JP4887029B2 - Assembled slope unit - Google Patents

Description

  The present invention relates to an assembly-type slope unit that is installed in an existing building structure or the like and enables passage of a wheelchair or the like.

For example, in a nursing home, a slope leading to the entrance is formed so that elderly people and persons with disabilities who need care can enter and exit with a wheelchair, etc. As such a slope, for example, patent literature 1 is disclosed.
In the residential care unit house of Patent Document 1, a slope that allows a care recipient to enter and exit with a wheelchair or the like is formed on the outdoor side of a sliding door provided therein. Thereby, the cared person can go in and out between indoors and outdoors while riding on the wheelchair.

  However, the conventional slope is provided in advance so as to communicate with the entrance of the house when the house is constructed. For this reason, it is not envisaged that a slope will be added after a house or facility has been constructed, and the development of a slope that can be added in a simple manner has been desired.

  Patent Document 2 discloses a portable slope that can be used by being bridged between the upper and lower steps of a step so that a wheelchair or the like can pass through the step safely. This portable slope improves portability by making it foldable. However, this portable slope is not developed for a house or a facility, and is not assumed to be used as a slope added to a house or a facility.

JP-A-8-296334 JP 2003-230597 A

  The present invention has been made in view of such conventional problems, and can be easily added to various existing building structures. The inclination angle of the inclined slope surface can be easily adjusted, and the inclination can be increased. An object of the present invention is to provide an assembly-type slope unit capable of maintaining high load bearing strength of the slope surface and handrail support.

1st invention is an assembly-type slope unit which has a floor part which forms a slope slope for passage, and a plurality of pillars which support the floor part,
The floor portion includes a floor frame that connects the struts adjacent to each other in the direction of travel of the inclined slope surface, and a floor board that is attached to the floor frame and forms the inclined slope surface.
The strut includes a leg strut portion having an extendable adjuster portion, a load receiving portion disposed at an upper end portion of the leg strut portion, and a handrail strut portion erected from the load receiving portion. The load receiving portion is formed with a mountain-shaped inclined surface for mounting the floor frame,
The floor frame is connected to the load receiving portion by a support shaft provided in a width direction orthogonal to the passage direction in a state of being placed on the mountain-shaped inclined surface,
The floor frame is inclined with respect to the leg struts by adjusting the length of the leg struts with the adjuster and rotating the floor frame about the support shaft. The assembled slope unit is characterized in that the inclined slope surface is formed by attaching the floor plate to a floor frame arranged (claim 1).

The assembly type slope unit of the present invention (hereinafter sometimes simply referred to as a slope unit) can be added later to an already constructed building structure.
And when adding the slope unit of this invention to an existing building structure, while adjusting the length of a leg support | pillar part by an adjuster part, a frame for floors is used for the fulcrum provided in the load receiving part. By rotating, the floor frame is inclined with respect to the leg support. Then, by attaching a floor board to the floor frame arranged in an inclined manner, inclined slope surfaces having various inclination angles can be easily formed.
Therefore, the slope unit can be easily added to various existing building structures.

Further, the inclination angle of the inclined slope surface can be adjusted along the floor frame along the mountain-shaped inclined surface of the load receiving portion. Therefore, it is easy to adjust the inclination angle of the inclined slope surface.
Moreover, the floor frame can be placed on the mountain-shaped inclined surface of the load receiving portion. Therefore, the floor frame can be stably disposed on the support column, and the load bearing strength of the inclined slope surface can be maintained high by the floor plate attached to the floor frame.

  Furthermore, the handrail strut part is erected on the leg strut part via the load receiving part, and even when the sloped slope surface is formed by the floor frame and the floor plate, the handrail pillar part is inclined with respect to the installation surface of the slope unit. There is no end. Thereby, even when the inclination angle of the inclined slope surface is adjusted, the handrail support column can be maintained substantially perpendicular to the installation surface. Therefore, when a handrail is configured by arranging a handrail member or the like orthogonal to the handrail support column, the strength of the handrail can be maintained high.

