CN219671813U - Concrete inclined roof steel structure - Google Patents

Abstract

The utility model discloses a concrete inclined roof steel structure, which relates to the technical field of concrete inclined roof steel structures and comprises a first connecting column, wherein one side of the first connecting column is connected with a first supporting column in a sliding manner, one end of the first supporting column is fixedly connected with a second connecting column, one end of the first supporting column is provided with a first square groove, one side of the first square groove is connected with a connecting plate in a sliding manner, one side of the connecting plate is connected with a fixing bolt in a sliding manner, and one end of the fixing bolt is connected with a fixing nut in a threaded manner. According to the utility model, the first support column and the second support column are arranged, so that the steel structure forms a triangular structure to keep stability, the first connecting column, the second connecting column and the third connecting column are arranged, all the triangular steel structures are connected together, all the steel structures are fixed by the fixing bolts and the fixing nuts, and the used connecting objects are basically smaller and are close to the wall, so that the occupied space is reduced.

Description

Concrete inclined roof steel structure

Technical Field

The utility model relates to the technical field of concrete inclined roof steel structures, in particular to a concrete inclined roof steel structure.

Background

The steel house is made of H-shaped steel and thin-wall cold-formed C, Z-shaped steel, and the roof and the wall are made of color-coated profiled steel plates or sandwich color steel plates, so that the steel house has basically replaced the traditional reinforced concrete construction in developed countries. The method has the advantages of light total amount, large span, less material consumption, low manufacturing cost, foundation saving, short construction period, safety, reliability, attractive appearance and the like. The method is widely applied to buildings such as single-layer industrial plants, warehouses, commercial buildings, office buildings, multi-layer parking lots, residences and the like.

In the steel structure of the roof of the building disclosed in the Chinese patent application publication No. CN216949016U, although the installation structure is arranged, the cornice is convenient to assemble during installation, the operation efficiency is high, but the support connector occupies a large indoor space, the roof is easy to damage due to vibration, and the roof is easy to damage due to vibration.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a concrete sloping roof steel structure, which solves the problems in the prior art.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: the device comprises a first connecting column, wherein one side of the first connecting column is connected with a first supporting column in a sliding manner, and one end of the first supporting column is fixedly connected with a second connecting column;

the first square groove is formed in one end of the first support column, the connecting plate is connected to one side of the first square groove in a sliding mode, the fixing bolt is connected to one side of the connecting plate in a sliding mode, the fixing nut is connected to one end of the fixing bolt in a threaded mode, the third square groove is formed in the second connecting column, the second clamping block is connected to one side of the third square groove in a sliding mode, the fixing bolt is connected to one side of the second clamping block in a sliding mode, the second support column is connected to one side of the second clamping block in a sliding mode, the fourth square groove is formed in the second support column in the second supporting column in a sliding mode, the fourth clamping block is connected to one side of the fourth square groove in a sliding mode, the third support column is connected to the upper end of the fourth clamping block in a sliding mode, the first connecting column is connected to the upper end of the third support column in a sliding mode, the second square groove is formed in one side of the first support column in a sliding mode, the first clamping block is connected to one side of the second square groove in a sliding mode, and the third connecting column is connected to one side of the first clamping block in a sliding mode;

the utility model discloses a flexible buffer board, including first support column, second support column, first support column, buffer board's lower extreme fixedly connected with telescopic link, first support column's one side is offered by the circular slot, one side sliding connection of circular slot has the telescopic link.

Optionally, the length and width of the movable plate are smaller than the length and width of the first support column, the height of the movable plate is smaller than the depth of the third chute, the width of the movable plate is consistent with the width of the third chute, and the length of the movable plate plus two limiting blocks is consistent with the length of the third chute.

Optionally, the length and the width of buffer board are unanimous with the length and the width of first spout, there is the clearance between buffer board and the fly leaf, the third spout save add the degree of depth of circle groove be less than the height of first support column, the diameter of telescopic link lower extreme closely agrees with the diameter of circle groove.

Optionally, the length, width and height of the first square groove closely agree with the length, width and height of the connecting plate, the fixing bolt penetrates through the first connecting column and the first supporting column, the length of the fixing bolt is larger than the length of the first connecting column, and the diameter of the fixing bolt is smaller than the height of the connecting plate.

