CN219993264U - Supporting structure for outdoor shed - Google Patents

Abstract

The utility model discloses a supporting structure for an outdoor shed, which comprises a bracket and tiles, wherein the bracket comprises a quadrilateral frame body formed by four supporting beams and four upright posts supported below the frame body, a water collecting tank is arranged on the inward surface of each supporting beam, a diversion channel which is in butt joint with the water collecting tank and guides water in the water collecting tank to the lower part of the upright post is arranged on the upright post, a plurality of tiles are uniformly paved in the frame body, the front end and the rear end of each tile are rotationally connected to the supporting beam, the top of one side of each tile is provided with a downward protruding side baffle, the other side of each tile is provided with a U-shaped bending part, the side baffle on one tile is positioned above the bending part of the adjacent tile, and the side baffle and the bending part extend to the two ends of each tile and are positioned above the water collecting tank. The utility model can prevent rainwater from splashing when falling from the top of the tile.

Description

Supporting structure for outdoor shed

Technical Field

The utility model relates to the technical field of outdoor sheds, in particular to a supporting structure for an outdoor shed.

Background

The rain-proof and sun-shading shed arranged at the upper part of the building entrance and exit is called as an outdoor shed. The outdoor canopy of building entrance and top layer balcony upper portion can shelter from the rainwater and protect outer door to avoid the rainwater erosion, in addition, when open-air tourism vacation, can temporarily build outdoor canopy, can also be applied to the keep out the wind of vehicle and hide rain and snow protection, hail and sun-proof, leaf prevention fall on the vehicle.

The traditional outdoor shed is generally assembled by a bracket and shed cloth, and then canvas, glass fiber reinforced plastic tiles, stainless steel encaustic tiles and the like are fixed on the bracket. The shed has the advantages that the production cost is low, the shed is single in function, the effect of shielding rain can only be achieved, the common use requirement of people in life cannot be met, meanwhile, some outdoor sheds in the market at present are provided with rain collecting structures, the outdoor sheds are all arranged in a free water falling mode that the front edge opening is arranged at the rear edge opening, rainwater is scattered to the ground through the outdoor shed, and the rainwater which falls down in a concentrated mode on the edge opening outside the shed is inconvenient for life and work of people due to water concentration.

Disclosure of Invention

The utility model aims to solve the defects of the technology and designs an outdoor shed supporting structure.

The utility model designs an outdoor shed supporting structure which comprises a bracket and tiles, wherein the bracket comprises a quadrilateral frame body formed by four supporting beams and four upright posts supported below the frame body, a water collecting tank is arranged on the inward surface of each supporting beam, a diversion channel which is in butt joint with the water collecting tank and guides water in the water collecting tank to the lower part of the upright post is arranged on the upright post, a plurality of tiles are uniformly paved in the frame body, the front end and the rear end of each tile are rotationally connected to the supporting beam, the top of one side of each tile is provided with a downward protruding side baffle, the other side of each tile is provided with a U-shaped bending part, the side baffle on one tile is positioned above the bending part of the adjacent tile, and the side baffle and the bending part extend to the two ends of each tile and are positioned above the water collecting tank.

The utility model has the technical effects that the water collecting grooves are arranged on the supporting beams around, the guide channels communicated with the water collecting grooves are arranged on the upright posts along the height direction, the side baffle plates and the bending parts are respectively arranged on two sides of each tile, and between the adjacent tiles, the side baffle plates on one tile extend to the upper part of the bending part of the other tile, so that rainwater at the top of the tile falls into the bending part along the side baffle plates, the bending parts extend to the front end and the rear end of the tile and are positioned above the water collecting grooves, the rainwater collected in the bending parts falls into the water collecting grooves, and then flows out through the guide channels, and the rainwater can be prevented from splashing when falling from the top of the tile.

Further preferably, the upright post is internally provided with a cavity, the upright post is provided with a butt joint port which is mutually inserted with the cavity and is used for butt joint of two adjacent support beam ports, the port of one support beam is propped against the side surface of the port of the other support beam after butt joint, the two support beam ports are internally provided with a first connecting block and a second connecting block respectively, the side surfaces of the first connecting block and the second connecting block, which face the respective support beam, are respectively provided with a threaded through hole, each support beam is provided with a connecting hole at the threaded through hole, and the inner wall of the cavity of the upright post is correspondingly provided with a threaded blind hole which is coaxial with the respective threaded through hole.

