JP2023096536A - Vertical lattice mounting structure - Google Patents

Abstract

To provide a vertical lattice mounting structure capable of improving workability when a vertical lattice is mounted on a vertical member.SOLUTION: A vertical lattice mounting structure is made up of a hanging-side stile 34 and a hollow vertical lattice 4C. A stepped screw 5 is provided on a mounting surface portion 341 of the hanging-side stile 34. In the stepped screw 5, an enlarged head portion 52 has a width dimension larger than that of a shaft portion 51. A mounted surface portion 411 of the vertical lattice 4C is provided with a round-bellied hole 6 into which the stepped screw 5 is inserted, and a wedge member 9 engaged with the stepped screw 5 is arranged in the vertical lattice 4C. The wedge member 9 has a wedge body portion 91 fixed to the mounted surface portion 411, a wedge insertion hole 92 into which the enlarged head portion 52 is inserted, a wedge groove portion 93 extending from the wedge insertion hole 92, and a pressure contact portion 94 projecting from the wedge body portion 91. A pressure-contact portion 94 is arranged to be in pressure-contact with the enlarged head portion 52 in a state where the shaft portion 51 is in arranged with the wedge groove portion 93.SELECTED DRAWING: Figure 3

Description

TECHNICAL FIELD The present invention relates to a vertical grating mounting structure for mounting a vertical grating on a vertical member such as a gate post or a gate vertical frame.

Conventionally, a gate unit is known in which a gate post decorative member or a gate door decorative member in which a plurality of hollow vertical lattices are fixed to horizontal members is attached to a gate post or vertical frame (see Patent Document 1). In this gate unit, the vertical lattice is not attached directly to the pillars or vertical stiles, but is attached to the outdoor side of the pillars or vertical stiles via horizontal members.

JP 2009-228279 A

By the way, in the gate unit described in Patent Document 1, the vertical lattice is attached to vertical members such as pillars and vertical stiles via horizontal members, so the horizontal members are arranged between the vertical lattice and the vertical members. Therefore, the dimension in the out-of-plane direction becomes large.
Here, it is conceivable to reduce the dimension in the out-of-plane direction by directly attaching the vertical gratings to the vertical members without using the horizontal members. For example, when a vertical lattice is attached directly to a vertical member using fixing screws, it is necessary to pass the fixing screws of the vertical members from the indoor side, and the holes for passing the fixing screws may be exposed to the outside. I don't like the design. As a mounting structure for the vertical lattice where the holes and the like are not exposed to the outside, for example, while protruding stepped screws are provided on the vertical members, wedge members themselves are attached to the upper and lower ends of the hollow vertical lattice. to be engaged with the stepped screw.
However, when the wedge members are used to attach the grate directly to the uprights as described above, the grate must be held in place during the driving operation of the wedge members. For this reason, it takes time and effort to attach the vertical lattice, and it is difficult to improve workability.

SUMMARY OF THE INVENTION An object of the present invention is to provide a mounting structure for a vertical lattice that can improve workability for mounting the vertical lattice to vertical members.

The mounting structure of the vertical lattice of the present invention is composed of a vertical member having a mounting surface portion along the longitudinal direction and a hollow vertical lattice having a mounting surface portion abutting on the mounting surface portion, and the mounting surface portion of the vertical member. is provided with a projecting portion having a shaft portion projecting from the mounting surface portion and an enlarged head portion formed at the tip of the shaft portion, the enlarged head portion having a width dimension larger than that of the shaft portion; A hole portion through which the projecting portion is inserted is provided in the mounting surface portion of the vertical lattice, and the hole portion extends from the insertion hole through which the enlarged head portion is inserted and the insertion hole, and the shaft portion is disposed thereon. A wedge member that has a long hole and is engaged with the projecting portion is arranged in the vertical lattice, and the wedge member is formed in a wedge body portion fixed to the mounting surface portion and the wedge body portion. a wedge insertion hole through which the enlarged head is inserted; a wedge groove portion extending from the wedge insertion hole and in which the shaft portion is arranged; a pressure contact portion protruding from the main body portion, the pressure contact portion being located on the side of the enlarged head portion that is separated from the longitudinal member in the out-of-plane direction with the shaft portion disposed in the wedge groove portion. It is characterized in that it is arranged to be press-contacted toward.

ADVANTAGE OF THE INVENTION According to this invention, the mounting structure of a vertical lattice which can improve the workability which attaches a vertical lattice to a vertical member can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external view showing a gate on which a vertical lattice mounting structure according to a first embodiment of the present invention is formed; The top view which shows the gate in which the attachment structure of the vertical lattice which concerns on 1st Embodiment is formed. FIG. 4 is an explanatory diagram showing the vertical lattice in the mounting structure of the vertical lattice according to the first embodiment; The perspective view which shows the wedge member in the mounting structure of the vertical grating|lattice which concerns on 1st Embodiment. Explanatory drawing which shows the procedure which forms the mounting structure of the vertical grating|lattice which concerns on 1st Embodiment. Explanatory drawing which shows the procedure which forms the mounting structure of the vertical grating|lattice which concerns on 2nd Embodiment of this invention.