Optionally, the length of the fixing bolt is greater than that of the second connecting column, the length of the second connecting column is consistent with that of the first connecting column, the height of the third square groove is less than that of the second connecting column, and the length, the width and the height of the third square groove are closely matched with those of the second clamping block.

Optionally, the length of the third support column is greater than the distance from the second support column to the first connection column, the height of the fourth square groove is less than the height of the second support column, the length, the width and the height of the fourth clamping block are closely matched with the length, the width and the height of the fourth square groove, and the width of the fourth clamping block is less than the width of the third support column.

Advantageous effects

The utility model provides a concrete pitched roof steel structure, which has the following beneficial effects:

this oblique roofing steel construction of concrete, through setting up first support column, second support column, make the steel construction form triangle structure and keep stability, be provided with first spliced pole, second spliced pole, third spliced pole again, make all triangle steel construction link together, make all steel construction fixed again with fixing bolt, fixation nut, the connector that uses is basically less and be close to the wall and reduced the space that occupies.

This oblique roofing steel construction of concrete through setting up third spout, fly leaf, makes the roof can carry out less removal, is provided with sponge board, extension spring again, when making the house take place to shake, can carry out the shock attenuation buffering for the first time, is provided with telescopic link, buffer board again, and when the unable thorough buffering of accomplishing of first shock attenuation carries out the shock attenuation buffering for the second time.

Drawings

FIG. 1 is a schematic view of the present utility model in elevation and cross section;

FIG. 2 is a schematic view of the left-hand cross-section of the present utility model;

FIG. 3 is a schematic top view of the present utility model;

fig. 4 is a schematic view of a three-dimensional structure of the present utility model.

In the figure: 1. a first connection post; 2. a first square groove; 3. a connecting plate; 4. a sponge plate; 5. a first clamping block; 6. a second square groove; 7. a movable plate; 8. a first support column; 9. a first chute; 10. a second chute; 11. a telescopic spring; 12. a limiting block; 13. a third chute; 14. a second connection post; 15. a third square groove; 16. a fixing bolt; 17. a second clamping block; 18. a second support column; 19. a fourth square groove; 20. a fourth clamping block; 21. a third support column; 22. a circular groove; 23. a telescopic rod; 24. a buffer plate; 25. a fixing nut; 26. and a third connecting column.

Description of the embodiments

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.

Examples

Referring to fig. 1 to 4, the present utility model provides a technical solution: a concrete sloping roof steel structure comprises a first connecting column 1, one side of the first connecting column 1 is slidingly connected with a first supporting column 8, one end of the first supporting column 8 is fixedly connected with a second connecting column 14, the length of the second connecting column 14 is consistent with that of the first connecting column 1, one end of the first supporting column 8 is provided with a first square groove 2, one side of the first square groove 2 is slidingly connected with a connecting plate 3, the length, width and height of the first square groove 2 are closely matched with those of the connecting plate 3, one side of the connecting plate 3 is slidingly connected with a fixing bolt 16, the fixing bolt 16 penetrates through the first connecting column 1 and the first supporting column 8, the length of the fixing bolt 16 is larger than that of the first connecting column 1, the diameter of the fixing bolt 16 is smaller than that of the connecting plate 3, the length of the fixing bolt 16 is larger than that of the second connecting column 14, one end of the fixing bolt 16 is in threaded connection with a fixing nut 25, the inside of the second connecting column 14 is provided with a third party groove 15, the height of the third party groove 15 is smaller than that of the second connecting column 14, one side of the third party groove 15 is slidably connected with a second clamping block 17, the length, the width and the height of the third party groove 15 are closely matched with those of the second clamping block 17, one side of the second clamping block 17 is slidably connected with a fixing bolt 16, one side of the second clamping block 17 is fixedly connected with a second supporting column 18, the inside of the second supporting column 18 is provided with a fourth party groove 19, the height of the fourth party groove 19 is smaller than that of the second supporting column 18, one side of the fourth party groove 19 is slidably connected with a fourth clamping block 20, the length, the width and the height of the fourth clamping block 20 are closely matched with those of the fourth party groove 19, the upper end of the fourth clamping block 20 is fixedly connected with a third supporting column 21, the width of the fourth clamping block 20 is smaller than that of the third supporting column 21, the length of the third supporting column 21 is larger than the distance from the second supporting column 18 to the first connecting column 1, the upper end of the third supporting column 21 is fixedly connected with the first connecting column 1, one side of the first supporting column 8 is provided with the second square groove 6, one side of the second square groove 6 is fixedly connected with the first clamping block 5, one side of the first clamping block 5 is slidably connected with the third connecting column 26, the first supporting column 8 and the second supporting column 18 are arranged to enable the steel structure to form a triangular structure to keep stable, the first connecting column 1, the second connecting column 14 and the third connecting column 26 are arranged to enable all the triangular steel structures to be connected together, all the steel structures are fixed through the fixing bolts 16 and the fixing nuts 25, and used connectors are basically smaller and are close to the wall to reduce occupied space.

