JP2526559Y2 - Orido upper shaft support structure - Google Patents

Description

[Detailed description of the invention] [Industrial application field] The invention relates to a shaft support structure of a folding door, and more particularly, to a shaft support structure at an upper portion of a suspension hanging fixed type.

[Conventional technology]

Heretofore, in this type of shaft support structure, there has been known a structure in which a hole fixed to a tip of a pivot shaft or a bag-shaped concave portion is integrally provided in a metal fitting fixed in a rail. The fixture body is fixed in the rail by, for example, clamping the protruding edge in the rail groove between the fixture body and a nut member screwed to the fixture body via a screw member. The pivot shaft is biased by a spring at the upper end of the folding door and is provided so as to always protrude upward.

[Problems to be solved by the invention]

By the way, at the time of folding at the hanging point of the folding door, the moment due to the weight of the door acts to shift the axis of the pivot with respect to the bracket main body, but in the above-described structure, in order to reduce frictional resistance at the time of rotation. Since the diameter of the hole or the recess is slightly larger than the diameter of the tip of the pivot shaft, the center of the shaft tends to shift. The degree of axial misalignment of the pivot axis relative to pivot bracket is, for example, as shown in FIG. 4, as from the axis R of the normal Orito 8 indicated by the two-dot chain line, even insignificant displaced in the R ₁ position In addition, since it is amplified by the width of the door, the center of gravity of the door becomes unstable, and the turning operability at the time of folding is reduced.

Accordingly, an object of the present invention is to provide an upper shaft support structure of a folding door that can automatically correct the axial center deviation of a pivot shaft with respect to a receiving fixture and can improve the operability at the time of folding. [Means for Solving the Problems] The present invention has been made to achieve the above-mentioned object, and is characterized by a pivot shaft provided at the upper end of a folding door and projected by a spring and projecting upward, A receiving fixture fixed in the rail and having a receiving recess into which the tip of the pivot shaft is engaged; a large-diameter engagement base is formed at the tip of the pivot shaft; A truncated cone-shaped shaft center adjusting surface having a vertex on the axis of the pivot shaft is formed at a further tip side of the base, and the receiving recess includes a housing recess for housing the engagement base and the shaft center. There is a configuration in which a guide inclined surface that guides the adjustment surface and recovers the axial center deviation of the pivot shaft is formed.

[Action]

According to this invention, when the folding door is folded, when a force for shifting the regular axis of the pivot shaft with respect to the receiving recess occurs, the frusto-conical shaft center adjusting surface is mainly applied to the guide inclined surface by the biasing force of the spring. Pressed. The pressed shaft center adjusting surface is guided by the drag of the guide inclined surface, and is pushed back to the normal shaft center position.

〔Example〕

 1 to 5 show an embodiment of the present invention.

This is an example of an axis suspension type that supports the weight of the door below the door. As shown in FIG. 4, between the upper rail 2 and the lower rail 4, there is a folding door 6 on the moving side and a hanging side on the hanging side. Folding doors 8 are provided side by side, and adjacent ends are connected by hinges 10 so as to be foldable.

Runners 12 and 12 are provided at the upper and lower ends of the folding door 6 on the moving side, respectively.
And pivots 14 and 16 are provided at the upper and lower ends of the folding door 8 on the hanging side, respectively. The upper rail 2 and the lower rail 4 are provided with brackets 18, 20 for supporting the pivots 14, 16.
Is provided.

As shown in FIG. 1 and FIG.
It is composed of a rectangular fitting main body 22 and a receiving recess 24 formed integrally with the fitting main body 22. An insertion hole 22a through which the screw member 26 is inserted is formed at one longitudinal end of the metal fitting body 22, and a plate-shaped nut member 28 is screwed into the screw member 26. The protruding edge of the upper rail 2 between the nut member 28
By holding the 2a, 2a, the metal fitting body 22 is fixed to the upper rail 2. If a raised portion 28a is formed on the periphery of the nut member 28, it is possible to obtain a fixed state in which loosening is unlikely to occur due to elastic action. Reference numeral 22b indicates a leg piece.

The upper pivot 14 is roughly composed of a case body 30 embedded in the upper end of the folding door 8 and a pivot shaft 322 housed in the case body 30. Spring 3 on case body 30
4 are accommodated therein, and the pivot shaft 32 is constantly urged to protrude upward. At the tip of the pivot shaft 32,
A small diameter portion 32a is formed, and the small diameter portion 32a has a receiving recess.
An engagement head 36 for 24 is provided rotatably. The engagement head 36 has an engagement base 36 having a diameter larger than the diameter of the pivot shaft 32.
a, and a substantially conical shaft center adjusting surface 36b continuously provided on the distal end side of the engagement base portion 36a.

The engagement head 36 has a large-diameter insertion hole 36c and a small-diameter insertion hole 3c.
6d are communicated with each other, and the small diameter portion 32a of the pivot shaft 32 is inserted through the small diameter insertion hole 36d, and the tip of the small diameter portion 32a is caulked to prevent the engaging head 36 from falling off. Reference numeral 38 indicates a washer.

