JPH0740611Y2 - Carport that can be expanded / folded and stored freely - Google Patents

Description

[Detailed Description of the Invention] (a) Field of Industrial Use The present invention relates to a carport that can be stored in an expandable / foldable manner.

(B) Conventional Technology As a garage that can be freely expanded and folded and stored, various structures using sheet materials have been known.

(C) Issues to be solved by the invention However, in these garages (carports) that can be expanded and folded freely, sheet materials are used as roofing materials in order to facilitate the expansion and folding. Must be replaced within a few years because its durability will decrease due to sunburn.

Furthermore, because the sheet material is light, the skeleton is not carefully assembled. In addition, since there are many parts that have a rotatable mechanism so that the frame can be folded, there is a problem that the strength against load is low and the like, so that the garage using the sheet material has poor durability.

In addition, when folding a garage that uses sheet material, the skeleton and sheet material of the garage face the ground when it is folded, which hinders traffic. Further, since the framework of the garage is not firmly fixed to the ground, there is a drawback that the garage may be blown off in strong wind.

In addition, a metal pipe is bent into an L-shape, and one end of the L-shape is installed so as to be perpendicular to the ground, and a sheet material is stretched over the upper surface of the L-shaped support pillar that is substantially parallel to the ground to form a garage. The method has a drawback in that an L-shaped support portion, which is substantially parallel to the ground when the sheet material is stored, is located above the ground, which is an obstacle when carrying a high-height article.

(D) Means for Solving the Problem As a means for solving such a problem, the following car port that can be folded and stored is developed.

That is, the carport according to the present invention, which can be stored in the expandable / foldable manner, is composed of a combination of the storage unit (A) and the columns (1) and (2). And this pillar (1),
The end of (2) is fixed to the ground, and a rotatable drive arm (4), (5) and a roof frame for supporting the roof and a resin plate (9), (9a), (10) for the roof are supported on the upper part thereof. , (10a) are connected to the drive arms (4) and (5) of the storage unit (A). When either the drive arm (4) or the drive arm (5) connected so as to follow each other by the drive mechanism of the deployment frame (7) is moved in a direction away from the rain gutter (8), the drive arm is moved. (4) is rotated in the (W) direction with the support (1) as a fulcrum, and the drive arm (5) is rotated in the (V) direction with the support (2) as a fulcrum. At that time, the ceiling frame (11) is fixed by the sliding mechanism (20) fixed to approximately the central portion of the driving arm (4) bent in a mountain shape and approximately in the central portion of the driving arm (5) bent in a mountain shape. The space is widened while holding it in parallel with the rain gutter (8). Further, in conjunction with the connecting frame (17) fixed to the ceiling frame (11), the connecting frame (16) rotatably connected to the connecting frame (17), the outer frame (15) and the middle frame. The roof composed of the resin plates (9) and (10) fixed to (14) and the side frame (13) is expanded while being supported by the upper surfaces of the resin plates (9a) and (10a).

Further, a connecting frame (16), an outer frame (15), a middle frame (14) and a side frame (13) that are rotatably connected to the hinge mechanism of the rain gutter (8).
The roof made of the resin plate (10a) fixed to the resin plate is supported by the inclined drive arms (4) and (5) when the distance between the rain gutter (8) and the ceiling frame (11) is widened. It is deployed inside the roof composed of (10). Consists of a connecting frame (16) rotatably connected to the hinge mechanism of the unfolding frame (7), an outer frame (15), a middle frame (14), and a resin plate (9a) fixed to the side frame (13). The roof thus constructed is made of a resin plate (9) while being pulled by the deployment frame (7) pushed by the drive arms (4) and (5) and supported by the inclined drive arms (4) and (5). Deploy inside the roof. The carport roof that can be unfolded and folded is the props (1), (2) and drive arms (4), (5).
It will be configured to support.

