CN218176313U - Building block for hydraulic engineering - Google Patents

Abstract

The utility model discloses a building block that hydraulic engineering used, including building block, first slider, first recess, second slider and second recess, first slider setting is on the right side of building block, and first recess is seted up in the left side of building block, and the second slider setting is at the top of building block, and the bottom at the building block is seted up to the second recess. This building block that hydraulic engineering used, through the cooperation of first slider, first recess, second slider and second recess, when laying the building block, should be according to from the bottom up and from the right order of turning left. When laying the present building block, need aim at the first slider in this building block right side and the position of the first recess in left side of right side building block at first for first slider just can get into the inner chamber of first recess, thereby the fixing of building block about realizing, also need aim at the position of the second recess of this building block bottom and the second slider at bottom building block top simultaneously, make the second slider can get into the inner chamber of second recess and realize the cooperation, thereby the fixing of building block about realizing.

Description

Building block for hydraulic engineering

Technical Field

The utility model relates to a concrete block technical field specifically is a building block that hydraulic engineering used.

Background

The building blocks are artificial blocks made of concrete, industrial waste (slag, fly ash and the like) or local materials, have larger overall dimension than bricks, have the advantages of simple equipment and high building speed, and meet the requirement of wall body reformation in the industrial development of buildings. The building blocks are divided into small building blocks, medium building blocks and large building blocks according to the size and the mass. The main specification of the building block series is larger than 115mm and smaller than 380mm, the building blocks are called small building blocks, the building blocks with the height of 380-980mm are called medium building blocks, the building blocks with the height of 980mm are called large building blocks, and the number of the medium and small building blocks is large in daily use.

However, the conventional block has a smooth surface, and is prone to collapse after being stacked for a plurality of times. Secondly, because of long-time use, soak in water for a long time, the fixity and the stability of building block all descend a lot, can arouse certain potential safety hazard in serious time, and this is not very favorable to hydraulic engineering whole work. In hydraulic engineering, how to design a building block capable of solving the problems is a subject to be researched.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a building block that hydraulic engineering used to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above purpose, the utility model provides a following technical scheme: the utility model provides a building block that hydraulic engineering used, includes building block, first slider, first recess, second slider and second recess, first slider sets up the right side at the building block, first recess is seted up in the left side of building block, the second slider sets up the top at the building block, the bottom at the building block is seted up to the second recess.

Preferably, the shape of the first sliding block is matched with that of the first groove inner cavity, and the shape of the second sliding block is matched with that of the second groove inner cavity.

Preferably, the front surface of the building block is provided with a through hole, an arched supporting block is arranged in an inner cavity of the through hole, a supporting plate is arranged at the top of the arched supporting block, a connecting block is arranged at the top of the supporting plate, and the connecting block is connected with the top of the building block.

Preferably, both sides of the arched support block are connected with the inner wall of the through hole.

Preferably, the connecting blocks are arranged linearly, four groups are arranged in total, and the connecting blocks are in a V shape.

Compared with the prior art, the beneficial effects of the utility model are that:

1. this building block that hydraulic engineering used, through the cooperation of first slider, first recess, second slider and second recess, when laying the building block, should be according to from the bottom up and from the right order of turning left. When the current building block is laid, the positions of the first sliding block on the right side of the building block and the first groove on the left side of the building block on the right side need to be firstly aligned, so that the first sliding block can just enter the inner cavity of the first groove, the left and right building block can be fixed, and the cohesion of the building block in the left and right directions is improved. Meanwhile, the positions of a second groove at the bottom of the building block and a second sliding block at the top of the building block at the bottom are required to be aligned, so that the second sliding block can enter an inner cavity of the second groove and be matched, the upper building block and the lower building block are fixed, and the cohesion of the building blocks in the vertical direction is improved. Because the shape of first slider is identical with the shape of first recess inner chamber, and the shape of second slider is identical with the shape of second recess inner chamber, so can not appear the too big unable condition of entering the recess of slider in the course of piling up, also can not appear the untight problem of cooperation that the slider undersize leads to. The stability of the whole building block is greatly improved under the matching condition.