  Therefore, according to the assembly type slope unit of the present invention, it can be easily added to various existing building structures, the inclination angle of the inclined slope surface can be easily adjusted, and the inclined slope surface and The load bearing strength of the handrail strut can be maintained high.

The second invention is a prefabricated slope unit comprising a floor portion that forms an inclined slope surface for passage, and a plurality of struts that support the floor portion,
The floor portion includes a floor frame that connects the struts adjacent to each other in the direction of travel of the inclined slope surface, and a floor board that is attached to the floor frame and forms the inclined slope surface.
The support column is formed with a jack base support column in which a male screw portion of the jack is erected and a female screw portion of a jack screwed into the male screw portion of the jack, and for mounting the floor frame. A load receiving portion formed of a mountain-shaped inclined surface, a handrail strut portion connected to an upper portion of the jack male screw portion, a screwed state of the jack male screw portion and the jack female screw portion. It has a locking nut that prevents locking,
The floor frame is connected to the load receiving portion by a support shaft provided in a width direction orthogonal to the passage direction in a state of being placed on the mountain-shaped inclined surface,
By adjusting the screwing height of the jack female screw portion with respect to the jack male screw portion and rotating the floor frame about the support shaft, the floor frame is inclined with respect to the support column. The assembled slope unit is configured to form the inclined slope surface by arranging and attaching the floor plate to the inclined floor frame.

The assembly-type slope unit of the present invention (hereinafter sometimes simply referred to as a slope unit) can also be added later to an already constructed building structure.
When the slope unit of the present invention is added to an existing building structure, the screwing height of the female screw portion for jack with respect to the male screw portion for jack is adjusted, and the support shaft provided in the load receiving portion is adjusted. By rotating the floor frame about the fulcrum, the floor frame is inclined with respect to the support column. Then, by attaching a floor board to the floor frame arranged in an inclined manner, inclined slope surfaces having various inclination angles can be easily formed.
Therefore, the slope unit can also be easily added to various existing building structures.

Also in the present invention, similarly to the first invention, the inclination angle of the inclined slope surface can be easily adjusted, the load-bearing strength of the inclined slope surface can be maintained high, and the handrail strut portion is used. The strength of the handrail constructed can be maintained high.
Therefore, the assembly-type slope unit of the present invention can be easily added to various existing building structures, and the inclination angle of the inclined slope surface can be easily adjusted, and the inclined slope surface and the handrail can be easily adjusted. The load bearing strength of the support can be kept high.

The reference invention is an assembly-type slope unit having a floor portion that forms an inclined slope surface for passage and a plurality of support columns that support the floor portion,
The column includes a jack base column in which a jack male screw portion is erected, a load receiving portion that forms a jack female screw portion that is screwed to the jack male screw portion, and the jack male screw. A handrail strut connected to the upper part of the part, and a locking nut for preventing loosening of the screwed state of the male screw portion for jack and the female screw portion for jack,
The floor portion is placed on the round pipe member and a round pipe member that spans between the load receiving portions of the struts facing each other in the width direction perpendicular to the direction of passage of the inclined slope surface. With floorboards,
By adjusting the screwing height of the jack female screw part with respect to the male screw part for jack and rotating the floor board around the round pipe member as a fulcrum, the floor board is inclined with respect to the column. The assembly type slope unit is configured to form the inclined slope surface .

The assembly-type slope unit of the present invention (hereinafter sometimes simply referred to as a slope unit) can also be added later to an already constructed building structure.
When the slope unit of the present invention is added to an existing building structure, the screwing height of the female screw portion for the jack with respect to the male screw portion for the jack is adjusted, and the floor plate is used with the round pipe member as a fulcrum. By turning, it is possible to easily form inclined slope surfaces having various inclination angles by inclining the floorboard with respect to the support column.
Therefore, the slope unit can also be easily added to various existing building structures.