When folding and storing the developed roof, when either the drive arm (4) or the drive arm (5) connected so as to follow each other is rotated, the drive arm (4) will be 1) is rotated in the (Y) direction with the fulcrum as the fulcrum, and the drive arm (5) is rotated in the (X) direction with the stanchion (2) as the fulcrum. Contrary to the unfolding, the ceiling frame (11) is driven by the drive arm. The sliding mechanism (20) fixed to (4) and the drive arm (5) keeps the space parallel to the rain gutter (8) while being held by the gutter (8) side and at the same time the drive arm (4), (5) is also folded to the rain gutter (8) side. At that time, the roof made of the resin plate (9a) is inside the roof made of the resin plate (9), and the roof made of the resin plate (10a) is inside the roof made of the resin plate (10). Are slid along the inclinations of the drive arms (4) and (5), respectively, and folded at the upper portions of the columns (1) and (2).

(E) Action To deploy the carport of the present invention, the prop (1),
When either the drive arm (4) or the drive arm (5) connected to the upper part of (2) is moved outward along the deployment frame (7), the drive that operates with the stanchions (1) and (2) as a fulcrum The roof is developed along the slopes of the arms (4) and (5) to form a carport. To fold, move either the drive arm (4) or the drive arm (5) inward along the deployment frame (7) and the roof will fold along the slope of the drive arms (4), (5). Be folded.

(F) Embodiment Hereinafter, an embodiment of the present invention will be described.

FIG. 1 shows an embodiment in a folded and stored state, in which columns (1) and (2) of metal pipe material are continuously provided and fixed vertically to the ground, and the upper portions of the columns (1) and (2) are fixed. The drive arms (4) and (5) of the storage unit (A) are connected to each other. This storage unit (A) includes drive arms (4), (5) for supporting the entire roof and resin plates (9), (9a), (1) for the roof.
0), (10a) and this resin plate (9), (9a), (10),
Side frame (13), middle frame (14), and outer frame (1) that reinforce (10a)
5), the connecting frame (16), the ceiling frame (11) and the deployment frame (7) that interlock with the operation of the drive arms (4) and (5), the reinforcement of the columns (1) and (2), and the resin plate. (Ten
It is composed of a rain gutter (8) having a function of restraining the motion of a).

Further, when folded and stored, the drive arms (4) and (5) and the resin plates (9a) and (10a) do not protrude from the storage unit (A), and the ceiling frame (11) is provided above the columns (1) and (2). ) And a resin plate (9), (10). The state of being housed in the rectangular frame is shown in FIG.
It is sectional drawing 6 between N. As shown in FIG. 5 and FIG. 6, driving is performed by rotatably supporting the sliding plate (23) fixed to the drive arm (4) with the pin (21) fixed to the column (1). The arm (4) can be rotatably operated about the support column (1) as a fulcrum at a height supported by the pin (21).

Furthermore, the operation of the drive arm (4) and the ceiling frame (11)
In order to interlock with each other, the bearing (24) is fixed to the uppermost part of the drive arm (4) bent in a mountain shape, and this bearing (24)
The shaft of the sliding mechanism (20) and the shaft of the sliding mechanism (20) are rotatably connected to each other, so that the rotation motion of the drive arm (4) that rotates about the support column (1) is fixed to the ceiling frame (11). The sliding mechanism (20) that moves the inside of 12) to the left and right changes to linear motion, and the drive arm (4) and the ceiling frame (11) work together. At this time, as will be described later, since the drive arm (4) and the drive arm (5) follow each other,
Similarly to the operation of the drive arm (4), the drive arm (5) rotatably connected to the support column (2) also changes the rotation operation with the support column (2) as a fulcrum into a linear motion by the sliding mechanism (20). The drive arm (5) and the ceiling frame (11) work together.