2. This building block that hydraulic engineering used, through the cooperation of through-hole, arch supporting shoe, backup pad, the existence of through-hole can prevent that the stormy weather building block from openly having accumulated too much rainwater, the potential safety hazard that arouses, the rainwater can be along the through-hole discharge. Secondly, the existence of the through holes can also reduce the use of the building block material, avoid waste and enable the whole building block to be more energy-saving and beautiful. Be provided with the arch supporting shoe in the inner chamber of through-hole, the arch supporting shoe can support the backup pad, and the backup pad supports the connecting block, and the connecting block links to each other with the top of building block again to can support the gravity at top, and the arch design can avoid appearing stress concentration's the condition, the maximize ground pressure at dispersion top. The both sides of arch supporting shoe link to each other with the inner wall of through-hole, can realize the dispersion of power with the lateral extrusion force of the pressure conversion at top, avoid the too big condition of stress to appear in building block somewhere.

3. This building block that hydraulic engineering used, through the cooperation of connecting block and building block, triangle-shaped has stability, consequently "V" font connecting block can promote the stability of connecting block department, realizes the dispersion of power. And secondly, the V-shaped unevenness can increase the friction force on the surface of the device building block, thereby being convenient to use.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a right side view of the present invention.

Fig. 4 is a top view of the present invention.

In the figure: 1. building blocks; 2. a first slider; 3. a first groove; 4. a second slider; 5. a second groove; 6. a through hole; 7. an arched support block; 8. a support plate; 9. and (4) connecting the blocks.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a building block that hydraulic engineering used, includes building block 1, first slider 2, first recess 3, second slider 4 and second recess 5, and first slider 2 sets up on the right side of building block 1, and first recess 3 is seted up in the left side of building block 1, and second slider 4 sets up at the top of building block 1, and second recess 5 is seted up in the bottom of building block 1.

Wherein, the shape of the first slide block 2 is matched with the shape of the inner cavity of the first groove 3, and the shape of the second slide block 4 is matched with the shape of the inner cavity of the second groove 5.

In this embodiment, since the shape of the first slider 2 is matched with the shape of the inner cavity of the first groove 3, and the shape of the second slider 4 is matched with the shape of the inner cavity of the second groove 5, the situation that the slider is too large and cannot enter the groove during stacking is avoided, and the problem of untight matching caused by too small slider is also avoided. The stability of the whole building block 1 is greatly improved under the matching condition.

Wherein, through-hole 6 has been seted up on the front of building block 1, is provided with arch supporting shoe 7 in the inner chamber of through-hole 6, and the top of arch supporting shoe 7 is provided with backup pad 8, and the top of backup pad 8 is provided with connecting block 9, and connecting block 9 links to each other with the top of building block 1.

In this embodiment, the existence of through-hole 6 can prevent that rainstorm weather building block 1 from openly having accumulated too much rainwater, the potential safety hazard that arouses, and the rainwater can be discharged along through-hole 6. Secondly, the existence of the through holes 6 can also reduce the use of the material of the building block 1, thereby avoiding waste and leading the whole building block 1 to be more energy-saving and beautiful. Be provided with arch supporting shoe 7 in the inner chamber of through-hole 6, arch supporting shoe 7 can support backup pad 8, and backup pad 8 supports connecting block 9, and connecting block 9 links to each other with the top of building block 1 again to can support the gravity at top, and the arch design can avoid the condition of stress concentration, and the pressure at maximize ground dispersion top.

Wherein, the two sides of the arched supporting block 7 are connected with the inner wall of the through hole 6.

In this embodiment, the two sides of the arched supporting block 7 are connected with the inner wall of the through hole 6, so that the pressure at the top can be converted into lateral extrusion force, force dispersion is realized, and the condition that the stress is too large at a certain position of the building block 1 is avoided.