The receiving recess 24 has an engagement base 36a corresponding to the pivot shaft 32.
And a conical guide inclined surface 24b, which guides the axial center adjustment surface 36b, as shown in the drawing, are formed so as to communicate with each other. The axis adjustment surface 36b is formed in a truncated cone shape having an apex on the axis R of the pivot shaft 32.

A description will be given of the operation of preventing the displacement of the shaft center by the shaft center adjusting surface 36b and the guide inclined surface 24b. As shown in FIG. Assuming the case where the axis R of the normal is displaced in R ₁ position,
One side surface 36e of the shaft center adjusting surface 36b and the opposing side surface 24c are in close contact with the guide inclined surface 24b. However, since the biasing force of the spring 34 is always acting on the shaft center adjusting surface 36b, the horizontal component F ₁ To the normal axis R position. Therefore, since the axial center deviation is always corrected, an adverse effect on the rotating operation due to the unstable center of gravity of the folding door 8 is avoided.

Next, the lower pivot 16 will be described with reference to FIGS.
The metal fitting 20 will be described.

The receiving bracket 20 is a bracket main body 40 fixed in the lower rail 4.
And a cup part 44 rotatably provided on the metal fitting body 40 via a rolling element 42 such as a steel ball. The bracket main body 40 includes, for example, a main member 46 constituting the whole.
And a rectangular piece-shaped sub-member 48 fitted to the main member 46,
The rolling element housing portion 50 fitted to the sub member 48 can be used.

An insertion hole 46a through which the screw member 52 is inserted is formed on one end side in the longitudinal direction of the main member 46, similarly to the metal fitting 18, and a plate-shaped nut member 54 is screwed to the screw member 52. The main member 46 is fixed to the lower rail 4 by sandwiching the protruding edges 4a of the lower rail 4 with the nut member 54. Reference numeral 54a indicates a raised portion provided on the periphery. On the other end side of the main member 46, fitting protrusions 46b, 46b for the sub member 48 are formed at intervals in the longitudinal direction, and the cup portion 44 is located in the middle of the fitting protrusions 46b, 46b. Insertion hole 46c
Are formed.

Fitting concave parts 48a, 48a corresponding to the fitting convex parts 46b, 46b of the main member 46 are formed at both ends of the sub member 48, and a holding concave part 48b for holding the rolling element housing part 50 is provided at a substantially central part. Are formed. In this example, the main member 46 and the sub member 48 are made of a synthetic resin such as nylon 6, and the cup portion 44 and the rolling element housing portion 50 are formed.
Are formed of metal, and the rolling element housing 50 is
Press fit into 48b. An annular protruding edge 48 is formed at the upper end of the holding recess 48b to prevent the rolling element housing portion 50 from being detached after the engagement.
c is formed. Further, the fitting protrusions 46b, 46b of the main member 46 are provided.
In addition, insertion holes 46d, 48d through which the stop pin 56 is inserted are formed at both ends of the sub member 48, respectively.

An annular accommodation groove 50a for accommodating the rolling element 42 is formed in the rolling element housing part 50, and a conical concave part 50c corresponding to the conical convex part 44a of the cup part 44 is formed in the central shaft part 50b. ing. As a result, a shaft center misalignment prevention function described later can be obtained. Of course, this configuration need not be provided.

The cup 44 has a pivot 1 on the opposite side of the conical projection 44a.
An engaging recess 44b for supporting the tip 62a of the sixth is formed,
A chamfered portion 44c is formed at the open end of the engagement concave portion 44b to facilitate the engagement of the pivot 16. A flange 44d is formed near the conical convex portion 44a of the cup portion 44 to prevent the main member 46 from slipping out.
Counterbore portions 46e, 46e are formed in the portion 6 so that the cup portion 44 can be flexibly supported by the pivot 16. A gap 58 is provided between the contact surface 44e of the cup 44 with the rolling element 42 and the upper surface 50e of the rolling element housing 50 so that the function of the rolling element 42 due to rolling friction is not impaired.

The pivot 16 uses a conventional one, and Orido 8
Body 60 embedded in the lower end of the
And a shaft main body 62 which is screwed to the shaft main body 60.

When the folding doors 6 and 8 are folded in the above configuration, the weight of the folding door 8 is concentrated on the tip 62a of the pivot 16, so that the coefficient of friction between the cup 44 and the tip 62a of the pivot 16 becomes extremely large. However, since the cup portion 44 is supported by the rolling element 42 below, the function of the rolling element 42 due to the rolling friction takes precedence, and the cup portion 44 and the pivot 16
Rotates integrally with the tip 62a. Thereby, the frictional resistance at the time of rotation is reduced as much as possible, and the influence of the weight of the folding door 8 is also avoided. Therefore, it is possible to improve the rotational operability at the time of folding. Further, the vertical adjustment of the folding door 8 can be easily performed by adjusting the screwing amount of the shaft main body 62 of the existing pivot 16, as shown in FIG. That is, the shaft body
By varying 62 screwed amount of from d ₁ to d _2, it is possible to adjust the vertical position of the folding door 8 (d ₂ -d ₁₎ minute.