Resin plate (9), (9a), (10), (10a) and side frame (13)
One side of the roof composed of the inner frame (14), the outer frame (15), and the connecting frame (16) has a deployment frame (7) and a ceiling frame (1
It is connected to 1) and rain gutter (8), and the other side is free. The connecting frame (17) fixed to the ceiling frame (11), the resin plates (9) and (10), the side frame (13), the middle frame (14), the outer frame (15) and the connecting frame (16). Since the roof connecting frame (16) constituted by is rotatably connected, when the ceiling frame (11) is operated, the roof is composed of the resin plate (9) and the resin plate (10). The roof is interlocked with the ceiling frame (11). At that time, the resin plate (9a) and the side frame (1
3), the middle frame (14), the outer frame (15), and the roof connecting frame (16) composed of the connecting frame (16) and the hinge mechanism of the deploying frame (7) are rotatably connected. Therefore, when the unfolding frame (7) is activated, the roof made of the resin plate (9a) interlocks with the unfolding frame (7). Also, resin plate (10
a), side frame (13), middle frame (14), outer frame (15) and connecting frame (1
Since the roof connecting frame (16) composed of 6) and the hinge mechanism part of the rain gutter (8) are rotatably connected, the resin plate (10
The roof constructed in a) is not held by the rain gutter (8) and pulled by the movement of the drive arms (4), (5), but only along the inclination of the drive arms (4), (5). Work together.
At this time, the roof composed of the resin plates (9a) and (10a) is inclined along the inclination of the drive arms (4) and (5),
Furthermore, since the roof composed of the resin plates (9) and (10) on the upper surface of the roof operates along the inclination of the drive arms (4) and (5) while sliding, the developed roof has a mountain-shaped inclination. Form the roof.

FIG. 3 shows an embodiment in the middle of unfolding, in which the driving arms (4) and (5), which were parallel to the columns (1) and (2) when viewed from the top in the folded and stored state, were rained by a human operation. Interlocking with the deployment frame (7) pushed in the direction opposite to the gutter (8), the columns (1) and (2) are deployed as fulcrums at a slightly different angle when viewed from above. At that time, the roof composed of the resin plate (9a) pulled by the deployment frame (7) and the roof composed of the resin plate (10a) held by the rain gutter (8) are composed of the pillars (1), It follows the tilt angles of the drive arms (4) and (5) that change using (2) as a fulcrum.

The roof composed of the resin plates (9) and (10) is interlocked with the connecting frame (17) of the ceiling frame (11) connected to the drive arms (4) and (5), and the inclined resin plate (9a ),(Ten
Gradually change the angle along the upper surface of the roof constructed in a). At this time, as shown in FIG. 9, the roof made of the resin plate (10) is made of the resin plate (10a) so as to operate along the upper surface of the roof made of the resin plate (10a). Interlocking rollers (1) operating along the roof side frame (13)
9) was rotatably connected to the connecting plate (18). The connecting plate (18) is a side frame (13) of a roof made of a resin plate (10).
Left and right fixed to the outer frame (15) side of. Furthermore, resin plate (9a)
The roof configured by (1) and the roof configured by the resin plate (9) have the same configuration, and the connecting plate (18) that connects the connecting roller (19) to the side frame (13 of the roof formed by the resin plate (9). ) Stuck to the left and right. By this connecting mechanism, the roof made of the resin plate (9) is unfolded and folded along the slope of the resin plate (90a) without becoming different from the roof made of the resin plate (9a). In addition, the roof made of the resin plate (10) does not become the roof made of the resin plate (10a) and the resin plate (1
It is unfolded and folded along the slope of 0a).

FIG. 2 and FIG. 4 show the embodiment in the unfolded state. After pushing the unfolding frame (7) with a person to widen the space between the unfolding frame (7) and the rain gutter (8), the operation of further unfolding the roof is performed. Drive arm (4) or drive arm (5) that follows
The carport is completely unfolded by pushing with a person until it hits the fixing plate (28) fixed to the unfolding frame (7). At this time, the roof composed of the resin plates (9), (9a), (10), (10a) becomes a carport roof along the slopes of the drive arms (4), (5).