Further, the inclination angle of the inclined slope surface can be adjusted along the curved surface of the round pipe member. Therefore, it is easy to adjust the inclination angle of the inclined slope surface. Moreover, a floor board can be mounted on the curved surface of a round pipe member. Therefore, the floor board can be stably arranged with respect to the support column, and the load resistance strength of the inclined slope surface can be maintained high by this floor board.
Therefore, the assembly-type slope unit of the present invention can be easily added to various existing building structures, and the inclination angle of the inclined slope surface can be easily adjusted, and the inclined slope surface and the handrail can be easily adjusted. The load bearing strength of the support can be kept high.

A preferred embodiment in the first and second inventions described above will be described.
In the first aspect of the invention, the load receiving portion is formed with screw holes at front and rear positions in the passage direction with respect to the apex portion of the mountain-shaped inclined surface, and the floor frame is screwed into the screw holes. It is preferable to be fixed to the load receiving portion by means of a combined screw (claim 2).
In this case, the inclination angle of the floor frame can be stably maintained with respect to the load receiving portion by the mountain-shaped inclined surface and the screws at the front and rear positions in the passage direction.

In the second invention, it is preferable that the handrail support portion is formed by fitting a round pipe member into the upper portion of the male screw portion for jack.
In this case, the handrail strut can be very easily connected to the upper part of the jack male thread in the jack base strut.

In the above reference invention, the floor board is divided into a plurality of floor board pieces, and the floor board piece includes a floor board portion to be placed on the round pipe member, and both ends of the floor board portion in the passage direction. It is preferable that the floor plate pieces that are adjacent to each other in the passage direction are connected to each other by the side plate portion .
In this case, it is easy to improve the strength of the floor board, and to easily place the floor board on the round pipe member, and to improve the assembling property of the assembly-type slope unit.

Further, the floor plate pieces adjacent to each other in the width direction are an inner surface of a side plate portion located on one side in the passage direction in one floor plate piece and a side plate portion located on the other side in the passage direction in the other floor plate piece. The round pipe member is preferably sandwiched between the inner side surface .
In this case, the strength of the floor board can be further improved. Moreover, it is easy to rotate the floor board piece with the round pipe member as a fulcrum, and the slope angle of each floor board piece can be adjusted appropriately to form an inclined slope surface.

Hereinafter, embodiments of the assembly type slope unit of the present invention will be described with reference to the drawings.
Example 1
As shown in FIGS. 1 to 5, the assembly-type slope unit 1 (hereinafter, simply referred to as the slope unit 1) of the present example has a sweep window or a ridge 81 such as a small edge in a building structure 8 such as an existing house. It is installed on the outdoor side, and a wheelchair or the like can be put in and out between the hill part 81 and the outdoors.
Moreover, the slope unit 1 has the floor part 2 which forms the inclined slope surface 41 for a wheelchair etc. to pass through, and the some support | pillar 5 which supports this floor part 2 from four directions.

  As shown in FIGS. 4 and 5, the floor portion 2 includes the floor frame 3 that connects the columns 5 adjacent to each other in the passage direction L of the inclined slope surface 41, and the inclined slope surface 41 attached to the floor frame 3. And a floor plate 4 that forms The strut 5 includes a leg strut portion 6 having an extendable adjuster portion 60, a load receiving portion 7 disposed at the upper end portion of the leg strut portion 6, and a handrail strut portion 51 erected from the load receiving portion 7. And have. The load receiving portion 7 is formed with a mountain-shaped inclined surface 71 for placing the floor frame 3 thereon.

As shown in the figure, the floor frame 3 is connected to the load receiving portion 7 by a support shaft 64 provided in the width direction W orthogonal to the passage direction L while being placed on the mountain-shaped inclined surface 71.
The assembly-type slope unit 1 adjusts the length of the leg support 6 by the adjuster 60 and rotates the floor frame 3 about the support shaft 64, thereby making the floor support 3 a leg support. 6 and the slope plate 41 is formed by attaching the floor plate 4 to the floor frame 3 that is inclined.

