooves 84 and 85 is equal to the spacing between the outer and inner guide grooves 80 and 81 of the central member 40. The outer guide groove 84 has a horizontal portion 84a and an inclined portion 84b continuous to the left end of the horizontal portion 84a.
It consists of The outer guide groove 84 extends from the right end of the left end member 43 along the outer surface of the horizontal guide groove 50d.
It is formed across the intersection of the horizontal guide groove 50d and the left end retraction guide groove 54. Slanted portion 84
b is formed from the left end of the horizontal portion 84a to the end of the terminal retraction guide groove while extending along the outer surface of the terminal retraction guide groove 54. The inner guide groove 85 is composed of a horizontal portion 85a and an inclined portion 85b continuous to the left end of the horizontal portion 85a. These horizontal parts 8
5a and the inclined portion 85b are formed along the inner surfaces of the horizontal guide groove 50d and the right central retraction guide groove 54, and are substantially parallel to the horizontal portion 84a and the inclined portion 84b. In addition, the horizontal guide groove 5 of the left end member 43
A protrusion 92 for guiding the guide surface portion 60c of the runner 6 is provided at a corner formed by the top surface and side surface of the guide groove 54 and the end retraction guide groove 54. The protrusion 92 has a right end side in contact with the straight member 61,
It is arranged on the terminal side of the terminal retraction guide groove 54.

As shown in FIGS. 5 to 8, one of the runners 6 includes a base 60, a frame 61 fixed to the base 60, and rollers 62, 62 rotatably provided on the front and rear walls of the frame 61. , a suspension bolt 63 rotatably provided toward the lower side of the frame 61.

The base 60 is made of synthetic resin and has a columnar shape, and the left and right end surfaces of the base 60 are formed into tapered surfaces 60a that are mountain-shaped in plan view. This tapered surface 60
The corner a is formed into a circular arc surface 60b. The top portion of the base portion 60 indicated by the dashed line l is projected above the roller 62 and forms the guide surface portion 60.
c. A reverse groove 60 is formed on the lower surface of the base 60.
d is formed in an elongated shape in the front-rear direction of the base 60. A mounting hole 60e having a circular shape in plan view is formed in the center of the lower surface of the base 60 where the opening of the reverse groove 60d is located, and the base 60 has the reverse groove 60d open.
Attachment recesses 60f, 60f are formed on the front and rear surfaces of. The mounting hole 60e and the left and right arcuate surfaces 60
A through hole 60g is provided in the base 60 located between the
60g is formed. Each through hole 60g penetrates the top and bottom surfaces of the base 60. Each through hole 6
Around the top surface of 0g, large diameter concave holes 60h, 60h are formed as shown in FIG.

The frame 61 is made of metal, and includes a substrate 61a disposed on the lower surface of the base 60, and the mounting recess 6 raised from the front and rear sides of the substrate 61a.
It is formed in a letter shape with support plates 61b, 61b disposed within 0f. An insertion hole 61c and mounting holes 61d, 61d are passed through the board 61a. The insertion hole 61c is coaxial with the mounting hole 60e and has a smaller diameter than the mounting hole 60e.
The insertion hole 61c is a shaft portion 6 of a hanging bolt 63, which will be described later.
3a is rotatably inserted.
The mounting holes 61d and 61d are the above-mentioned through holes 60g and 60.
It is coaxially associated with g. In addition, each of the support plates 61
Bearing holes 61e, 61e that meet a part of the reverse groove 60d are penetrated through the bearing holes 61e, 61b.

The roller 62 is made of synthetic resin and has a disk shape, and a bearing hole 62a is passed through the axial center of the roller 62. A recessed hole 62b is formed in the outer end surface of the roller 62 located around the bearing hole 62a, and an annular protruding surface 62c projects from the inner end surface of the roller 62 located around the bearing hole 62a.

The roller shaft 64 of the roller 62 is a cylindrical rod-shaped shaft portion 6.
4a, and a large diameter head 6 at one end of the shaft portion 64a.
4b is provided.

The suspension bolt 63 includes a cylindrical rod-shaped shaft portion 63a, and a large-diameter head 63b is provided at the top end of the shaft portion 63a. A male thread 63c is formed on the outer circumferential surface of the shaft portion 63a extending from the lower end to the upper portion beyond the central portion in the axial direction. The top of the shaft portion 63a,
A reduced diameter portion 63d is formed between the male screw 63c and the male thread 63c.

