CN214580401U

CN214580401U - Triple nested multidirectional reinforcement grid

Info

Publication number: CN214580401U
Application number: CN202022724255.6U
Authority: CN
Inventors: 周伟
Original assignee: Hebei Shuangcheng New Material Technology Co ltd
Current assignee: Hebei Shuangcheng New Material Technology Co ltd
Priority date: 2020-11-23
Filing date: 2020-11-23
Publication date: 2021-11-02
Anticipated expiration: 2030-11-23

Abstract

The utility model relates to a grid is reinforceed to triple nested formula multidirectionally, including the grid main part, this grid main part integrated into one piece, the grid main part includes several square hole units that interconnect in proper order together, each square hole unit all include square hole, well square hole and interior square hole, square hole and interior square hole whole be the setting of returning the font, this well square hole is located between square hole and the interior square hole, and the slope sets up; the middle rib belt forming the middle square hole is connected with the middle part of the outer rib belt forming the outer square hole; the inner rib belt forming the inner square hole is connected to the middle part of the middle rib belt of the middle square hole. The utility model has the advantages that: the load can be transferred and dispersed to a plurality of directions, and the aim of integrally bearing the product is fulfilled to the maximum extent; the length of the outer rib belt is larger than that of the middle rib belt and that of the inner rib belt, and the outer rib belt is obviously and clearly connected through a naturally formed triangle in a tight and stable manner.

Description

Triple nested multidirectional reinforcement grid

Technical Field

The utility model relates to a three-fold nested multidirectional reinforcement grid relates to the grid field.

Background

The existing grating has too many or too large holes due to unreasonable arrangement of the ribs, and cannot provide enough bearing capacity, so that the stability performance is obviously lower in the longitudinal direction and the transverse direction and other directions, and the deformation and the failure are easy to occur.

Disclosure of Invention

For overcoming the defects of the prior art, the utility model provides a three-fold nested multidirectional reinforcement grid, the technical scheme of the utility model is:

the three-nested multidirectional reinforcement grid comprises a grid main body, wherein the grid main body is integrally formed, the grid main body comprises a plurality of square hole units which are sequentially connected with each other, each square hole unit comprises an outer square hole, a middle square hole and an inner square hole, the outer square hole and the inner square hole are integrally arranged in a shape like a Chinese character 'hui', and the middle square hole is positioned between the outer square hole and the inner square hole and is obliquely arranged; the middle rib belt forming the middle square hole is connected with the middle part of the outer rib belt forming the outer square hole; the inner rib belt forming the inner square hole is connected to the middle part of the middle rib belt of the middle square hole.

The square hole is formed by four outer rib belts and the middle square hole is formed by four middle rib belts; the inner square hole is formed by surrounding four inner rib belts.

Two oblique rib belts arranged in an X shape are arranged inside the outer square hole, and the intersection point of the two oblique rib belts is located at the center of the inner square hole to form a first node.

The middle parts of the oblique rib belts and the middle rib belts and the inner rib belts form a second node, and two inner rib belts, one middle rib belt and one oblique rib belt are crossed at the second node.

And a third node is formed between the outer rib belt and the adjacent middle rib belt, and one outer rib belt and four middle rib belts are crossed at the third node.

And a fourth node is formed between the adjacent outer rib belts and the inclined rib belts, and four outer rib belts and four inclined rib belts are crossed at the fourth node.

The diameter of the outer rib belt is larger than the diameters of the inner rib belt, the middle rib belt and the inclined rib belt.

The diameters of the inner rib belt, the middle rib belt and the inclined rib belt are equal.

The utility model has the advantages that: the load can be transferred and dispersed to a plurality of directions, and the aim of integrally bearing the product is fulfilled to the maximum extent; the length of the outer rib belt is larger than that of the middle rib belt and that of the inner rib belt, the layers are obviously and clearly connected through the naturally formed triangle, and the aim of multi-directional strengthening and consideration of the product is fulfilled. The whole structure is clear and beautiful, the layers are clear, and the identification degree is obvious.

Drawings

Fig. 1 is a schematic view of the main structure of the present invention.

Detailed Description

The invention will be further described with reference to specific embodiments, the advantages and features of the invention will become more apparent as the description proceeds. These examples are merely illustrative and do not limit the scope of the invention in any way. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention, and that such changes and modifications are intended to be included within the scope of the invention.