Preferably, the inner wall of the cavity of the upright post is provided with a groove body along the height direction to serve as a diversion channel, the top end of the diversion channel is positioned at the butt joint position, and when the supporting beam is inserted into the butt joint position, the port at one end of the water collecting tank is in butt joint with the port at the top end of the diversion channel.

Preferably, the plurality of threaded through holes are uniformly distributed on the first connecting block and the second connecting block.

Preferably, the inner wall of the cavity is provided with a mounting groove at the position of the threaded blind hole, a pre-tightening block matched with the mounting groove is arranged in the mounting groove, and the threaded blind hole is positioned on the pre-tightening block.

Preferably, the mounting grooves are distributed along the height direction of the upright post, the openings of the mounting grooves face upwards, and the pre-tightening blocks are inserted into the mounting grooves from the openings.

Preferably, the first connecting block and the second connecting block are hollow section structures, the threaded through holes are formed in the first connecting block and the second connecting block in a screw hole column type mode, and reinforcing ribs are distributed on the surfaces of the first connecting block and the second connecting block in a staggered mode.

Preferably, semicircular protrusions are arranged at the positions, facing the ports of the support beams, of the first connecting block and the second connecting block, and semicircular positioning grooves matched with the semicircular protrusions are formed in the end faces of the support beams.

Preferably, the water collection tank is close to the bottom of the support beam and is integrally designed with the bottom surface of the support beam.

Further preferably, the top surface of the tile is designed to be inclined downwards from the middle to the two sides.

Drawings

FIG. 1 is a general block diagram of the present utility model;

FIG. 2 is an exploded view of the support beam and column of the present utility model;

FIG. 3 is an exploded view of the support beam, the upright and the first and second connection blocks of the present utility model;

FIG. 4 is an exploded view of the support beam and tile of the present utility model;

FIG. 5 is a block diagram of the ends of a tile in accordance with the present utility model.

In the figure: 200. a support beam; 201. a column; 202. a water collection tank; 203. a diversion channel; 204. edge baffle plates; 205. a bending part; 206. a cavity; 207. an interface; 208. a first connection block; 209. a second connection block; 210. a threaded through hole; 211. a threaded blind hole; 212. a mounting groove; 213. a pre-tightening block; 214. reinforcing ribs; 215. a semicircular protrusion; 216. a semicircular positioning groove; 217. tiles.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which are derived by a person skilled in the art based on the embodiments of the utility model, fall within the scope of protection of the utility model.

In this embodiment, as shown in fig. 1 to 5, the support comprises a support and tiles 217, the support comprises a quadrangular frame body surrounded by four support beams 200 and four upright posts 201 supported under the frame body, the upright posts 201 are positioned at four corners of the frame body, the inward faces of each support beam 200 are provided with water collecting grooves 202, the water collecting grooves 202 are distributed along the length direction of the support beam 200, each upright post 201 is provided with a diversion channel 203, the diversion channels 203 are distributed along the height direction of the upright posts 201, and the top ends of the diversion channels 203 are butted with the water collecting grooves 202, so that water in the water collecting grooves 202 flows into the diversion channels 203 and finally flows out from the tail ends of the upright posts 201, and rainwater is prevented from directly falling from two ends of the tiles 217 to cause splashing.

A plurality of tiles 217 are uniformly paved in a frame body, adjacent tiles 217 are mutually close and are arranged in parallel, the front end and the rear end of each tile 217 are rotationally connected to the corresponding supporting beam 200, the top of one side of the left side and the right side of each tile 217 is provided with a downward protruding edge baffle 204, the edge baffle 204 forms an eave structure, the bottom of the other side of each tile 217 is provided with a U-shaped bending part 205, the edge baffle 204 on one tile 217 is positioned above the bending part 205 of the adjacent tile 217, so that rainwater at the top of each tile 217 can flow down along the two sides of the top, flow into the bending part 205 of the adjacent tile from one side, flow into the bending part 205 from the other side, flow into the water collecting tank 202 from the bending part 205, flow into a guide channel through the water collecting tank 202, and flow out along the upright 201.