Hereinafter, the assembly type slope unit 1 of this example will be described in detail with reference to FIGS.
As shown in FIG. 1 to FIG. 3, the slope unit 1 of the present example uses the hill portion 81 such as a sweep window or a small edge in an existing house or existing facility that has already been constructed, It is intended to allow people with weakness (users) such as the elderly and disabled to enter and leave between indoors and outdoors, and can be added later to various existing houses or facilities. Is. And the slope unit 1 of this example is a portable assembly-type slope unit 1, and conveys each component member in a disassembled state to an existing house or an existing facility where the slope unit 1 needs to be added. By assembling the components in the garden of an existing facility, the device has been devised so that it can be easily assembled even if it is not a specialist in construction.

In addition, FIG. 1 is a figure which shows the slope unit 1 connected and installed in the hill part 81 in the existing house or the existing facility in the state seen from the side, FIG. 2 is a top view of the slope unit 1 FIG. 3 is a front view of the slope unit 1.
As shown in FIGS. 1 to 3, in the slope unit 1 of the present example, the horizontal floor surface 40 formed by the floor portion 2 is connected to the hill portion 81, and the above-described inclined slope surface 41 with respect to the horizontal floor surface 40. Were combined.

The slope unit 1 of the present example includes a floor frame 3 and a floor plate 4 that constitute the floor portion 2, a leg strut portion 6 that constitutes the column 5, a load receiving portion 7, a handrail column portion 51 and the like before assembly. Each component is disassembled and can be transported by a transport vehicle such as a truck in this disassembled state.
As shown in FIGS. 4 and 5, the floor frame 3 of this example is configured using a channel including a center plate portion 31 and a pair of side plate portions 32 erected from both ends of the center plate portion 31. The inner side surface of the center plate portion 31 faces downward on the mountain-shaped inclined surface 71 of the load receiving portion 7.

  As shown in FIG. 4, the load receiving portion 7 of this example is formed by forming a mountain-shaped inclined surface 71 on the upper surface of the block material. The load receiving portion 7 is formed with screw holes 72 at front and rear positions in the passage direction L with respect to the apex portion of the mountain-shaped inclined surface 71. The floor frame 3 is fixed to the load receiving portion 7 with screws 73 screwed into the screw holes 72. Accordingly, the inclination angle of the floor frame 3 can be stably maintained with respect to the load receiving portion 7 by the mountain-shaped inclined surface 71 and the screws 73 at the front and rear positions in the passage direction L.

  Further, as shown in FIG. 5, the load receiving portion 7 is formed with a shaft hole 74 through which the shaft 64 is inserted. And in the state which inserted the support shaft 64 in the support shaft hole 74 of the load receiving part 7, both ends of this support shaft 64 are spanned between the side plate parts 32 of the floor frame 3, thereby the floor. The working frame 3 is rotatable with respect to the load receiving portion 7. Further, the floor frame 3 is rotatable while being placed on the mountain-shaped inclined surface 71 of the load receiving portion 7.

Further, the floor plate 4 is formed by forming a framework from various members such as angles (L-shaped steel), channels, and C-shaped steel, and a plate material such as a striped steel plate and an expanded metal is disposed on the framework.
Moreover, the floor part 2 and the support | pillar 5 can be comprised using the member which consists of aluminum for weight reduction.

As shown in FIG. 4, the leg strut portion 6 of this example is adjusted to be screwed into the screw strut portion 612 at the lower end of the round pipe 621 and the leg strut lower portion 61 in which the thread portion 612 is erected on the pedestal top 611. It comprises a leg strut upper part 62 formed by welding a nut 622 for use. The adjuster portion 60 of the present example has a threaded portion 612 disposed in the round pipe 621, and the lower end of the leg strut in a state where the male threaded portion 612 is screwed to the adjustment nut 622 welded to the lower end of the round pipe 621. The height from the ground to the load receiving portion 7 is adjusted by rotating 61 with respect to the upper portion 62 of the leg column. Further, a locking nut 63 is screwed onto the male screw portion 612, and the length of the leg support 6 can be fixed by tightening the locking nut 63 with respect to the adjusting nut 622.
Further, as shown in FIG. 5, the handrail support column 51 of this example is connected to the load receiving portion 7 and the floor frame 3 with a pair of connecting plate portions 511 disposed at the lower ends thereof. It is.