[First embodiment]
A first embodiment of the present invention will be described below with reference to the drawings.
The gate 1 shown in FIGS. 1 and 2 is of a double-opening type, and includes a gatepost 2 (longitudinal member) erected on the ground and a door body 3 supported by the gatepost 2 so as to be openable and closable. The gate post 2 is made of aluminum with a hollow rectangular cross section, and has a mounting surface portion 21 which is a facing surface portion facing the outdoors. A vertical grating 4D is attached. The door body 3 is made of aluminum and has a hollow rectangular cross section. The upper frame 31, the lower frame 32, the door tip side vertical frame 33 (vertical member), and the suspension side vertical frame 34 (vertical member) are combined into a frame body, A plurality of vertical lattices 4A attached to the outdoor facing surface portions 311 and 321 of the upper frame 31 and the lower frame 32, and a plurality of mounting surfaces 331 attached to the outdoor facing surface portion of the door leading frame 33. It is provided with a vertical lattice 4B and a plurality of vertical lattices 4C attached to a mounting surface portion 341, which is a facing surface portion on the outdoor side of the suspension-side vertical stile 34. As shown in FIG. A handle 36 for opening and closing operation is provided on the door tip side vertical frame 33 . The mounting structure of the vertical grating according to the first embodiment is the mounting structure of the vertical grating 4C to the suspension-side vertical frame 34 and the mounting structure of the vertical grating 4D to the gatepost 2 .
In the following description, the horizontal direction of the gate 1 is defined as the X-axis direction, the vertical direction of the gate 1 is defined as the Y-axis direction, and the projection direction (out-of-plane direction) of the gate 1 is defined as the Z-axis direction. The X-, Y-, and Z-axis directions are orthogonal to each other.

Mounting surface portions 21, 331, and 341 of the gatepost 2, the door-side vertical frame 33, and the suspension-side vertical frame 34, which are vertical members, are provided with stepped screws 5 (protruding portions) that protrude to the outside in the Z-axis direction. It is The stepped screw 5 is provided at a position corresponding to each upper end and each lower end of a plurality of short shape members 41B to be attached to the mounting surface portion 331 of the vertical frame 33 on the side of the door. Further, the stepped screws 5 are attached to the upper end portion 342, the lower end portion 343, and the intermediate portion 344 of the suspension-side vertical frame 34, respectively. Of these stepped screws 5, the stepped screw 5 attached to the upper end portion 342 of the suspension-side vertical frame 34 is an upward projecting portion in the present invention, and is attached to the lower end portion 343 of the suspension-side vertical frame 34. The attached screw 5 is a downward projecting portion in the present invention, and the stepped screw 5 attached to the intermediate portion 344 of the suspension-side vertical frame 34 is an intermediate projecting portion in the present invention. The mounting position of the stepped screw 5 to the gatepost 2 is the same as the mounting position of the stepped screw 5 to the suspension-side vertical frame 34 in the first embodiment.
The stepped screw 5 has a shaft portion 51 protruding outside from the mounting surface portions 21 , 331 , 341 and an enlarged head portion 52 formed at the tip of the shaft portion 51 . The enlarged head portion 52 has a width dimension larger than that of the shaft portion 51 .

The plurality of vertical lattices 4A are composed of aluminum profile members 41A having hollow rectangular cross sections. 311 and 321. Of the plurality of vertical lattices 4A, the vertical lattice 4A arranged on the door end side is configured by connecting vertically divided shape members 41A with connecting members so as not to interfere with the handle 36. As shown in FIG. Cap members are attached to the upper and lower ends of the shaped member 41A.

The plurality of vertical gratings 4B are composed of an aluminum shaped member 41B having a hollow rectangular cross-section that is shorter in the Y-axis direction than the vertical grating 4A, and upper wedges inserted into the upper and lower end portions of the shaped member 41B. It comprises a member 7 and a lower wedge member 8 . So-called daruma holes 6 (holes) are formed in the upper and lower ends of the facing surface (mounting surface) on the indoor side of the shape member 41B. The paddle hole 6 is formed in the same manner as the paddle hole 6 of the vertical lattice 4C, which will be described later.
This vertical lattice 4B is formed by engaging the stepped screws 5 of the door end side vertical frame 33 inserted through the potholes 6 with the upper wedge member 7 and the lower wedge member 8, so that the mounting surface portion of the door end side vertical frame 33 331 attached. In this embodiment, two shaped members 41B are arranged side by side in the X-axis direction above the handle 36 . Also, two of them are arranged side by side in the X-axis direction at a position below the handle 36 . Cap members are attached to the upper and lower ends of the shape member 41B. The upper wedge member 7 and the lower wedge member 8 are inserted into the shape member 41B, but instead of these, a wedge member 9, which will be described later, is attached to the upper end portion of the indoor facing surface portion (mounted surface portion) of the shape member 41B. , and the lower end portion, and may be fixed at a position corresponding to the hole 6 for pharmacies.