The case where the roller 62 is attached to the frame 61 will be explained. Shaft portion 63a of hanging bolt 63
from the male screw 63c side to the insertion hole 61 of the frame 61.
c and with the head 63b of the hanging bolt 63 positioned below the bearing hole 61e of the frame 61, the roller shaft 64 is fitted into the roller 62 and the frame 61. In other words, the shaft portion 6 of the roller shaft 64
4a from the bearing hole 62a of one roller 62 to the bearing hole 61e of the frame 61 to the other roller 6.
2 into the bearing hole 61e. The rollers 62, 62 are rotatably attached to the frame 61 by crushing the tip of the shaft portion 64a protruding into the recessed hole 62b of the other roller 62. In this case, the head 64b of the roller shaft 64 is connected to one of the rollers 6
It is arranged in the concave hole 62b of No. 2.

The case where the frame 61 is attached to the base 60 will be explained. The support plate 61b of the frame 61 is positioned in the mounting recesses 60f, 60f of the base 60,
The frame 61 is fixed to the base 60 by inserting the rivet 65 from the through hole 60g into the attachment hole 61d and crushing the tip of the rivet 65 protruding from the lower surface of the frame 61. At this time, the large diameter head 65a of the rivet 65 is located within the large diameter concave hole 60h of the base 60 and does not protrude from the top surface of the base 60. Further, in the assembled runner 6, the shaft portion 64a of the roller shaft 64 located between the support plates 61b, 61b is rotatably located within the reverse groove 60d of the base portion 60. Head 63 of hanging bolt 63
b is rotatably located within the mounting hole 60e of the base 60. Due to the rotating structure of the hanging bolt 63, the running direction of the runner 6 is freely determined.
A nut 66 is attached to the male thread of the hanging bolt 63.

On the other hand, the runner 6 has the guide groove 80,
81 and guide pins 12 and 13 guided to guide grooves 84 and 85 are provided. These guide pins 12 and 13 protrude horizontally from the top surface of the base 60 while being spaced apart from each other in the front-rear direction. Both left and right end surfaces of the guide pins 12 and 13 are arc-shaped guide surfaces 12.
a, 13a. guide pin 12,
The horizontal width h ₁ of 13 is smaller than the horizontal width h ₂ of the parallel front and rear surfaces of the base 60 .

The other runner 7 is constructed as shown in FIG. 9, and the same parts as those of the runner 6 are given the same reference numerals to avoid redundant explanation. The runner 7 is provided with a guide pin 14 guided to the middle guide groove 82 and the middle guide groove 83. The guide pin 14 projects horizontally from approximately the center of the top surface of the base portion 60 . Both left and right end surfaces of the guide pin 14 are formed into arcuate guide surfaces 14a. The horizontal width h ₃ of the guide pin 14 is smaller than the horizontal width h ₄ of the parallel front and rear surfaces of the base 60 . The height of this guide pin 14 is higher than that of the guide pins 12 and 13.

In the embodiment configured as above,
When the doors 1 and 2 are closed, the runners 6 and 7
are arranged as follows.

The runner 6 of the door 1 is located in the right center retraction guide groove 5
The runner 7 of the door 1 is located at the end of the right end retraction guide groove 53. The runner 7 of the door 2 is located at the end of the left center retraction guide groove 52, and the runner 6 of the door 2 is located at the end of the left end retraction guide groove 54. Due to the arrangement of the runners 6 and 7, the guide pins 12 and 13 are positioned in the outer and inner guide grooves 80 and 81 and the outer and inner guide grooves 84 and 85, and the guide pin 14 is located in the middle guide groove 82 and the middle guide groove 83. located in