In the assembling-type slope unit 1 of this example, the inclination angle of the inclined slope surface 41 is easily adjusted and the load resistance strength of the inclined slope surface 41 is improved.
And when adding the slope unit 1 of this example to the existing building structure 8, while adjusting the length of the leg support | pillar part 6 with the adjuster part 60, the spindle 64 provided in the load receiving part 7 is used. By rotating the floor frame 3 around the fulcrum, the floor frame 3 is inclined with respect to the leg support 6. After that, by attaching the floor plate 4 to the floor frame 3 that is inclined, the inclined slope surface 41 having various inclination angles can be easily formed.
Therefore, the slope unit 1 can be easily added to various existing building structures 8.

Further, the inclination angle of the inclined slope surface 41 can be adjusted along the mountain-shaped inclined surface 71 of the load receiving portion 7 with the floor frame 3. Therefore, the inclination angle of the inclined slope surface 41 can be easily adjusted.
Further, the floor frame 3 can be placed on the mountain-shaped inclined surface 71 of the load receiving portion 7. Therefore, the floor frame 3 can be stably disposed with respect to the support column 5, and the load bearing strength of the inclined slope surface 41 can be kept high by the floor plate 4 attached to the floor frame 3.

  Further, the handrail column 51 is erected on the leg column 6 via the load receiving unit 7, and the slope unit 1 is installed even when the inclined slope surface 41 is formed by the floor frame 3 and the floor plate 4. There is no inclination with respect to the surface (ground). Thereby, even when the inclination angle of the inclined slope surface 41 is adjusted, the handrail support column 51 can be maintained substantially perpendicular to the installation surface. Therefore, when the handrail 50 (see FIG. 3) is configured by arranging the handrail member 52 and the like orthogonal to the handrail support column 51, the strength of the handrail 50 can be maintained high.

  Therefore, according to the assembly-type slope unit 1 of this example, it can be easily added to various existing building structures 8, the inclination angle of the slope slope surface 41 can be easily adjusted, and the slope The load bearing strength of the slope surface 41 and the handrail support column 51 can be maintained high.

(Example 2)
As shown in FIG. 6, the assembly-type slope unit 1 of this example uses the following jack base column 65 and the like instead of the leg column 6 of the column 5.
Specifically, as shown in the figure, the column 5 of the present example includes a jack base column 65 in which a male screw portion 651 for jacks is erected and a mountain-shaped inclined surface on which the floor frame 3 is placed. 71 and a handrail column 51 connected to the upper part of the male screw portion 651 for the jack. The load receiving portion 7 of this example is formed with a jack female screw portion 75 that is screwed into the jack male screw portion 651.

The height of the load receiving portion 7 from the ground is adjusted by relatively rotating the jack female screw portion 75 formed on the load receiving portion 7 and the jack male screw portion 651 in the jack base column 65. Can do.
Further, in the column 5 of this example, a locking nut 63 is screwed onto the jack male screw portion 651, and the load receiving portion is lifted from the ground by tightening the locking nut 63 against the load receiving portion 7. The height up to 7 can be fixed.

As shown in FIG. 6, the floor frame 3 of this example is configured by using an angle member having an L shape with a pair of plate portions orthogonal to each other, and the mountain-shaped inclined surface 71 of the load receiving portion 7 includes The inner surface of one plate portion of the angle member is brought into contact.
Further, the load receiving portion 7 is provided with a support shaft 64 toward the inner side in the width direction W orthogonal to the passage direction L of the inclined slope surface 41. The support shaft 64 is configured by a bolt, is inserted into a support shaft hole 33 formed in the other plate portion of the angle member, and is screwed into the load receiving portion 7.

Then, in a state where the support shaft 64 is inserted into the support shaft hole 33 of the floor frame 3, the support shaft 64 is screwed into the load receiving portion 7, so that the floor frame 3 is attached to the load receiving portion 7. Can be rotated. Further, the floor frame 3 is rotatable while being placed on the mountain-shaped inclined surface 71 of the load receiving portion 7.
In addition, the load receiving part 7 of this example was comprised with the casting. On the other hand, as shown in FIG. 7, the load receiving portion 7 forms, for example, a frame by welding a pair of angles 75, and a block member 76 in which the mountain-shaped inclined surface 71 is formed on the frame. It can also be constructed by welding.