As shown in FIG. 3, the plurality of vertical gratings 4C are formed in a hollow shape having attached surface portions 411 that can come into contact with the mounting surface portion 341, and have the same vertical dimension as the vertical gratings 4A. The vertical lattice 4C includes an aluminum shape member 41C having a hollow rectangular cross section, an upper wedge member 7 and a lower wedge member 8 inserted into an upper end portion 412 and a lower end portion 413 of the shape member 41C, and and a wedge member 9 arranged in an intermediate portion 414 between the upper end portion 412 and the lower end portion 413 of the shape member 41C and separated from both in the Y-axis direction, and the upper end portion 412 of the shape member 41C And the upper and lower edges of the lower end portion 413 are attached with cap members 10 that cover the edges.
A mounting surface portion 411 of the vertical lattice 4C is provided with a paddle hole 6 as a hole portion through which each stepped screw 5 is inserted. 414 respectively.
The daruma hole 6 has an insertion hole 61 through which the enlarged head portion 52 is inserted, and an elongated hole 62 extending upward from the insertion hole 61 and in which the shaft portion 51 is arranged. The width dimension of the elongated hole 62 is set to be smaller than the width dimension of the enlarged head portion 52, so that the vertical lattice 4C can be easily positioned with respect to the suspension-side vertical stile 34. As shown in FIG.

The upper wedge member 7 is a plate-shaped wedge main body that is inserted into the shape member 41C from above along the inner surface of the attached surface portion 411 in the Y-axis direction and arranged at a position corresponding to the paddle hole 6 in the upper end portion 412. 71, a circular wedge insertion hole 72 formed in the wedge main body 71 and through which the enlarged head portion 52 of the stepped screw 5 as an upward protrusion is inserted; and a wedge groove portion 73 in which the shaft portion 51 of the stepped screw 5 is disposed; It has a pressure contact portion 74 which is cut and raised outward and protrudes. At the upper part of the wedge main body part 71, a plate-shaped wedge driving part 711 is bent toward the outside. It is inclined with respect to the Y-axis direction so as to taper downward, thereby improving the insertability into the shaped member 41C. The press-contact portion 74 is arranged to press-contact the enlarged head portion 52 toward the side away from the suspension-side vertical frame 34 in the Z-axis direction in a state where the shaft portion 51 is arranged in the wedge groove portion 73 . there is This upper wedge member 7 engages with a stepped screw 5 as an upward protrusion.

The lower wedge member 8 is a plate-shaped wedge main body portion that is inserted in the Y-axis direction from below into the shape member 41C along the inner surface of the attached surface portion 411 and arranged at a position corresponding to the hole 6 in the lower end portion 413. 81, a wedge insertion hole 82 formed in the wedge main body 81 and through which the enlarged head portion 52 of the stepped screw 5 as a downward projecting portion is inserted; The wedge groove portion 83 in which the shaft portion 51 of the stepped screw 5 is arranged, and the wedge main body portion 81 toward the outside in the Z-axis direction (out-of-plane direction) toward the side away from the suspension side vertical frame 34 It has a pressure contact portion 84 which is cut and raised to protrude. At the lower part of the wedge body part 81, a plate-shaped wedge driving part 811 is bent toward the outside. It is inclined with respect to the Y-axis direction so as to taper downward, thereby improving the insertability into the shaped member 41C. The press-contact portion 84 is arranged to press-contact the enlarged head portion 52 toward the side away from the suspension-side vertical frame 34 in the Z-axis direction in a state in which the shaft portion 51 is arranged in the wedge groove portion 83 . there is The lower wedge member 8 has a shape obtained by vertically inverting the upper wedge member 7, and engages with a stepped screw 5 as a downward projecting portion.