Referring to fig. 1, the utility model relates to a three-fold nested multidirectional reinforcement grid, including the grid main part, this grid main part integrated into one piece, the grid main part includes several square hole units that interconnect together in proper order, each square hole unit all include square hole in the outside, well square hole and interior square hole, square hole in the outside and interior square hole wholly be the setting of returning the font, this well square hole is located between square hole in the outside and interior square hole, and the slope sets up; the middle rib belt 8 forming the middle square hole is connected with the middle part of the outer rib belt 5 forming the outer square hole; the inner ribbon 6 forming the inner square hole is connected to the middle part of the middle ribbon 8 of the middle square hole.

The square hole is formed by four outer rib belts 5 in a surrounding manner, and the square hole is formed by four middle rib belts 8 in a surrounding manner; the inner square hole is formed by four inner rib belts 6 in an enclosing mode.

Two oblique rib belts 7 arranged in an X shape are arranged inside the outer square hole, and the intersection point of the two oblique rib belts 7 is located at the center of the inner square hole to form a first node 1.

The middle parts of the oblique rib belts 7 and the middle rib belts 8 and the inner rib belts 6 form a second node 2, and two inner rib belts, one middle rib belt and one oblique rib belt are crossed at the second node.

A third node 3 is formed between the outer rib belt 5 and the adjacent middle rib belt 8, and the outer rib belt 5 and the four middle rib belts 8 are crossed at the third node 3.

A fourth node 4 is formed between the adjacent outer rib belts and the inclined rib belts, and four outer rib belts 5 and four inclined rib belts 7 are crossed at the fourth node.

The diameter of the outer rib belt 5 is larger than the diameters of the inner rib belt 6, the middle rib belt 8 and the inclined rib belt 7.

The diameters of the inner rib belt 6, the middle rib belt 8 and the inclined rib belt 7 are equal.

The utility model discloses a theory of operation is: two oblique rib belts (arranged diagonally) arranged through the outer square hole and the inner square hole enable the inside of the whole outer square hole and the inner square hole and the middle square hole to form a triangle for division and connection, the stability characteristics of the triangle are utilized, the stability of nesting among a product structure and three holes is ensured, and the multi-direction deformation resistance of the product is improved. Meanwhile, compared with a square hole grid, the through inner rib belt, the through outer rib belt, the through middle rib belt and the through inclined rib belt are formed in the area with weak strength, and the arrangement of each rib belt provides powerful guarantee for improving the bearing strength in the directions.

Claims

1. The three-nested multidirectional reinforcement grid comprises a grid main body, wherein the grid main body is integrally formed and is characterized in that the grid main body comprises a plurality of square hole units which are sequentially connected with each other, each square hole unit comprises an outer square hole, a middle square hole and an inner square hole, the outer square hole and the inner square hole are integrally arranged in a shape like a Chinese character 'hui', and the middle square hole is positioned between the outer square hole and the inner square hole and is obliquely arranged; the middle rib belt forming the middle square hole is connected with the middle part of the outer rib belt forming the outer square hole; the inner rib belt forming the inner square hole is connected to the middle part of the middle rib belt of the middle square hole.

2. The triple-nested multidirectional reinforcement grid according to claim 1, wherein the outer square holes are surrounded by four outer ribs, and the middle square holes are surrounded by four middle ribs; the inner square hole is formed by surrounding four inner rib belts.

3. The triple-nested multidirectional reinforcement grid according to claim 1 or 2, wherein two diagonal rib strips arranged in an X shape are arranged inside the outer square hole, and the intersection point of the two diagonal rib strips is located at the center of the inner square hole to form a first node.

4. The triple-nested multidirectional reinforcement grid according to claim 3, wherein the diagonal ribs, the middle portion of the middle rib and the inner ribs form a second junction point, and two inner ribs, one middle rib and one diagonal rib intersect at the second junction point.

5. A triple nested multidirectional reinforcement grid according to claim 1 or 2, wherein said outer ribs and adjacent middle ribs form a third node, and one outer rib and four middle ribs intersect at said third node.

6. A triple-nested multidirectional reinforcement grid according to claim 1 or 2, wherein a fourth node is formed between adjacent outer and diagonal rib strips, and four outer rib strips and four diagonal rib strips intersect at the fourth node.

7. The triple nested multidirectional reinforcement grid according to claim 2, wherein the diameter of the outer tendons is greater than the diameter of the inner tendons, the middle tendons, and the diagonal tendons.

8. The triple-nested multidirectional reinforcement grid according to claim 7, wherein the inner rib strips, the middle rib strips and the diagonal rib strips are equal in diameter.