  When the slope unit 1 of this example is added to the existing building structure 8, the screwing height of the jack female screw portion 75 to the jack male screw portion 651 is adjusted, and the load receiving portion 7 is provided. The floor frame 3 is tilted with respect to the column 5 by rotating the floor frame 3 with the support shaft 64 as a fulcrum. After that, by attaching the floor plate 4 to the floor frame 3 that is inclined, the inclined slope surface 41 having various inclination angles can be easily formed. Therefore, the slope unit 1 of this example can also be easily added to various existing building structures 8.

Also in this example, as in the first embodiment, the inclination angle of the inclined slope surface 41 can be easily adjusted, the load bearing strength of the inclined slope surface 41 can be maintained high, and the handrail support column 51 It is possible to maintain the strength of the handrail 50 constituted by using the high.
Also in the assembly-type slope unit 1 of this example, the other configurations are the same as those of the first embodiment, and the same functions and effects as those of the first embodiment can be obtained.

( Reference example )
As shown in FIGS. 8 to 10, the assembly-type slope unit 1 of this example is configured by using a round pipe member 35 instead of forming the mountain-shaped inclined surface 71 in the load receiving portion 7. Further, in this example, the floor frame 3 is not used, and the floor plate 4 is rotated around the round pipe member 35 as a fulcrum instead of providing the support shaft 64 in the load receiving portion 7. Yes.
Specifically, the floor portion 2 of the present example has a round pipe member 35 that spans between the load receiving portions 7 of the struts 5 that face each other in the width direction W orthogonal to the passing direction L of the inclined slope surface 41. And a floor plate 4 placed on the round pipe member 35.

  Further, as shown in FIGS. 9 and 10, the floor board 4 of this example is divided and formed into a plurality of floor board pieces 45, and each floor board piece 45 has a floor board portion 451 placed on the round pipe member 35, and The floor plate portion 451 includes a pair of side plate portions 452 that are bent downward from both end portions in the passage direction L. The floor plate pieces 45 adjacent to each other in the traffic direction L are connected by a side plate portion 452. Further, in the passage direction L and the width direction W, the floor plate pieces 45 adjacent to each other can be welded to fix the connected state.

Further, as shown in FIG. 10, the floor plate pieces 45 adjacent to each other in the width direction W are connected to the inner surface of the side plate portion 452 </ b> A located on one side of the passage direction L in one floor plate piece 45 and the other floor plate piece 45. A round pipe member 35 is sandwiched between the inner surface of the side plate portion 452B located on the other side in the passage direction L.
As shown in FIG. 8, the connection of the round pipe member 35 to the load receiving portion 7 can be performed using a flange member 36 provided with an insertion shaft 361 for insertion into the end of the round pipe member 35.

When the slope unit 1 of this example is added to the existing building structure 8, the screwing height of the female screw portion 75 for the jack with respect to the male screw portion 651 for the jack is adjusted, and the round pipe member 35 is adjusted. The floor board pieces 45 are rotated with respect to the fulcrum, so that each floor board piece 45 is inclined with respect to the support column 5. And the floor board pieces 45 adjacent to the passing direction L can be connected by the side-plate part 452, and the inclined slope surface 41 which has various inclination angles can be formed easily.
Therefore, the slope unit 1 of this example can also be easily added to various existing building structures 8.

Further, the inclination angle of the inclined slope surface 41 of this example can be adjusted along the floor plate 4 along the curved surface of the round pipe member 35. Therefore, the inclination angle of the inclined slope surface 41 can be easily adjusted. Further, the floor plate 4 can be placed on the curved surface of the round pipe member 35. Therefore, the floor plate 4 can be stably disposed with respect to the support column 5, and the load bearing strength of the inclined slope surface 41 can be maintained high by the floor plate 4.
Also in the assembly-type slope unit 1 of this example, the other configurations are the same as those of the first and second embodiments, and the same effects as those of the first and second embodiments can be obtained.