As shown in FIG. 4, the wedge member 9 includes a rectangular plate-shaped wedge body portion 91 screwed to the inner surface of the mounting surface portion 411, and a stepped screw formed on the wedge body portion 91 and serving as an intermediate projecting portion. a wedge insertion hole 92 through which the enlarged head portion 52 of the stepped screw 5 is inserted; a wedge groove portion 93 extending upward along the Y-axis direction from the wedge insertion hole 92 and in which the shaft portion 51 of the stepped screw 5 is arranged; It has a pressure contact portion 94 which is cut and raised from the wedge main body portion 91 and protrudes outward from the wedge main body portion 91 toward the side away from the suspension-side vertical frame 34 in the axial direction (out-of-plane direction).
The pressure contact portion 94 is composed of a pair of leaf spring portions 95 arranged along both edges of the long hole 62 in the attachment surface portion 411 and extending in the Y-axis direction. The leaf spring portion 95 includes a guide plate portion 951 raised from the wedge body portion 91 toward the side away from the suspension-side vertical frame 34 in the Z-axis direction, and a guide plate portion 951 that is continuous with the guide plate portion 951. It has a flat plate portion 952 along the axial direction and a connecting plate portion 953 that connects the flat plate portion 952 to the wedge body portion 91 . The guide plate portion 951 is arranged below the flat plate portion 952, and its upper end (the end connected to the flat plate portion 952) is positioned vertically toward the suspension side than the lower end (the end connected to the wedge main body portion 91). The attached surface portion 411 is inclined with respect to the Y-axis direction so as to be located on the side away from the frame 34 . The connecting plate portion 953 is arranged above the flat plate portion 952, and is turned in the opposite direction to the guide plate portion 951 so that the lower end thereof is located on the side farther from the suspension-side vertical frame 34 than the upper end. It is inclined with respect to the Y-axis direction. The angle of inclination of the connecting plate portion 953 is greater than the angle of inclination of the guide plate portion 951 . The press-contact portion 94 press-contacts the enlarged head portion 52 toward the side away from the suspension-side vertical frame 34 in the Z-axis direction while the shaft portion 51 is arranged in the wedge groove portion 93 .
The wedge member 9 is positioned such that a portion of the enlarged head portion 52 is hooked on the flat plate portion 952, and the upper portion of the enlarged head portion 52 exceeds the flat plate portion 952 and faces the connecting plate portion 953 in the Z-axis direction. By arranging, it will be in the engagement state engaged with the stepped screw 5 as an intermediate protrusion part.

As described above, the vertical lattice 4D is configured in the same manner as the vertical lattice 4C and is attached to the gatepost 2, so a detailed description of the vertical lattice 4D will be omitted.

A procedure for attaching the vertical lattice 4C to the hanging side vertical frame 34 of the gate 1 will be described below.
First, the stepped screws 5 are pre-attached to the mounting surface portions 341 of the upper end portion 342 , the lower end portion 343 and the intermediate portion 344 of the suspension-side vertical frame 34 .
Next, as shown in FIG. 5(A), each stepped screw 5 is inserted into each insertion hole 61 of the shaped member 41C, and the stepped screw 5 as an intermediate protrusion is inserted into the wedge insertion hole 92 of the wedge member 9. Next, as shown in FIG. Also insert the
Next, the shaped member 41C is driven in from above, and as shown in FIG. The portion 51 is placed in the wedge groove portion 93 . At this time, as the shaped member 41C moves downward with respect to the suspension-side vertical frame 34, the enlarged head portion 52 of the stepped screw 5 as the intermediate protruding portion slides against the guide plate portion 951 of the plate spring portion 95. Guided to the outdoor side, it then slides while being pressed against the flat plate portion 952, and as the shaped member 41C moves further downward, a part of the expanded head portion 52 is caught on the flat plate portion 952 and the expanded head portion 52 is displaced. The upper portion is arranged at a position facing the connecting plate portion 953 in the Z-axis direction beyond the flat plate portion 952 . At this position, the flat plate portion 952 is pressed against the enlarged head portion 52, and the wedge member 9 and the stepped screw 5 are engaged. In this way, the shape member 41C is provisionally positioned at a predetermined position with respect to the suspension-side vertical frame 34, and can be prevented from being separated from the suspension-side vertical frame 34 to the outdoor side, for example.
Next, as shown in FIG. 5(C), the upper wedge member 7 is inserted into the shaped member 41C from above, and the stepped screw 5 at the upper end portion 342 of the suspension-side vertical frame 34 is expanded into the wedge insertion hole 72. The head 52 is inserted. Subsequently, the wedge driving portion 711 of the upper wedge member 7 is driven downward to dispose the shaft portion 51 of the stepped screw 5 in the wedge groove portion 73 and press the enlarged head portion 52 against the pressing portion 74 . In this manner, the upper wedge member 7 and the stepped screw 5 as the upper projecting portion are engaged. Also, the lower wedge member 8 is inserted into the shaped member 41C from below, and the enlarged head portion 52 of the stepped screw at the lower end portion 343 of the vertical frame 34 on the suspension side is inserted into the wedge insertion hole 82 . Subsequently, the wedge driving portion 711 of the lower wedge member 8 is driven downward to dispose the shaft portion 51 of the stepped screw 5 in the wedge groove portion 73 and press the enlarged head portion 52 against the pressure contact portion 84 . In this manner, the lower wedge member 8 and the stepped screw 5 as the lower projecting portion are engaged.
Next, as shown in FIG. 5(D), the cap member 10 is attached so as to cover the upper and lower edges of the shaped member 41C, resulting in the state shown in FIG. 5(E).
By directly attaching the vertical lattice 4C to the suspension-side vertical frame 34 as described above, the mounting structure of the vertical lattice 4C in which the mounting surface portion 411 is in contact with the mounting surface portion 341 is configured. The vertical lattice 4D is attached to the gatepost 2 in substantially the same manner to constitute the mounting structure of the vertical lattice 4D.