FIG. 7 shows the main part of the drive arm in the unfolded state, and the drive arm (4) bent in a mountain shape is formed by the support column (1).
It is rotatably connected with and the shaft center is taken out by the column support (22). The strut receiver (22) is also fixed with a rain gutter (8) which also serves to make the interval between the strut (1) and the strut (2) parallel. Further, the bearing (24) fixed to substantially the center of the drive arm (4) is rotatable so as to transmit the operation of the drive arm (4) operating with the support (1) as a fulcrum to the ceiling frame (11). A sliding mechanism (20) that operates on is connected.
The bearing (24) and the sliding mechanism (20) transmit the load applied to the ceiling frame (11) to the drive arm (4). Similarly, the drive arm (5) also supports the load of the ceiling frame (11) by the bearing (24) and the sliding mechanism (20). The drive bearing (27a) connected to the side of the drive arm (4) that faces the strut side is the drive arm (4).
It is fixed with bolts (35) to prevent it from coming off. The drive bearing (27a) comprises a bearing of the drive arm (4) and a drive pulley (26) for transmitting the operation of the drive arm (4) to the deployment frame (7). The drive arm (4) rotates about the column (1) as a fulcrum. At that time, the drive pulley (26) connected to the drive bearing (27a) moves left and right along the rails provided on the deployment frame (7), and the space between the deployment frame (7) and the gutter (8) is kept. The action to change slowly. At that time, a drive bearing (2) rotatably connected to the drive arm (5) that follows the drive arm (4).
The drive pulley (26) of 7) also moves left and right along the rails provided on the deployment frame (7). Therefore, the deploying frame (7) is interlocked with the drive arms (4) and (5) to change the distance between the deploying frame (7) and the rain gutter (8) evenly on the left and right.

FIG. 8 shows the structure of the sliding mechanism. A sliding frame (12) in which a sliding mechanism (20) is rotatably connected to a bearing (24) fixed to drive arms (4) and (5) and the sliding mechanism (20) is fixed to a ceiling frame (11). A roller (30) and a guide roll (31) are provided on the sliding mechanism (20) in order to smoothly operate inside.

10 and 11 show a deployment frame drive mechanism. Pulleys (25), (25) are provided at both ends of the deployment frame (7) so that the drive arm (4) and the drive arm (5) follow each other.
a) is rotatably fixed to the fixed plate (28) by the shaft (32), the wire (29) is stretched between the pulleys (25) and (25a) at both ends, and one side of the wire (29) is a drive bearing. The drive arm (4) was actuated in the (Y) direction by fixing it to the fixing pin (34) of (27) and fixing the opposing wire (29) to the fixing pin (34) of the drive bearing (27a). At this time, the drive arm (5) operates in the following (X) direction. At this time, the distance at which the drive arm (4) operates to the drive arm (4a) and the distance at which the drive arm (5) operates to the drive arm (5a) become the same, and the columns (1) and (2) are used as fulcrums. The angles of the drive arms (4) and (5) are the same, and the roof is folded parallel to the rain gutter (8). At this time, the drive bearings (27) and (27a) are respectively driven by the drive sheaves (26) so that the drive bearings (27) and (27a) are smoothly driven along the rails provided inside the deployment frame (7). ) Axis (3
Connected rotatably with 3). In addition, drive arm (4a)
When the drive arm (5a) is operated in the (W) direction, the drive arm (5a) follows the (V) direction, and when the drive arm (4a) to the drive arm (4) are operated, the drive arm (5a) is also the drive arm (5). Works up to. At this time, since the drive arms (4) and (5) having the stanchions (1) and (2) as fulcrums are deployed while having the same right and left angles, the rain gutter (8), the deployment frame (7), and the roof. Develops while holding parallel.