During the use, insert the second fixture block 17 in the third party's groove 15, fix it with fixing bolt 16 and fixation nut 25, the second support column 18 is accomplished with second spliced pole 14 and is connected, insert fourth square groove 19 with fourth fixture block 20, the second spliced pole 14 is accomplished with third support column 21 and is connected, put into first square groove 2 with connecting plate 3, fix it through fixing bolt 16 and fixation nut 25, first spliced pole 1 is accomplished with first support column 8 and is connected, the purpose that occupation room space and stable in structure that the support connector is less has been reached.

Examples

Referring to fig. 1 to 4, the present utility model provides a technical solution: a concrete sloping roof steel structure comprises a first connecting column 1, one side of the first connecting column 1 is slidingly connected with a first supporting column 8, one end of the first supporting column 8 is fixedly connected with a second connecting column 14, one side of the first supporting column 8 is provided with a third sliding groove 13, one side of the third sliding groove 13 is slidingly connected with a limiting block 12, one side of the limiting block 12 is fixedly connected with a movable plate 7, the length and width of the movable plate 7 are smaller than those of the first supporting column 8, the height of the movable plate 7 is smaller than the depth of the third sliding groove 13, the width of the movable plate 7 is consistent with the width of the third sliding groove 13, the length of the movable plate 7 plus the length of the two limiting blocks 12 is consistent with the length of the third sliding groove 13, one end of the movable plate 7 is fixedly connected with a sponge plate 4, one side of the sponge plate 4 is provided with a second sliding groove 10, one side of the second sliding groove 10 is fixedly connected with a telescopic spring 11, a first chute 9 is arranged on one side of the sponge board 4, a buffer board 24 is slidingly connected on one side of the first chute 9, the length and width of the buffer board 24 are consistent with those of the first chute 9, a gap exists between the buffer board 24 and the movable board 7, the lower end of the buffer board 24 is fixedly connected with a telescopic rod 23, a round groove 22 is arranged on one side of the first supporting column 8, the depth of a rounding groove 22 of a province of the third chute 13 is smaller than the height of the first supporting column 8, a telescopic rod 23 is slidingly connected on one side of the round groove 22, the diameter of the lower end of the telescopic rod 23 is closely matched with the diameter of the round groove 22, the roof can move less by arranging the third chute 13 and the movable board 7, and the telescopic rod 23 and the buffer board 24 are arranged when the house vibrates and cannot be completely buffered, and performing secondary shock absorption buffering.

When the movable plate 7 is in use, when the house vibrates, the movable plate 7 moves downwards along the third sliding groove 13, the first shock absorption and buffering are carried out through the sponge plate 4 and the telescopic spring 11, when the vibration is large, the first shock absorption and buffering cannot be carried out thoroughly on the vibration, the movable plate 7 continuously descends and contacts with the buffer plate 24, the buffer plate 24 moves downwards, the telescopic rod 23 moves downwards along with the buffer plate, the movable plate moves in the circular groove 22, the second shock absorption and buffering are carried out, and the purpose of preventing a roof from being damaged when the vibration is buffered through a steel structure is achieved.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (6)