[Second embodiment]
A second embodiment of the present invention will be described below with reference to the drawings.
The mounting structure of the vertical grating according to the second embodiment is configured in substantially the same manner as the mounting structure of the vertical grating according to the first embodiment, but as shown in FIG. Instead of the member 7 and the lower wedge member 8, a wedge member 9 fixed to the inner surface of the attached surface portion 411 of the shaped member 41C is provided. Therefore, in the second embodiment, the wedge member 9 is fixed to each of the upper end portion 412, the lower end portion 413 and the intermediate portion 414 of the shaped member 41C at positions corresponding to the paddle holes 6, respectively. For this reason, the press-contact portion 94 of the wedge member 9 press-contacts the enlarged head portions 52 of the stepped screws as the upward projecting portion, the downward projecting portion, and the intermediate projecting portion which are inserted into the respective hollows 6 .

In the second embodiment, the vertical lattice 4C is attached to the suspension side vertical frame 34 in the following procedure.
First, the cap members 10 shown in FIG. 6A are attached to the upper and lower edges of the shape member 41C to form the vertical lattice 4C. The cap member 10 may be attached in advance.
Next, as shown in FIG. 6(B), each stepped screw 5 is inserted through the insertion hole 61 and the wedge insertion holes 72, 82, 92 of the vertical lattice 4C. Subsequently, as shown in FIG. 6(C), the vertical grating 4C itself is driven in from above, the shafts 51 of the stepped screws 5 are arranged in the wedge grooves 73, 83, and 93 described above, and the enlarged heads are mounted. The pressure contact portions 74, 84, and 94 are brought into pressure contact with 52 to bring the wedge members 9 and the stepped screws 5 into an engaged state. In this way, the vertical lattice 4C is attached to the suspension-side vertical frame 34, and the mounting structure of the vertical lattice 4C is constructed.
Note that the vertical lattice 4D in the second embodiment is configured in the same manner as the vertical lattice 4C in the second embodiment, and may be attached to the gatepost 2 (see the first embodiment) in substantially the same manner.

[Modification]
In the first and second embodiments, the pressure contact portion 94 is composed of the plate spring portion 95. However, if the wedge member 9 and the stepped screw 5 can be engaged by moving the vertical lattice 4C downward, the plate spring The press-contact portion 94 may be configured in a configuration of 95 units and 8 units.
In the first embodiment, only one wedge member 9 is provided between the upper wedge member 7 and the lower wedge member 8 in the Y-axis direction to minimize the resistance during mounting of the vertical lattice 4C. A plurality of them may be arranged at intervals in the Y-axis direction according to the dimension in the longitudinal direction. Also in the second embodiment, a plurality of wedge members 9 may be arranged in the intermediate portion 414 of the vertical lattice 4C. A paddle hole 6 is formed according to the wedge member 9 .
In the first embodiment, the upper wedge member 7 and the lower wedge member 8 are inserted into the upper end portion 412 and the lower end portion 413 of the vertical grating 4C. It may be fixed to the mounting surface portion 411 instead of 9 .
In the first and second embodiments, the elongated hole 62 of the paddle hole 6 and the wedge groove portion 93 of the wedge member 9 are formed to extend upward. Alternatively, it may extend in a direction orthogonal to the Z-axis direction and crossing the Y-axis direction.
In the first and second embodiments, the mounting structure of the vertical lattice is configured as a gate, but it may be configured as a fence. In this case, the vertical members are columns of the fence.

