CN215254117U - Waveform brick mosaic structure with stable structural strength - Google Patents

Abstract

The invention discloses a waveform brick splicing structure with stable structural strength, which comprises concave bricks and convex bricks, wherein bearing reinforcing steel bars are connected and arranged in the concave bricks and the convex bricks which are adjacent in the horizontal direction. This application helps improving the overall structure intensity of wave wall body.

Description

Waveform brick mosaic structure with stable structural strength

Technical Field

The invention relates to the field of shaped bricks, in particular to a corrugated brick splicing structure with stable structural strength.

Background

The shaped bricks are mainly used for decoration in rooms and cities, and have various shapes.

As figure 1, there is a wave wall body at present, including concave brick 1 and convex brick 2, the both sides of concave brick 1 concave surface all are formed with first vertical butt face 11, the other both sides of concave brick 1 concave surface all are formed with first horizontal butt face 12, the both sides of convex brick 2 convex surface all are formed with the vertical butt face 21 of second, the other both sides of convex brick convex surface all are formed with the horizontal butt face 22 of second, through the butt of first vertical butt face 11 and the vertical butt face 21 butt of second and first horizontal butt face 12 and the butt face 22 butt of second, and then make concave brick 1 and convex brick 2 along the crisscross concatenation of level and vertical direction, form wave wall body, handsome in appearance.

The concave bricks and the convex bricks are spliced and fixed in an adhesive mode to form a wavy wall, and the concave bricks have concave surfaces, so that the structural strength of the concave surfaces is low, and the concave bricks are distributed in the middle of the wavy wall in a staggered mode, so that the structural strength of the whole wavy wall is low, and an improvement part is provided.

Disclosure of Invention

In order to improve the structural strength of wave wall body, this application provides a wave form brick mosaic structure that structural strength is stable.

The application provides a stable wave form brick mosaic structure of structural strength adopts following technical scheme:

the utility model provides a wave form brick mosaic structure that structural strength is stable, includes concave brick and convex brick, adjacent on the horizontal direction all connect in concave brick and the convex brick and be provided with the bearing reinforcing bar.

By adopting the technical scheme, the concave bricks and the convex bricks are spliced together through the heavy steel bars to form the wavy wall, and the bearing steel bars are utilized to contribute to enhancing the bearing capacity of the concave bricks and the convex bricks, so that the overall structural strength of the wavy wall is improved.

Preferably, two first inserting holes are symmetrically formed in the first vertical abutting surfaces of the concave bricks, two second inserting holes are symmetrically formed in the second vertical abutting surfaces of the convex bricks, any one first inserting hole in each concave brick is communicated with the second inserting holes in the two adjacent convex bricks in an aligned mode, and two ends of any one bearing steel bar are inserted into one first inserting hole and the second inserting hole communicated with the first inserting hole respectively.

Through adopting above-mentioned technical scheme, utilize bearing reinforcing bar to peg graft with first spliced eye and second spliced eye, realize that concave brick and convex brick splice each other.

Preferably, the length of the bearing steel bar is equal to the sum of the lengths of the first splicing hole and the second splicing hole.

Through adopting above-mentioned technical scheme, the length of bearing reinforcing bar equals with the length sum of first spliced eye and second spliced eye, helps making concave brick and convex brick laminating more when piecing together, helps making the wave wall body more pleasing to the eye.

Preferably, first connecting holes are formed in the first horizontal abutting face of the concave brick, second connecting holes are formed in the second horizontal abutting face of the convex brick, connecting ribs are arranged between the concave brick and the convex brick, and two ends of each connecting rib are respectively matched with the first connecting holes and the second connecting holes in an inserting mode.

By adopting the technical scheme, the upper concave brick and the lower concave brick which are adjacent to each other are connected by the connecting ribs, and the bearing reinforcing steel bars are matched to splice the wavy wall body, so that the structural strength of the wavy wall body is further improved.

Preferably, any one of the first connecting holes is communicated with the bottom of the first inserting hole on one side, an inserting groove is formed in the end part, located in the first inserting hole, of the bearing steel bar, and the connecting rib is in inserting interference fit with the bearing steel bar.

Through adopting above-mentioned technical scheme, utilize splice bar and bearing reinforcing bar to peg graft, then the staff makes it form interference fit with the bearing reinforcing bar through strikeing the splice bar, helps further improving the structural strength of wave wall body.

Preferably, the bearing reinforcing steel bar is provided with a first marking line, and the length of the first marking line is parallel to the length direction of the bearing reinforcing steel bar.

Through adopting above-mentioned technical scheme, utilize the position relation of first mark line and first spliced eye, when rotating the bearing reinforcing bar, utilize the position of first mark line, can make the drill way of first spliced eye towards first connecting hole, the splice bar of being convenient for is pegged graft with the bearing reinforcing bar and is cooperated.

Preferably, the insertion groove is a circular groove.

By adopting the technical scheme, the circular grooves and the end parts of the connecting ribs are more adaptive, so that the connecting ribs and the plug-in connection are more convenient and faster.