Explanatory drawing shown in the state which looked at the assembly-type slope unit installed in connection with the hill part in the existing house or the existing facility in Example 1 from the side. The top view which shows the assembly-type slope unit in Example 1. FIG. The front view which shows the assembly-type slope unit in Example 1. FIG. Sectional explanatory drawing which shows the principal part in an assembly-type slope unit in Example 1 in the state seen from the width direction. Sectional explanatory drawing which shows the principal part in an assembly-type slope unit in Example 1 in the state seen from the passing direction. Cross-sectional explanatory drawing which shows the principal part in the assembly-type slope unit in Example 2 seen from the passing direction. Sectional explanatory drawing which shows the principal part in the other assembly-type slope unit in Example 2 seen from the passing direction. Cross-sectional explanatory drawing which shows the principal part in an assembly-type slope unit in a reference example in the state seen from the passing direction. Explanatory perspective drawing which shows the state which formed the floor part with the floor-plate piece in a reference example . Cross-sectional explanatory drawing which shows the state in which the floor part was formed with the floor board piece in a reference example .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Assembling-type slope unit 2 Floor part 3 Floor frame 35 Round pipe member 4 Floor board 41 Inclined slope surface 45 Floor board piece 5 Support | pillar 51 Handrail support | pillar part 6 Leg support | pillar part 60 Adjuster part 64 Support shaft 65 Jack base support | pillar 651 Jack screw Part 7 Load receiving part 71 Mountain-like inclined surface 75 Female screw part for jack 8 Building structure 81 Height part L Passing direction W Width direction

Claims (4)

An assembly type slope unit having a floor portion that forms an inclined slope surface for passage, and a plurality of support columns that support the floor portion,
The floor portion includes a floor frame that connects the struts adjacent to each other in the direction of travel of the inclined slope surface, and a floor board that is attached to the floor frame and forms the inclined slope surface.
The strut includes a leg strut portion having an extendable adjuster portion, a load receiving portion disposed at an upper end portion of the leg strut portion, and a handrail strut portion erected from the load receiving portion. The load receiving portion is formed with a mountain-shaped inclined surface for mounting the floor frame,
The floor frame is connected to the load receiving portion by a support shaft provided in a width direction orthogonal to the passage direction in a state of being placed on the mountain-shaped inclined surface,
The floor frame is inclined with respect to the leg struts by adjusting the length of the leg struts with the adjuster and rotating the floor frame about the support shaft. An assembly type slope unit characterized in that the inclined slope surface is formed by attaching the floor plate to a floor frame arranged. In Claim 1, the load receiving part is formed with screw holes at front and rear positions in the passage direction with respect to the apex part of the mountain-shaped inclined surface.
The assembly-type slope unit, wherein the floor frame is fixed to the load receiving portion with a screw screwed into the screw hole. An assembly type slope unit having a floor portion that forms an inclined slope surface for passage, and a plurality of support columns that support the floor portion,
The floor portion includes a floor frame that connects the struts adjacent to each other in the direction of travel of the inclined slope surface, and a floor board that is attached to the floor frame and forms the inclined slope surface.
The support column is formed with a jack base support column in which a male screw portion of the jack is erected and a female screw portion of a jack screwed into the male screw portion of the jack, and for mounting the floor frame. A load receiving portion formed of a mountain-shaped inclined surface, a handrail strut portion connected to an upper portion of the jack male screw portion, a screwed state of the jack male screw portion and the jack female screw portion. It has a locking nut that prevents locking,
The floor frame is connected to the load receiving portion by a support shaft provided in a width direction orthogonal to the passage direction in a state of being placed on the mountain-shaped inclined surface,
By adjusting the screwing height of the jack female screw portion with respect to the jack male screw portion and rotating the floor frame about the support shaft, the floor frame is inclined with respect to the support column. An assembly type slope unit characterized in that the inclined slope surface is formed by mounting and attaching the floor plate to the inclined floor frame.   4. The assembly type slope unit according to claim 3, wherein the handrail support column part is formed by fitting a round pipe member into an upper part of the male screw part for jack.

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