[Summary of Invention]
The mounting structure of the vertical lattice of the present invention is composed of a vertical member having a mounting surface portion along the longitudinal direction and a hollow vertical lattice having a mounting surface portion abutting on the mounting surface portion, and the mounting surface portion of the vertical member. is provided with a projecting portion having a shaft portion projecting from the mounting surface portion and an enlarged head portion formed at the tip of the shaft portion, the enlarged head portion having a width dimension larger than that of the shaft portion; A hole portion through which the projecting portion is inserted is provided in the mounting surface portion of the vertical lattice, and the hole portion extends from the insertion hole through which the enlarged head portion is inserted and the insertion hole, and the shaft portion is disposed thereon. A wedge member that has a long hole and is engaged with the projecting portion is arranged in the vertical lattice, and the wedge member is formed in a wedge body portion fixed to the mounting surface portion and the wedge body portion. a wedge insertion hole through which the enlarged head is inserted; a wedge groove portion extending from the wedge insertion hole and in which the shaft portion is arranged; a pressure contact portion protruding from the main body portion, the pressure contact portion being located on the side of the enlarged head portion that is separated from the longitudinal member in the out-of-plane direction with the shaft portion disposed in the wedge groove portion. It is characterized in that it is arranged to be press-contacted toward.
According to the mounting structure of the vertical lattice of the present invention, the protrusions are inserted into the holes of the vertical lattice, and the vertical lattice is moved with respect to the vertical member, thereby causing the pressure contact portion of the wedge member to be pressed against the enlarged head. can be installed, and the vertical lattice can be attached directly to the vertical member. In this way, for example, compared to the installation work of driving the wedge member while holding the vertical lattice in a predetermined position, it is only necessary to move the vertical lattice itself, so the installation work of directly attaching the vertical lattice to the vertical members is simplified. can be carried out, and the workability can be improved.

In the vertical grating mounting structure of the present invention, the wedge main body is formed in a plate shape, and the pressure contact portion is a pair of leaf spring portions arranged along both edges of the long hole in the mounting surface portion. The plate spring portion includes a guide plate portion raised from the wedge main body portion toward the side away from the vertical member, a flat plate portion continuous with the guide plate portion, and the flat plate portion connected to the wedge. and a connecting plate portion connected to the main body portion, and the guide plate portion is arranged such that the end portion connected to the flat plate portion is positioned further away from the vertical member than the end portion connected to the wedge main body portion. and the wedge member may be engaged with the protruding portion at a position where at least a portion of the enlarged head portion is caught on the flat plate portion.
According to such a configuration, since the pair of leaf spring portions are arranged along both edges of the elongated hole, the pair of leaf spring portions are pressed against the enlarged head portion, for example, only one edge of the elongated hole. Compared to the case where the leaf spring portions are arranged along the grooves, the vertical lattice can be in an engaged state in which it is difficult for the vertical lattice to separate from the vertical member, and the mounting state of the vertical lattice with respect to the vertical member can be stabilized.
Further, in the leaf spring portion, the swollen head portion can be smoothly guided toward the flat plate portion by the guide plate portion inclined from the wedge main body portion, while the connecting plate portion connects the flat plate portion and the wedge main body portion. As compared with the case where there is no portion, the pressure contact force of the flat plate portion against the bulging head portion can be increased, and the bulging head portion can be made difficult to come off from the leaf spring portion. can be stabilized.

In the vertical grating mounting structure of the present invention, the long holes may be formed to extend upward from the insertion holes, and the wedge groove portions may be formed to extend upward from the wedge insertion holes.
According to such a configuration, by moving the vertical lattice downward with respect to the vertical member, the pressure contact portion of the wedge member can be brought into pressure contact with the enlarged head.

In the mounting structure of the vertical lattice of the present invention, the hole is provided in each of the upper end portion, the lower end portion, and the intermediate portion arranged between the upper end portion and the lower end portion of the vertical lattice, and the protrusion is provided. The portion includes an upward projection that is inserted into the hole at the upper end of the vertical lattice, a downward projection that is inserted into the hole at the lower end of the vertical lattice, and the intermediate portion of the vertical lattice. each of the upper protrusion, the lower protrusion and the intermediate protrusion has the shaft and the enlarged head, and the wedge member is , an upper wedge member engaged with the upper protrusion and a lower wedge member engaged with the lower protrusion are further arranged in the vertical lattice, The upper wedge member includes a wedge main body portion inserted and arranged in the vertical lattice along the mounting surface portion, and a wedge formed in the wedge main body portion and through which the enlarged head portion of the upward projecting portion is inserted. an insertion hole, a wedge groove portion extending upward from the wedge insertion hole and in which the shaft portion is arranged, and a pressure contact portion protruding from the wedge body portion toward the side away from the longitudinal member in the out-of-plane direction. The pressure contact portion of the upper wedge member is located on the side of the bulging head portion of the upward protruding portion that is away from the vertical member in the out-of-plane direction in a state where the shaft portion is disposed in the wedge groove portion. The lower wedge member includes a wedge main body portion inserted and arranged in the vertical lattice along the mounting surface portion, and a wedge main body portion formed on the wedge main body portion and on the lower protruding portion. a wedge insertion hole through which the swollen head portion is inserted; a wedge groove portion extending downward from the wedge insertion hole and in which the shaft portion is arranged; and a pressure contact portion protruding from a portion of the lower wedge member, wherein the pressure contact portion of the lower wedge member is out of plane with respect to the enlarged head portion of the lower protrusion with the shank disposed in the wedge groove. It may be arranged such that it presses against the side facing away from the longitudinal member in the direction.
According to such a configuration, for example, when there are no holes or wedge members in the middle part of the vertical lattice, only the upper end and the lower end of the vertical lattice are attached to the vertical members, and the longitudinal lattice The larger the dimension in the direction, the more likely that the intermediate portion will vibrate slightly due to the influence of wind or the like, making chattering noise more likely to occur. The middle part of the vertical lattice can be attached to the vertical member, and the above-described chattering noise can be suppressed.
Also, the wedge members and the intermediate projections can be engaged prior to inserting the upper and lower wedge members into the upper and lower ends of the longitudinal gratings so that the longitudinal gratings are in place. The labor for holding can be reduced, and the installation workability of the vertical lattice to the vertical members can be improved.