Preferably, the connecting rib is provided with a second marking line, and the distance from the second marking line to the connecting rib plugging end, the length of the first connecting hole and the length of the second connecting hole are equal.

Through adopting above-mentioned technical scheme, when the splice bar was pegged graft in advance with heavy reinforcing bar and is joined in marriage, utilize the mark line to help playing the effect of contrast, help making the staff can be according to the position of mark line when knocking the splice bar, the grafting degree of depth of control splice bar and inserting groove helps preventing that the grafting degree of depth is too deep, leads to concave brick and convex brick to damage.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the bearing reinforcing steel bars are utilized to splice and splice the concave bricks and the convex bricks in a staggered manner, so that the bearing capacity of the concave bricks and the convex bricks is improved, and the structural strength of the wavy wall is improved;

2. the concave bricks and the convex bricks are spliced by matching the connecting ribs with the bearing reinforcing steel bars, so that the structural strength of the wavy wall is further improved;

3. through the splicing of the connecting ribs and the bearing reinforcing steel bars and the interference fit, the connecting ribs are connected with the bearing reinforcing steel bars, and further the structural strength of the wave-shaped wall body is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of a corrugated wall in the present application;

FIG. 2 is an exploded view of the first embodiment of the present application;

FIG. 3 is an exploded schematic view of a second embodiment of the present application, which mainly shows the structures of concave bricks and convex bricks;

fig. 4 is a schematic structural view of a second part of the embodiment of the present application, which mainly shows the structures of the load-bearing reinforcing steel bars and the connecting bars.

Reference numerals: 1. concave bricks; 11. a first plug hole; 12. a first connection hole; 2. a convex brick; 21. a second plug hole; 22. a second connection hole; 3. a load-bearing reinforcing bar; 31. inserting grooves; 32. a first marking line; 4. connecting ribs; 41. a plug-in part; 42. a second marking line.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses wave form brick mosaic structure that structural strength is stable.

EXAMPLE 1

Referring to fig. 2, a wave form brick mosaic structure that structural strength is stable includes about from top to bottom crisscross concave brick 1 and convex brick 2 that sets up, concave brick 1's first vertical butt face runs through along its length direction symmetry and has seted up two first spliced eyes 11, the length direction of arbitrary first spliced eye 11 all is perpendicular with first vertical butt face, convex brick 2's the vertical butt face of second runs through along its length direction symmetry and has seted up two second spliced eyes 21 that correspond intercommunication and length direction is parallel with two first spliced eyes 11, be provided with bearing reinforcing bar 3 between concave brick 1 and the convex brick 2, bearing reinforcing bar 3 passes first spliced eye 11 and second spliced eye 21 in proper order, along the crisscross concatenation of horizontal direction with concave brick 1 and convex brick 2 together.

Referring to fig. 2, first connecting hole 12 has all been seted up on two first horizontal butt faces of concave brick 1, two first connecting holes 12 do not link up, second connecting hole 22 has all been seted up on two second horizontal butt faces of convex brick 2, two second connecting holes 22 do not link up, first connecting hole 12 on arbitrary concave brick 1 communicates with the second connecting hole 22 of two adjacent convex bricks 2 in the vertical direction in alignment, equal vertical splice bar 4 that is provided with between the first horizontal butt face of arbitrary concave brick 1 and the second horizontal butt face of the convex brick 2 that corresponds, the cooperation of pegging graft of the other end and the second connecting hole 22 of the cooperation of pegging graft of the one end and the first connecting hole 12 of arbitrary splice bar 4.

The implementation principle of the first embodiment of the application is as follows: in the actual concatenation process, utilize bearing reinforcing bar 3 to splice concave brick 1 and convex brick 2 together along the horizontal direction, then utilize splice bar 4 to splice concave brick 1 and convex brick 2 crisscross together along vertical direction, form the wave wall body, utilize bearing reinforcing bar 3 and splice bar 4 to connect concave brick 1 and convex brick 2, help improving the joint strength of concave brick 1 and convex brick 2, and then improve the bearing capacity of concave brick 1 and convex brick 2, help improving the structural strength of wave wall body promptly.

Example 2

Referring to fig. 3, the embodiment of the present application differs from the first embodiment in that: two first spliced eye 11 on the arbitrary first vertical butt face of concave brick 1 do not all are to run through and set up, form four first spliced eye 11 on concave brick 1 promptly, two second spliced eye 21 on the arbitrary second vertical butt face of convex brick 2 do not all are to run through and set up, form four second spliced eye 21 promptly, first spliced eye 11 on arbitrary concave brick 1 communicates with the second spliced eye 21 on two adjacent convex bricks 2 respectively in alignment, the one end of arbitrary bearing reinforcing bar 3 is pegged graft with first spliced eye 11 and bearing reinforcing bar 3's the other end is pegged graft with second spliced eye 21, bearing reinforcing bar 3's length is the same with the sum of the length of first spliced eye 11 and second spliced eye 21.