A case of opening the closed doors 1 and 2 will be explained. For example, in order to open the door 1, the runners 6 and 7 are moved from the right center retraction guide groove 51 and the right end retraction guide groove 53 to the lateral guide groove 50a by pulling the door 1 forward. Then, by laterally moving the door 1 in the direction of the door 2, the runners 6 and 7 move into the horizontal guide grooves 50a, 50b, 50.
d, and door 1 is moved to the rear of door 2. After the door 1 starts moving, the runner 6 moves between the right center retraction guide groove 51 and the horizontal guide groove 5.
When passing through the intersection J of 0a, one guide pin 12 passes through the intersection j of the outer guide groove 80 and the inner guide groove 82, as shown by the imaginary line in FIG. 13 is the inner guide groove 8
1, so one guide pin 12
crosses the middle guide groove 82 while drawing a circular arc without colliding with the corner K of the intersection j. The guide pins 12 and 13 are connected to the outer and inner guide grooves 8.
From the inclined parts 80b, 81b of 0,81 to the horizontal part 8
Move to 0a, 81a.

After that, the runner 6 moves to the left center retraction guide groove 5.
2 and the horizontal guide groove 50a, the other guide pin 13 passes through the inner guide groove 81
However, since one guide pin 12 is guided to the outer guide groove 80, the other guide pin 13 does not collide with the corner n of the intersection m. without crossing the middle guide groove 82.

In addition, when closing the door 1, by moving the door 1 in the opposite direction to the above, the runners 6 and 7 move from the horizontal guide grooves 50d, 50b, and 50c to the right center retraction guide groove 51 and the right end retraction guide groove. 53, and the door 1 becomes flush as shown in the first diagram. When the runner 6 passes through the intersections M and J during the process of closing the door 1,
Similarly to the above, the other guide pin 13
When one guide pin 12 passes through the intersection j, one guide pin 12 is guided to the outer guide groove 80, and when one guide pin 12 passes the intersection j, the other guide pin 13 is guided to the inner guide groove 81. 6 will be prevented from moving in the other direction.

On the other hand, when opening and closing the door 2, the guide pin 14 of the runner 7 moves inside the middle guide groove 82 between the left center retraction guide groove 52 and the horizontal guide grooves 50a, 50b, 5.
When moving between 0c and passing through the intersections j and m, the guide pin 14 is in contact with the inner guide groove 82 and the outer guide groove 82.
Due to the barrier effect caused by the difference in depth between the inner guide grooves 80 and 81, the guide grooves are guided without colliding with the intersecting corner n.

By the way, according to the embodiment, as shown in FIGS. 15 and 16, the central members 40 and 41 forming the guide groove 5 or the central member 41 and the terminal member 4
Even if there is a step P at the joint of the guide pins 12, 13, 14, the horizontal width of the guide pins 12, 13, 14
Difference between h ₁ , h ₃ and the front and rear widths h ₂ , h ₄ of the base 60
Due to the presence of h ₅ and h ₆ , guide pins 12, 13, 1
4 is taken into the corresponding outer, inner, and middle guide grooves 80 to 85 from the linear member 41, the tapered surface 60a of the guide surface portion 30c of the base 60, this tapered surface 6
0a, the arc surface 60b comes into contact with the step P, so that the base 60 is guided into the horizontal guide groove 50a, and then the guide pins 12, 13, 14
are taken into the outer, inner, and middle guide grooves 80 to 85. As a result, the runner 67 can smoothly move through the joints between the linear member 41 and the central member 40 and the end members 42.

According to the embodiment, the guide pins 12, 13,
14 is formed horizontally in the left and right direction,
Guide pin 1 in the outer, inner, and middle guide grooves 80 to 85
Directivity is generated in 2, 13, and 14, and guidance by the outer, inner, and middle guide grooves 80 to 85 is performed smoothly. In particular, the guide pins 12 and 13 do not have the disadvantage of being strained between the outer and inner guide grooves 80, 81, 84, and 85 during their movement.

According to the embodiment, the guide pins 12, 13,
The left and right end surfaces of 14 are guide surfaces 12a, 13a, 14a.
Since the guide pins 12, 13,
14 into the outer, inner, and middle guide grooves 80 to 85, and the horizontal portion 80 of the outer, inner, and middle guide grooves 80 to 85.
The curves that move between a to 85a and the inclined portions 80b to 85b are smooth.

Furthermore, in the case of the linear member 41, the runner 6,
Since the guide surface portions 63c of 7 are guided at the interval 41f (horizontal guide groove 50b), the linear member 41 can be shared.