In the mounting structure of the vertical lattice of the present invention, the hole is provided in each of the upper end portion, the lower end portion, and the intermediate portion arranged between the upper end portion and the lower end portion of the vertical lattice, and the protrusion is provided. The portion includes an upward projection that is inserted into the hole at the upper end of the vertical lattice, a downward projection that is inserted into the hole at the lower end of the vertical lattice, and the intermediate portion of the vertical lattice. each of the upper protrusion, the lower protrusion and the intermediate protrusion has the shaft and the enlarged head, and the wedge member is , and fixed at positions corresponding to the holes provided in the upper end portion, the lower end portion, and the intermediate portion of the vertical lattice, and the pressure contact portion of the wedge member is positioned at the upper end portion, the lower end portion, and the intermediate portion of the vertical lattice. The arrangement may be such that the enlarged heads of the upward protrusion, the downward protrusion, and the intermediate protrusion inserted through the respective holes of the lower end and the intermediate portion are pressed against each other.
According to such a configuration, for example, when there are no holes or wedge members in the middle part of the vertical lattice, only the upper end and the lower end of the vertical lattice are attached to the vertical members, and the longitudinal lattice The larger the dimension in the direction, the more likely that the intermediate portion will vibrate slightly due to the influence of wind or the like, making chattering noise more likely to occur. The middle part of the vertical lattice can be attached to the vertical member, and the above-described chattering noise can be suppressed.
Further, by simply inserting the upward, intermediate and downward protrusions of the vertical member into the holes of the vertical lattice and moving the vertical lattice downward, the pressure contact portions of the wedge members are brought into contact with the bulging heads. In other words, it can be attached directly to the vertical members simply by driving the vertical gratings themselves from above. It is possible to eliminate the trouble of inserting and arranging the vertical lattice, and to easily attach the vertical lattice to the vertical member.

In the mounting structure of the vertical lattice of the present invention, a cap member may be attached to cover the edges at the upper end and the lower end of the vertical lattice.
According to such a configuration, since the cap member is attached to the edge of the vertical lattice, the exposure of the edge can be eliminated.
In addition, for example, in a configuration in which the upper wedge member and the lower wedge member are inserted into the vertical lattice at the upper end portion and the lower end portion of the vertical lattice, even if the upper wedge member and the lower wedge member are to come off unexpectedly, the cap member will hit them. Therefore, wedge detachment can be suppressed.

DESCRIPTION OF SYMBOLS 1... Gate, 10... Cap member, 2... Gate post, 21, 331, 341... Mounting surface part, 3... Door body, 31... Upper frame, 311, 321... Facing surface part, 32... Lower frame, 33... Door end side vertical Frame 34 Suspension-side vertical frame 342, 412 Upper end 343, 413 Lower end 344, 414 Intermediate portion 36 Handle 411 Mounting surface 41A to 41C Shape member 4A to 4D... Vertical grating, 5... Stepped screw, 51... Shaft part, 52... Enlarged head part, 6... Daruma hole (hole part), 61... Insertion hole, 62... Elongated hole, 7... Upper wedge member, 71, 81 , 91... Wedge main body 711, 811... Wedge driving part 72, 82, 92... Wedge insertion hole 73, 83, 93... Wedge groove part 74, 84, 94... Pressure contact part 8... Lower wedge member 9 ... Wedge member, 95 ... Leaf spring portion, 951 ... Guide plate portion, 952 ... Flat plate portion, 953 ... Connection plate portion.