Referring to fig. 3 and 4, two first connection holes 12 on two first horizontal abutting surfaces of the concave brick 1 are respectively communicated with two first insertion holes 11 on one first vertical abutting surface, and two first insertion holes 11 on the other first vertical surface of the concave brick 1 are respectively communicated with two second insertion holes 21 of the adjacent convex brick 2 in an aligned manner; two second connecting holes 22 on two second horizontal abutting surfaces of the convex brick 2 are respectively communicated with two second inserting holes 21 of one second vertical abutting surface; bearing steel bar 3 is located first spliced eye 11 and has all seted up inserting groove 31 with the tip that is located second spliced eye 21, inserting groove 31 sets up to the circular slot, the lower extreme of splice bar 4 is provided with grafting portion 41, the grafting portion 41 of splice bar 4 is pegged graft with inserting groove 31 and is formed interference fit, bearing steel bar 3 keeps away from the one end of inserting groove 31 and is carved with first mark line 32, the length direction of first mark line 32 is parallel with bearing steel bar 3's length direction, and first mark line 32 is located the notch side of inserting groove 31, second mark line 42 has been carved on the splice bar 4, the distance of second mark line 42 to splice bar 4 grafting end, the length of first connecting hole 12 and the length homogeneous phase of second connecting hole 22 equal.

In the actual connection process, after the bearing steel bar 3 is inserted, the bearing steel bar 3 is rotated to enable the first marking line 32 to be positioned at the upper side, so that the notch of the insertion groove 31 is upward and communicated with the first connection hole 12 or the second connection hole 22, and the insertion part 41 of the connection steel bar 4 is conveniently aligned and inserted with the insertion groove 31; when splice bar 4 and bearing reinforcing bar 3 peg graft in advance, the staff strikes splice bar 4 and makes it peg graft and interference fit with bearing reinforcing bar 3, utilize second mark line 42, help the staff to control the degree of depth of striking to splice bar 4, and then help preventing to strike the in-process and cause concave brick 1 and convex brick 2 to damage, through being connected splice bar 4 and bearing reinforcing bar 3, improve the joint strength of concave brick 1 convex brick 2, and then help improving the joint strength of wave wall body.

The implementation principle of the embodiment of the application is as follows: utilize splice bar 4 and bearing reinforcement 3 to splice concave brick 1 and convex brick 2 along vertical and horizontal direction, help improving concave brick 1 and convex brick 2's bearing capacity, and then help improving the structural strength of wave wall body, rethread bearing reinforcement 3 and 4 grafting interference fit of splice bar are connected, further help improving the structural strength of wave wall body.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a stable wave form brick mosaic structure of structural strength which characterized in that: the concrete brick comprises a concave brick (1) and a convex brick (2), wherein the concave brick (1) and the convex brick (2) are adjacent to each other in the horizontal direction, and bearing steel bars (3) are connected and arranged in the concave brick (1) and the convex brick (2).

2. The tile splicing structure of claim 1, wherein the tile splicing structure comprises: two first plug holes (11) are symmetrically formed in a first vertical abutting surface of the concave brick (1), two second plug holes (21) are symmetrically formed in a second vertical abutting surface of the convex brick (2), any first plug hole (11) in the concave brick (1) is communicated with the second plug holes (21) in the two adjacent convex bricks (2) in an aligned mode, and the two ends of any bearing steel bar (3) are respectively plugged in one first plug hole (11) and the second plug hole (21) communicated with the first plug hole.

3. The tile splicing structure of claim 2, wherein the tile splicing structure has stable structural strength, and comprises: the length of the bearing steel bar (3) is equal to the sum of the lengths of the first inserting hole (11) and the second inserting hole (21).

4. A structurally stable corrugated tile splicing structure as set forth in claim 3, wherein: first connecting hole (12) have all been seted up on the first horizontal butt face of concave brick (1), second connecting hole (22) have all been seted up to the second horizontal butt face of convex brick (2), be provided with between concave brick (1) and convex brick (2) splice bar (4), the both ends of splice bar (4) are pegged graft the cooperation with first connecting hole (12) and second connecting hole (22) respectively.

5. The tile splicing structure of claim 4, wherein the tile splicing structure comprises: any one of the first connecting holes (12) is communicated with the bottom of the first inserting hole (11) on one side of the first connecting hole, an inserting groove (31) is formed in the end portion, located in the first inserting hole (11), of the bearing steel bar (3), and the connecting rib (4) is in inserting interference fit with the bearing steel bar (3).

6. The tile splicing structure of claim 5, wherein the tile splicing structure comprises: the bearing steel bar (3) is provided with a first marking line (32), and the length of the first marking line (32) is parallel to the length direction of the bearing steel bar (3).

7. The tile splicing structure of claim 5, wherein the tile splicing structure comprises: the insertion groove (31) is a circular groove.

8. The tile splicing structure of claim 5, wherein the tile splicing structure comprises: the connecting rib (4) is provided with a second marking line (42), and the distance from the second marking line (42) to the inserting end of the connecting rib (4), the length of the first connecting hole (12) and the length of the second connecting hole (22) are equal.

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