FIG. 12 shows an embodiment in which the drive arm is reinforced, and the load on the roof and the load applied to the roof are the maximum when the sloped portions of the drive arms (4) and (5) and the mountain shape are bent. Since it is applied to the upper part, the reinforcing frame (36) is fixed to the inside of the drive arms (4) and (5) that are bent in a mountain shape to reinforce the bending of the drive arms (4) and (5). be able to.

FIG. 13 shows an embodiment in which the number of columns is three or more. When the load on the roof is large or the width of the roof is wide, the number of columns is more than two, so that the columns (1), (2 ) And the drive arms (4) and (5) can be less loaded. The support pillar (3) is fixed to the middle of the support pillar (1) and the support pillar (2) perpendicularly to the ground, and on the upper part of the support pillar (3),
Revolving L-shaped reinforcing arm (6)
And the sliding mechanism (2) in the same manner as the drive arms (4) and (5) so as to interlock with the operation of the ceiling frame (11).
0) was fixed to the uppermost part of the reinforcing arm (6). The reinforcing arm (6) is slightly longer than the inclined surface of the drive arms (4) and (5) which are inclined with the support columns (1) and (2) as fulcrums, and the inclination angles thereof are the drive arms (4) and (5). ), The drive arm (4) and the drive arm (5) are parallel to each other when the roof is deployed, but the reinforcement arm (6)
Because the inclined surface is longer than the drive arms (4) and (5),
Drive arm (4) or drive arm (5) when viewed from above
It depends on either. Therefore, when sliding the roof, the sliding mechanism (20) fixed to the reinforcing arm (6)
It operates along the sliding frame (12) fixed to the ceiling frame (11), and the drive arm (4) side or the drive arm (5)
Fold to either side.

The distance between the support column (3) and the support column (1) is set at the center of the support column (1) so that the reinforcing arm (6) does not collide with the pipes and the sliding mechanism (20) of the drive arms (4) and (5). From the point in the horizontal position at the center point of the bearing (24) fixed to the drive arm (4) and at the center point of the bearing (24) fixed to the reinforcing arm (6) from the center point of the column (3). The distance is equal to or greater than the sum of the distance at the horizontal position and the length of the sliding mechanism (20). Further, the spacing between the columns (3) and the columns (2) is also the same.

Further, the distance between the bearing (24) fixed to the reinforcing arm (6) and the sliding mechanism (20) is set to be equal to or larger than the pipe diameter of the drive arms (4) and (5) so that the reinforcement arm (6) and the drive arm ( Fold without touching 4) and (5).

FIG. 14 shows an embodiment in which the inclination angle of the roof is made small, and a resin plate (9b) is formed on the upper surface of the deployment arms (7) of the drive arms (4) and (5) having the mountain-shaped inclination. The roof is connected to the deployment frame (7), and a resin plate (9
The roof composed of a) is connected to the roof composed of the resin plate (9b) and the resin plate (9), and the roof composed of the resin plate (9) is connected to the ceiling frame (11) on the upper surface thereof. The roof, which is connected to the frame (17) and the sloped surface on the side of the rain gutter (8) is also made of a resin plate (10b), is connected to the rain gutter (8) and is made of a resin plate (10a) on its upper surface. The roof is connected to the roof composed of resin plate (10b) and resin plate (10),
Further, by connecting the roof composed of the resin plate (10) on the upper surface thereof with the connecting frame (17) of the ceiling frame (11), the operation of the drive arms (4) and (5) and the resin plate (9),
The roof composed of (9a), (9b), (10), (10a), and (10b) works together.

In addition, since the height of the mountain portion of the drive arms (4) and (5) becomes lower as the roof inclination angle becomes smaller, the length of the roof made of the resin plate in the vertical direction must be made shorter than this height. , When folded, the side face does not become a rectangle covered with a roof made of resin plate. Therefore, the number of roofs made of resin plates increases.