The upright 201 and the supporting beams 200 can be made of profiles, the upright 201 is internally provided with a cavity 206, the top of the upright 201 is provided with a butt joint 207 communicated with the cavity 206, in this embodiment, the butt joint 207 is opened on the surface of the top of the upright 201 which is inwards adjacent, so that the ports of two adjacent supporting beams 200 can be inserted into the butt joint 207 to form connection, wherein the port of one supporting beam 200 is inserted to the bottom, that is, the port of the other supporting beam 200 is abutted to the inner wall corresponding to one side of the upright 201, after the port of the other supporting beam 200 is inserted, the port of the other supporting beam 200 is abutted to the side of the previous supporting beam 200 to form flush butt joint, the ports of the two supporting beams 200 are internally provided with a first connecting block 208 and a second connecting block 209 respectively, the side of the first connecting block 208 and the second connecting block 209 facing the respective supporting beam 200 are respectively provided with a threaded blind hole 211, the inner wall of the upright 201 is correspondingly provided with a threaded blind hole 211 coaxial with the respective threaded blind hole 210, one end of the threaded blind hole 210 faces the inner wall of the upright 201, one end of the threaded blind hole 211 faces the inner wall of the upright 201, that is provided with the threaded blind hole 211, and the other end of the threaded blind hole 210 faces the threaded blind hole 211 faces the inner wall of the upright 201, so that the two adjacent supporting beams 200 can be fixedly connected with the threaded blind holes 200.

In this embodiment, the inner wall of the cavity 206 of the upright 201 extends along the height direction to form a channel body, the channel body is used as the diversion channel 203, the top end of the channel body extends to the butt joint 207, and when the supporting beam 200 is inserted into the butt joint 207, the port of the top end of the channel body is located under the port of one end of the water collecting tank 202 to form butt joint, so that the butt joint of the water collecting tank 202 and the diversion channel 203 is realized.

In another embodiment, the number of the threaded through holes 210 may be plural, in this embodiment, the number of the threaded through holes 210 on the first connecting block 208 is four, and the threaded through holes are distributed at four corners of the first connecting block 208; the number of the threaded through holes 210 on the second connecting block 209 is two, and the threaded through holes are distributed vertically symmetrically.

In another embodiment, the inner wall of the cavity 206 is provided with a mounting groove 212 at the threaded blind hole 211, in this embodiment, the mounting groove 212 is similar to a groove body in structure, and extends out from the inner wall of the cavity 206 along the height direction, the top and two ends of the mounting groove 212 are both open, a pre-tightening block 213 adapted to the mounting groove 212 is provided in the mounting groove 212, the threaded blind hole 211 is located on the pre-tightening block 213, a bolt is inserted into the threaded blind hole 211 to form a fixation after passing out from the threaded through hole 210, and the pre-tightening block 213 can flexibly align the threaded through hole 210.

In addition, the pre-tightening block 213 is mounted or dismounted from one end opening of the mounting groove 212, so that the pre-tightening block 213 can be mounted detachably.

In another embodiment, the first connecting block 208 and the second connecting block 209 are hollow section structures, i.e. hollow structures, the threaded through holes 210 are disposed on the first connecting block 208 and the second connecting block 209 in a form of screw hole columns, and reinforcing ribs 214 are distributed on the surfaces of the first connecting block 208 and the second connecting block 209 in a staggered manner, so that the first connecting block 208 and the second connecting block 209 are light in weight, but have larger strength.

In another embodiment, the first connection block 208 and the second connection block 209 extend out of the semicircular protrusion 215 towards the port of the support beam 200, the end surface of the support beam 200 is provided with a semicircular positioning groove 216 adapted to the semicircular protrusion 215, and when the support beam 200 is inserted into the docking port 207, the semicircular protrusion 215 is embedded into the semicircular positioning groove 216 to form positioning, so as to prevent relative sliding between the first connection block 208 and the second connection block 209 and the support beam 200.

In another embodiment, the water collection tank 202 is located near the bottom of the support beam 200 and is integrally formed with the bottom surface of the support beam 200 to prevent the water collection tank 202 from falling off.

In another embodiment, the top surface of the tile 217 is inclined downward from the middle to the two sides, so that the rainwater on the top of the tile 217 can smoothly flow into the bent portions 205 on the two sides.