Claims (6)

Composed of a vertical member having a mounting surface along the longitudinal direction and a hollow vertical lattice having a mounting surface that abuts on the mounting surface,
The mounting surface portion of the vertical member is provided with a projecting portion having a shaft portion projecting from the mounting surface portion and an enlarged head portion formed at the tip of the shaft portion,
The enlarged head has a width dimension larger than that of the shaft,
A hole through which the projecting portion is inserted is provided in the mounting surface portion of the vertical lattice,
the hole portion has an insertion hole through which the enlarged head portion is inserted and an elongated hole extending from the insertion hole and in which the shaft portion is arranged;
A wedge member that engages with the protrusion is disposed in the vertical lattice,
The wedge member includes a wedge body portion fixed to the mounting surface portion, a wedge insertion hole formed in the wedge body portion and through which the swollen head portion is inserted, and a shaft portion extending from the wedge insertion hole. and a pressure contact portion protruding from the wedge body portion toward the side away from the vertical member in the out-of-plane direction,
The press-contact portion is arranged to press-contact the bulging head portion in an out-of-plane direction toward a side away from the vertical member in a state in which the shaft portion is arranged in the wedge groove portion. The mounting structure of the vertical lattice. In the vertical grating mounting structure according to claim 1,
The wedge main body is formed in a plate shape,
The pressure contact portion is composed of a pair of leaf spring portions arranged along both edges of the long hole in the mounting surface portion,
The leaf spring portion includes a guide plate portion raised from the wedge body portion toward the side away from the vertical member, a flat plate portion continuous with the guide plate portion, and the flat plate portion connected to the wedge body portion. and a connecting plate portion to be connected,
The guide plate portion is inclined with respect to the mounting surface portion such that an end portion continuous with the flat plate portion is located on a side further away from the vertical member than an end portion continuous with the wedge body portion,
The mounting structure of the vertical lattice, wherein the wedge member is engaged with the protruding portion at a position where at least a part of the enlarged head portion overlaps with the flat plate portion. In the vertical grating mounting structure according to claim 1 or claim 2,
The long hole is formed extending upward from the insertion hole,
The vertical grating mounting structure, wherein the wedge groove portion is formed to extend upward from the wedge insertion hole. In the vertical grating mounting structure according to claim 3,
The holes are provided in each of the upper end portion, the lower end portion, and the intermediate portion disposed between the upper end portion and the lower end portion of the vertical lattice,
The protrusions include an upward protrusion inserted through the hole at the upper end of the vertical grating, a downward protrusion inserted through the hole at the lower end of the vertical grating, and the and an intermediate projecting portion inserted through the hole in the intermediate portion,
each of the upward protruding portion, the downward protruding portion and the intermediate protruding portion has the shaft portion and the enlarged head portion;
The wedge member is arranged to engage with the intermediate protrusion,
An upper wedge member that engages with the upper protrusion and a lower wedge member that engages with the lower protrusion are further disposed in the vertical lattice,
The upper wedge member includes a wedge main body portion inserted and arranged in the vertical lattice along the mounting surface portion, and a wedge formed in the wedge main body portion and through which the enlarged head portion of the upward projecting portion is inserted. an insertion hole, a wedge groove portion extending upward from the wedge insertion hole and in which the shaft portion is arranged, and a pressure contact portion protruding from the wedge body portion toward the side away from the longitudinal member in the out-of-plane direction. The pressure contact portion of the upper wedge member is located on the side of the bulging head portion of the upward protruding portion that is away from the vertical member in the out-of-plane direction in a state where the shaft portion is disposed in the wedge groove portion. It is arranged to press against the
The lower wedge member includes a wedge body portion inserted and arranged in the vertical lattice along the mounting surface portion, and a wedge formed in the wedge body portion and through which the swollen head portion of the downward projecting portion is inserted. an insertion hole, a wedge groove portion extending downward from the wedge insertion hole and in which the shaft portion is arranged, and a pressure contact portion protruding from the wedge body portion toward the side away from the longitudinal member in the out-of-plane direction. The pressure contact portion of the lower wedge member is located on the side of the bulging head portion of the downward protruding portion that is separated from the vertical member in the out-of-plane direction with the shaft portion disposed in the wedge groove portion. A mounting structure of a vertical lattice, characterized in that it is arranged to be pressed against. In the vertical grating mounting structure according to claim 3,
The holes are provided in each of the upper end portion, the lower end portion, and the intermediate portion disposed between the upper end portion and the lower end portion of the vertical lattice,
The protrusions include an upward protrusion inserted through the hole at the upper end of the vertical grating, a downward protrusion inserted through the hole at the lower end of the vertical grating, and the and an intermediate projecting portion inserted through the hole in the intermediate portion,
each of the upward protruding portion, the downward protruding portion and the intermediate protruding portion has the shaft portion and the enlarged head portion;
The wedge member is fixed at a position corresponding to the hole provided in each of the upper end, the lower end and the intermediate portion of the vertical lattice,
The press-contact portion of the wedge member includes enlarged heads of the upward protrusion, the downward protrusion, and the intermediate protrusion inserted through the holes of the upper end, the lower end, and the intermediate portion of the vertical grating, respectively. A mounting structure of a vertical lattice, characterized in that it is arranged to press against the part. In the vertical lattice mounting structure according to claim 4 or 5,
A mounting structure of a vertical lattice, wherein a cap member is attached to the edges of the upper end and the lower end of the vertical lattice to cover the edges.

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