1. The utility model provides a concrete sloping roof steel structure, includes first spliced pole (1), its characterized in that: one side of the first connecting column (1) is connected with a first supporting column (8) in a sliding manner, and one end of the first supporting column (8) is fixedly connected with a second connecting column (14);

the novel concrete pile comprises a first support column (8), a connecting plate (3) and a second support column (6), wherein one end of the first support column (8) is provided with a first square groove (2), one side of the first square groove (2) is connected with the connecting plate (3) in a sliding manner, one side of the connecting plate (3) is connected with a fixing bolt (16) in a sliding manner, one end of the fixing bolt (16) is connected with a fixing nut (25) in a threaded manner, the inside of the second support column (14) is provided with a third square groove (15), one side of the third square groove (15) is connected with a second clamping block (17) in a sliding manner, one side of the second clamping block (17) is connected with a fixing bolt (16) in a sliding manner, one side of the second clamping block (17) is connected with a second supporting column (18) in a sliding manner, one side of the second supporting column (18) is provided with a fourth clamping block (20) in a sliding manner, the upper end of the fourth clamping block (20) is connected with a third supporting column (21) in a fixed manner, the upper end of the third supporting column (21) is connected with a first connecting column (1) in a fixed manner, one side of the first side of the third supporting column (8) is connected with a first side of the first clamping block (5) in a sliding manner, one side of the second supporting column (6) is connected with the first side of the first side (5);

the utility model provides a flexible buffer board structure for the solar cell module, including first support column (8), second spout (10) are seted up by third spout (13) in one side of first support column (8), one side sliding connection of third spout (13) has restriction piece (12), one side fixedly connected with fly leaf (7) of restriction piece (12), one end fixedly connected with sponge board (4) of fly leaf (7), second spout (10) have been seted up in one side of sponge board (4), one side fixedly connected with extension spring (11) of second spout (10), first spout (9) have been seted up in one side of sponge board (4), one side sliding connection of first spout (9) has buffer board (24), the lower extreme fixedly connected with telescopic link (23) of buffer board (24), one side of first support column (8) is seted up by circular slot (22), one side sliding connection of circular slot (22) has telescopic link (23).

2. A concrete pitched roof steel structure according to claim 1, wherein: the length and the width of the movable plate (7) are smaller than those of the first supporting column (8), the height of the movable plate (7) is smaller than the depth of the third sliding groove (13), the width of the movable plate (7) is consistent with that of the third sliding groove (13), and the length of the movable plate (7) plus two limiting blocks (12) is consistent with that of the third sliding groove (13).

3. A concrete pitched roof steel structure according to claim 1, wherein: the length and the width of the buffer plate (24) are consistent with those of the first sliding groove (9), a gap exists between the buffer plate (24) and the movable plate (7), the depth of the rounding groove (22) of the third sliding groove (13) is smaller than the height of the first supporting column (8), and the diameter of the lower end of the telescopic rod (23) is closely matched with that of the rounding groove (22).

4. A concrete pitched roof steel structure according to claim 1, wherein: the length, the width and the height of the first square groove (2) are closely matched with those of the connecting plate (3), the fixing bolt (16) penetrates through the first connecting column (1) and the first supporting column (8), the length of the fixing bolt (16) is larger than that of the first connecting column (1), and the diameter of the fixing bolt (16) is smaller than that of the connecting plate (3).

5. A concrete pitched roof steel structure according to claim 1, wherein: the length of the fixing bolt (16) is larger than that of the second connecting column (14), the length of the second connecting column (14) is consistent with that of the first connecting column (1), the height of the third square groove (15) is smaller than that of the second connecting column (14), and the length, the width and the height of the third square groove (15) are closely matched with those of the second clamping block (17).

6. A concrete pitched roof steel structure according to claim 1, wherein: the length of the third support column (21) is larger than the distance from the second support column (18) to the first connecting column (1), the height of the fourth square groove (19) is smaller than the height of the second support column (18), the length, the width and the height of the fourth clamping block (20) are closely matched with the length, the width and the height of the fourth square groove (19), and the width of the fourth clamping block (20) is smaller than the width of the third support column (21).