In another embodiment, the support beam 200, the upright 201 and the tile 217 are all shaped, and are light in weight and high in strength.

The present utility model is not limited to the above-mentioned preferred embodiments, and any person who can obtain other various products under the teaching of the present utility model can make any changes in shape or structure, and all the technical solutions that are the same or similar to the present utility model fall within the scope of the present utility model.

Claims (10)

1. The supporting structure for the outdoor shed is characterized by comprising a bracket and tiles (217), wherein the bracket comprises a quadrilateral frame body formed by four supporting beams (200) and four upright posts (201) supported under the frame body, a water collecting tank (202) is arranged on the inward facing surface of each supporting beam (200), a diversion channel (203) which is in butt joint with the water collecting tank (202) and guides water in the water collecting tank (202) to the lower part of the upright post (201) is arranged on the upright post (201),

a plurality of tiles (217) are evenly laid in the framework, the front and back ends of the tiles (217) are rotationally connected to the supporting beam (200), one side top of each tile (217) is provided with a downward protruding side baffle (204), the other side of each tile (217) is provided with a U-shaped bending part (205), the side baffle (204) on one tile (217) is located above the bending part (205) of the adjacent tile (217), and the side baffle (204) and the bending part (205) are all extended to two ends of each tile (217) and are located above the water collecting tank (202).

2. The outdoor shed supporting structure according to claim 1, wherein the upright (201) is internally provided with a cavity (206), the upright (201) is provided with a butt joint (207) which is communicated with the cavity (206) and is used for butt joint of ports of two adjacent supporting beams (200), the ports of one supporting beam (200) are propped against the port side surface of the other supporting beam (200) after butt joint, the ports of the two supporting beams (200) are internally provided with a first connecting block (208) and a second connecting block (209) respectively, the positions of the first connecting block (208) and the second connecting block (209) facing the side surfaces of the respective supporting beams (200) are respectively provided with a threaded through hole (210), each supporting beam (200) is provided with a connecting hole at the threaded through hole (210), and the inner wall of the cavity (206) of the upright (201) is correspondingly provided with a threaded blind hole (211) coaxial with the respective threaded through hole (210).

3. The outdoor shed supporting structure according to claim 1 or 2, wherein the inner wall of the cavity (206) of the upright (201) is provided with a groove body along the height direction as a diversion channel (203), the top end of the diversion channel (203) is positioned at the opposite joint (207), and when the supporting beam (200) is inserted into the opposite joint (207), one end port of the water collecting tank (202) and the top end port of the diversion channel (203) form an opposite joint.

4. The outdoor shelter support structure of claim 2, characterized in that the plurality of threaded through holes (210) are evenly distributed on the first connection block (208) and the second connection block (209).

5. The outdoor shed support structure according to claim 2, wherein the inner walls of the cavities (206) are provided with mounting grooves (212) at the threaded blind holes (211), pre-tightening blocks (213) matched with the mounting grooves (212) are arranged in the mounting grooves (212), and the threaded blind holes (211) are located on the pre-tightening blocks (213).

6. The outdoor shed support structure according to claim 5, wherein the mounting grooves (212) are distributed in the height direction of the upright (201), the openings of the mounting grooves (212) are upward, and the pre-tightening blocks (213) are inserted into the mounting grooves (212) from the openings.

7. The outdoor shed supporting structure according to claim 2, wherein the first connecting block (208) and the second connecting block (209) are hollow section structures, the threaded through holes (210) are arranged on the first connecting block (208) and the second connecting block (209) in a screw hole column shape, and reinforcing ribs (214) are distributed on the surfaces of the first connecting block (208) and the second connecting block (209) in a staggered manner.

8. The outdoor shed supporting structure according to claim 7, wherein semicircular protrusions (215) are arranged at the positions, facing the ports of the supporting beam (200), of the first connecting blocks (208) and the second connecting blocks (209), and semicircular positioning grooves (216) matched with the semicircular protrusions (215) are formed in the end faces of the supporting beam (200).

9. A support structure for an outdoor shelter according to claim 3, characterised in that the water collection trough (202) is arranged close to the bottom of the support beam (200) and is designed in one piece with the bottom of the support beam (200).

10. The outdoor shelter support structure of claim 1, wherein the top surface of the tiles (217) is of a centre-to-side downward sloping design.