(6) Modification of the invention In the embodiment described above, one guide groove 80, 81 is configured into two in the central member 40,
Although the example in which the other guide groove 82 is composed of one guide groove is illustrated, the number of each guide groove is not limited to this. For example, one guide groove may have three guide grooves and the other guide groove may have two guide grooves, or one guide groove 4
It is possible to combine a large number of guide grooves, such as one guide groove and three guide grooves on the other side. In addition, as shown in Figure 17, the depths of the left and right end retraction guide grooves 53 and 54 are
The depth is set to allow passage of the guide pins 12, 13, 14 of the runners 6, 7, and the inner, outer, and inner guide grooves 83, 84, 85 can be omitted. Further, in the above embodiments, the guide member 4 is divided into parts, but the guide member may be integrated. The guide pin in the above embodiments may have a cylindrical shape or other shape as long as it is a member that is guided by the guide groove.

(7) Effects of the invention As explained above, the invention has the following effects.

(b) A pair of central retracting guide grooves that intersect in a substantially V-shape at the center of the horizontal guide grooves, the width of which is narrow from the inclination direction of one of the central retracting guide grooves toward the sliding direction, and the width of each central retracting guide groove is narrow toward the sliding direction, and Since a plurality of pin guide grooves protruding along the guide groove are arranged in parallel, movement between the horizontal guide groove and the central retraction guide groove is performed smoothly by combination with the guide pin guided by the guide groove. It will be done.

(b) With the structure in (a) above, the intersections with the pin guide grooves provided from the inclination direction of the other central retraction guide groove toward the sliding direction are arranged alternately, so each intersection Due to the interaction of one guide pin guided by the plurality of guide grooves when passing through the intersection, the other guide pin passing through the intersection moves without colliding with the corner of the intersection, The door opens and closes smoothly.

(c) As a result of (a) and (b) above, an auxiliary member such as a switching lever is not required at each intersection of the horizontal guide groove and the central retraction guide groove, and the guide structure can be simplified.

[Brief explanation of the drawing]

Figures 1a and b are an overall plan view and an enlarged plan view of main parts showing the guide structure of a conventional sliding door device, and Figure 2
The figure is a perspective view of the guide structure of the sliding door device according to the present invention, FIG. 3 is an exploded perspective view of the guide member of the guide structure, FIG. 4 is a schematic diagram of the guide groove of the guide structure, and FIG. The figure is a perspective view of one of the runners used in the guide structure, FIG. 6 is an exploded perspective view of the runner, and FIG. 7 is a sectional view taken along the - line in FIG.
8 is a cross-sectional view taken along the - line in FIG. 5, FIG. 9 is a perspective view of the other runner, FIGS. 10 a and b are end views taken along the - line in FIG. 14, and FIG. XI
12 is an end view taken along the line XII-XII in FIG. 14, FIG. 13 is an end view taken along the - line in FIG.
Figure 4 is a cutaway plan view of the rail surface of the central member for explaining the action of the present invention, and Figures 15 and 16 are plan views with the rail surface cut away around the joint between the central member and the straight member. FIG. 17 is a schematic diagram of a guide groove corresponding to FIG. 4 showing a modification of the present invention. 1, 2... Door, 4... Guide member, 5... Guide groove, 6, 7... Runner, 12, 13, 14
...Guide pin, 50,50a-50d...Horizontal guide groove, 51,52...Central retraction guide groove,
53, 54...Terminal retraction guide groove, 80-85
...Pin guide groove, 80a-85a...horizontal portion, 80b-85b...slanted portion.

Claims (1)

[Claims for Utility Model Registration] A pair of central retraction guide grooves that intersect in a substantially V-shape at the center of one straight horizontal guide groove, and a pair of central retraction guide grooves that are identical to the central retraction guide groove at both ends of the horizontal guide groove. A pair of terminal retraction guide grooves are provided which intersect with each other while being inclined to the side, and these grooves guide the guided member provided on the frame surface of the door so that the door can be slid in the opposite direction when the door is opened, and flush when the door is closed. In the guide structure of the sliding door device, the top surface of one of the central guide groove and the horizontal guide groove has a narrow width extending from the inclination direction to the sliding direction, and a groove extending along the side surface of each groove. A guide structure for a sliding door device, characterized in that a plurality of protruding guide grooves for pins are arranged in parallel.