Wherein, the connecting blocks 9 are linearly arranged, and have four groups in total, and the shape of V-shaped.

In this embodiment, the triangle has stability, so the V-shaped connecting block 9 can improve the stability of the connecting block 9, and realize the force dispersion. Secondly, the V-shaped unevenness can increase the friction force of the surface of the device building block 1, and is convenient to use.

The working principle is as follows: the blocks 1 should be laid in the order from bottom to top and from right to left. When laying current building block 1, need aim at the first slider 2 in this building block 1 right side at first and the position of the first recess 3 in the left side of right side building block 1 for first slider 2 just can get into the inner chamber of first recess 3, thereby realizes controlling building block 1's fixed, promotes the cohesion of building block 1 left and right sides direction. Meanwhile, the positions of the second groove 5 at the bottom of the building block 1 and the position of the second sliding block 4 at the top of the building block 1 at the bottom also need to be aligned, so that the second sliding block 4 can enter the inner cavity of the second groove 5 and realize matching, the fixing of the upper building block 1 and the lower building block 1 is realized, and the cohesion of the building block 1 in the up-and-down direction is improved. Because the shape of the first sliding block 2 is matched with the shape of the inner cavity of the first groove 3, and the shape of the second sliding block 4 is matched with the shape of the inner cavity of the second groove 5, the situation that the sliding block is too large and cannot enter the groove can not occur in the stacking process, and the problem of untight matching caused by too small sliding block can not occur. The fit condition greatly improves the stability of the whole building block 1. The existence of through-hole 6 can prevent that rainstorm weather building block 1 from openly having accumulated too much rainwater, the potential safety hazard that arouses, and the rainwater can be discharged along through-hole 6. Secondly, the existence of the through holes 6 can also reduce the use of the material of the building block 1, thereby avoiding waste and leading the whole building block 1 to be more energy-saving and beautiful. Be provided with arch supporting shoe 7 in the inner chamber of through-hole 6, arch supporting shoe 7 can support backup pad 8, and backup pad 8 supports connecting block 9, and connecting block 9 links to each other with the top of building block 1 again to can support the gravity at top, and the arch design can avoid the condition of stress concentration, and the pressure at maximize ground dispersion top. The both sides of arch supporting shoe 7 link to each other with the inner wall of through-hole 6, can realize the dispersion of power with the lateral extrusion force of pressure conversion at top, avoid building block 1 certain department to appear the too big condition of stress. The triangle has stability, so the V-shaped connecting block 9 can improve the stability of the connecting block 9 and realize the force dispersion. Secondly, the V-shaped unevenness can increase the friction force of the surface of the device building block 1, and is convenient to use.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a building block that hydraulic engineering used, includes building block (1), first slider (2), first recess (3), second slider (4) and second recess (5), its characterized in that: the first sliding block (2) is arranged on the right side of the building block (1), the first groove (3) is formed in the left side of the building block (1), the second sliding block (4) is arranged at the top of the building block (1), and the second groove (5) is formed in the bottom of the building block (1).

2. A block for hydraulic engineering according to claim 1, wherein: the shape of the first sliding block (2) is matched with the shape of the inner cavity of the first groove (3), and the shape of the second sliding block (4) is matched with the shape of the inner cavity of the second groove (5).

3. A block for hydraulic engineering according to claim 1, characterized in that: the building block is characterized in that a through hole (6) is formed in the front face of the building block (1), an arched supporting block (7) is arranged in an inner cavity of the through hole (6), a supporting plate (8) is arranged at the top of the arched supporting block (7), a connecting block (9) is arranged at the top of the supporting plate (8), and the connecting block (9) is connected with the top of the building block (1).

4. A block for hydraulic engineering according to claim 3, characterized in that: and two sides of the arched supporting block (7) are connected with the inner wall of the through hole (6).

5. A block for hydraulic engineering according to claim 3, wherein: the connecting blocks (9) are linearly arranged, four groups are arranged in total, and the shape of the connecting blocks is V-shaped.

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