FIG. 15 shows an embodiment in which the roof tilt angle is changed separately for the front and rear sides. In this embodiment, the driving is performed with a large tilt angle on the deployment frame (7) side and a small tilt angle on the rain gutter (8) side. Although the roof using the arms (4) and (5) is shown,
On the contrary, the inclination angle on the deployment frame (7) side may be small and the inclination angle on the rain gutter (8) side may be large.

FIG. 16 shows an example in which the roof is bent into a curved line. By making the entire roof into a curved line, the roof can be made to have a gentle feeling. Furthermore, the side surface when folded is different from a straight-sloped roof, and curved resin plates (9), (10)
Inside the roof composed of resin plates (9a), (9b),
The roof composed of (10a) and (10b) and the drive arms (4) and (5) can be stored.

Further, the carport according to the present invention, which can be unfolded and folded freely, can be used not only for roofs used for rain and sun protection of vehicles, but also for temporary storage of articles and roofs for stores.

(G) Effect of the Invention As described above, according to the present invention, the support columns (1) and (2) are fixed to the ground, and the rotatable drive arms (4) and
(5) is connected, and further, a roof that operates on the upper surface is connected, which is durable because it uses the same material size and material as a conventional fixed assembly carport. Of course you can. Since the roof using the resin plate can be folded to the columns (1) and (2) side, when the roof is folded and stored, the garage land can be used not only for storing cars and articles but also for other purposes. Furthermore, when the roof is unfolded, the space becomes wider, so the sun is better and there is an excellent effect that the land can be used effectively.

[Brief description of drawings]

FIG. 1 is a perspective view of a folded storage state, FIG. 2 is a perspective view of a developed state, FIG. 3 is a perspective view in the middle of developing, FIG. 4 is a perspective view from below in a developed state, and FIG. 1 is a sectional view taken along line MM in FIG. 1, FIG. 6 is a sectional view taken along line NN in FIG. 1, FIG. 7 is a side view of an essential part of a drive arm, and FIG. 8 is an essential part of a sliding mechanism. FIG. 9 is a perspective view, FIG. 9 is a perspective view of a main part of side frame connection,
Fig. 10 is a front view of the main parts of the expansion frame, Fig. 11 is a plan view of the main parts of the expansion frame, Fig. 12 is an embodiment in which the drive arm is reinforced, and Fig. 13 is an operation in the case of three or more columns. Example,
Fig. 14 shows an example in which the inclination angle of the roof is reduced,
The figure shows an example in which the roof tilt angle is changed separately for the front and rear,
FIG. 16 shows an example in which the roof is bent into a curved line. (1), (2), (3) ... Posts, (4), (4a),
(5), (5a) ... drive arm, (7) ... deployment frame, (9), (9a), (9b), (10), (10a), (10
b) ... Resin plate.

Claims (1)

[Scope of utility model registration request] 1. A pillar (1) having two or more erected on the ground,
(2) and chevron-shaped drive arms (4), (5) whose one ends are rotatably supported at the upper ends of the columns (1), (2)
And resin plates (9), (9a), (10), which are slidable on the drive arms (4), (5) along the width direction thereof.
A roof in which two or more plate members such as (10a) are connected to each other and one side of the resin plates (9) and (10) of the roof are rotatably connected to each other, and the drive arm (4),
It is attached to the ceiling frame (11) to which a long sliding frame (12) slidably connected to the uppermost part of (5) is fixed, and to the end side of the resin plate (9a) on the tip side of one roof, A deployment frame (7) in which the distal ends of the drive arms (4) and (5) are slidably connected, and a support column (1),
A rain gutter (8) erected over the upper end side of (2) and rotatably connected to the end side of the resin plate (10a) on the tip side of the other roof, and one of the drive arms (4) to the other. A carport that has a pulley mechanism that rotates the drive arm (5) in the opposite direction and can be stored and expanded and folded.