In this way, not only can the rotational operability at the time of folding be improved, but also the mounting cost can be reduced by using the existing pivot 16.

In this example, the contact surface structure between the metal fitting body 40 and the cup portion 44 is specified, but is not limited thereto.
It can be changed appropriately within a range in which the rolling friction function of the rolling elements 42 can be obtained.

Next, the function of preventing axial misalignment by the conical convex portion 44a and the conical concave portion 50c formed between the cup portion 44 and the rolling element housing portion 50 will be described.

As shown in FIG. 10, the conical convex portion 44a of the cup portion 44
Is formed in a conical shape having an apex on the axis R of the cup portion 44. Force F ₂ for shifting the axis of the pivot 16 occurs at the moment the action due to the weight of the folding door 8, if If the axial center R is displaced in the R ₁ position, and one side surface 44h of the conical projection 44a, the conical recess 50c Although the opposing side surface 50g is in close contact, the conical convex portion 44a
, The weight W of the folding door 8 always acts, so the horizontal component
It is pushed back to the axis R the normal position by F _3. Therefore,
Since the axial center deviation is always corrected, an adverse effect on the rotating operation due to the unstable center of gravity of the folding door 8 is avoided. The conical convex portion 44a has a truncated top portion so that the function of preventing axial misalignment between the conical concave portion 50c and the rolling frictional function of the rolling element 42 is reliably obtained. It is desirable to form a frustoconical shape. The conical convex portion 44a and the conical concave portion 50c can be relatively formed between the cup portion 44 and the metal fitting body 40.

Next, the runner 12 attached to the upper and lower ends of the movable folding door 6 will be described with reference to FIGS. 11 and 12. FIG.

The runner 12 is a case body embedded in the end face of the folding door 6
64, a shaft body 66 housed in the case body 64, and a runner body 68 rotatably provided at the tip of the shaft body 66. Although not shown, a spring is mounted on the case body 64 similarly to the pivot 14, and the shaft body 66 is urged outward. A small diameter part 66 is provided at the tip of the shaft body 66.
a is formed, and the runner body 68 is
8a is formed. Runner body 68 has a large diameter base 68b
And a small diameter engaging portion 68c, and the insertion hole 68a
The base portion 68b and the engagement portion 68c are formed with large-diameter concave portions 68d and 68e, respectively. Further, the recess 68 of the base 68b
In d, an annular groove 68f for accommodating the sphere 70 is formed, and
At the outer end of the base portion 68b, an annular convex portion 68g that contacts the protruding edges 2a, 4a of the upper rail 2 and the lower rail 4 is formed. The sphere 70 is retained by a washer 72. The tip of the shaft main body 66 is caulked through the washer 74 after the insertion, whereby the runner main body 68 is prevented from coming off.

[Effect of the invention]

According to this invention, at the time of folding the folding door, even if a force for shifting the axis of the pivot shaft occurs, the frustroconical shaft center adjustment surface is forcibly pushed back to the normal shaft center position by the guide inclined surface, Instability of the center of gravity of the folding door due to axial misalignment can be avoided, so that folding operability can be improved.

[Brief description of the drawings]

FIG. 1 is a view showing an embodiment of an upper shaft support structure of a folding door according to the present invention, wherein FIG. 1 (A) is a sectional view in use, FIG. 1 (B) is a side view thereof, and FIG. Exploded perspective view of main part, third
FIG. 4 is a partial cross-sectional view of the pivot, FIG. 4 is a perspective view showing a use state, FIG. 5 is a view showing a function of preventing axial misalignment, and FIG. 6 is a view showing a bracket and a pivot at the lower part of the folding door. 9A is a cross-sectional view of a used state, FIG. 9B is a side view of a main part, FIG. 7 is an exploded perspective view of the metal fitting, FIG.
The figure shows the vertical adjustment of the folding door by adjusting the pivot.
FIG. 10 is a diagram showing a function of preventing axial misalignment by the bracket shown in FIG. 6, FIG. 11 is a side view of the runner, and FIG. 12 is a sectional view of a main part thereof. 2 ... Upper rail, 6, 8 ... Folding door 18 ... Bracket, 24 ... Receiving recess 24b ... Guide inclined surface, 32 ... Pivot shaft 36a ... Engagement base, 36b ... Shaft center adjustment surface

Claims (1)

(57) [Scope of request for utility model registration] 1. A pivot shaft provided at an upper end of a folding door and projected upward by being biased by a spring, and a bracket having a receiving recess fixed in an upper rail and into which a tip end of the pivot shaft is engaged. A large diameter engaging base is formed at the distal end of the pivot shaft, and a frusto-conical shape having a vertex on the axis of the pivot shaft located at the further distal side of the engaging base. An axis adjusting surface is formed, and the receiving recess is formed with a receiving recess for receiving the engagement base and a conical guide inclined surface for guiding the axis adjusting surface and restoring the axial center deviation of the pivot shaft. The upper shaft support structure of the folding door.