CN111335511A - Prefabricated unit wall structure of ceramic brick - Google Patents

Abstract

The invention discloses a wall structure of a ceramic brick prefabricating unit, which comprises a steel frame, porous ceramic bricks and a positioning structure, wherein the steel frame comprises 2 square steel tubes and 2 pieces of angle steel, the number of the angle steel is set to be a plurality, the angle steel is arranged between the 2 square steel tubes in parallel, positioning holes are formed in the upper end surface and the lower end surface of each porous ceramic brick and a horizontal plane penetrating through the angle steel, the positioning structure comprises positioning pins and nylon gaskets which are integrally formed, the positioning pins are symmetrically arranged on two sides of each nylon gasket, the porous ceramic bricks are stacked between the adjacent angle steel, the nylon gaskets are arranged between the upper and lower adjacent porous ceramic bricks or between the porous ceramic bricks and the angle steel, the positioning pins are arranged in the positioning holes, and cement mortar is arranged between the upper and lower adjacent porous ceramic bricks. The invention makes the perforated ceramic bricks and the steel frame into the prefabricated unit wall body in the factory stage, has high processing precision, simple and convenient field installation and high construction speed, and greatly shortens the construction period.

Description

Prefabricated unit wall structure of ceramic brick

Technical Field

The invention belongs to the field of construction of architectural decoration engineering, and particularly relates to a wall structure of a ceramic brick prefabricated unit.

Background

In order to meet the requirements of national building on energy conservation, high efficiency and green standard, various unit plate type curtain walls appear in succession. The ceramic brick uses natural pottery clay as a raw material, has unique visual decoration effect, low heat conductivity coefficient, corrosion resistance and scouring resistance, and is a better choice for curtain wall materials. The construction sequence of the existing ceramic brick curtain wall is that steel frames are welded on the outer side of the wall body of a building and then ceramic bricks are built layer by layer, the construction site occupies a large space and is slow in construction speed, the verticality and the levelness of the ceramic brick curtain wall are not easy to control, and the overall construction quality is poor.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a wall body structure of a ceramic brick prefabricated unit, which can improve the construction speed of a ceramic brick curtain wall, ensure the installation flatness of the ceramic brick curtain wall and improve the overall construction quality.

In order to achieve the purpose, the invention adopts the following technical scheme:

the invention provides a wall structure of a ceramic brick prefabricating unit, which comprises a steel frame, perforated ceramic bricks and a positioning structure, wherein the steel frame comprises 2 square steel tubes and 2 pieces of angle steel, the number of the angle steel is set to be a plurality of angle steel, the angle steel is parallelly arranged among the 2 square steel tubes, positioning holes are formed in the upper end surface and the lower end surface of each perforated ceramic brick and a horizontal plane penetrating through the angle steel, the positioning structure comprises positioning pins and nylon gaskets which are integrally formed, the positioning pins are symmetrically arranged on two sides of each nylon gasket, the perforated ceramic bricks are piled between the adjacent angle steel, the nylon gaskets are arranged between the upper and lower adjacent perforated ceramic bricks or between the perforated ceramic bricks and the angle steel, the positioning pins are arranged in the positioning holes, and cement mortar is arranged between the upper and lower adjacent perforated ceramic bricks.

The prefabricated unit wall structure can be prefabricated in a factory, and is hung outside a building wall through the steel support after the whole prefabricated unit wall structure is manufactured, so that the mounting quality, the mounting efficiency and the mounting stability of the ceramic brick curtain wall are improved, the workload of field welding is reduced, and the construction period is shortened.

According to the preferable technical scheme, the surfaces of the square steel pipe and the angle steel are plated with zinc protective layers, and the length of the section of the square steel pipe is equal to that of the horizontal plate of the angle steel.

The zinc protective layer can protect the square steel pipe and the angle steel from being corroded by rainwater, and the service life is prolonged.

As a preferred technical scheme, 2 groups of positioning holes are arranged on the upper end surface and the lower end surface of each perforated ceramic brick, the 2 groups of positioning holes are symmetrically arranged along the center line of the ceramic brick, each group of positioning holes comprises 4 positioning holes, and each group of positioning holes is correspondingly provided with one positioning structure.

The technical effect is further that the two groups of positioning holes are arranged, and when the upper pored ceramic brick and the lower pored ceramic brick are arranged in a staggered mode, each pored ceramic brick can be fixed with the upper pored ceramic brick and the lower pored ceramic brick which are adjacent to each other through the positioning holes.

As the preferred technical scheme, the perforated ceramic bricks which are adjacent up and down are arranged in a staggered mode, and cement mortar is arranged between the horizontally adjacent perforated ceramic bricks.

Further technical effect, foraminiferous ceramic brick adopts crisscross mounting means to make foraminiferous ceramic brick of intermediate position pass through the locating pin and be connected with other 4 foraminiferous ceramic bricks location, has improved overall structure's stability.

According to the preferable technical scheme, one side, close to the vertical face of the angle steel, of the perforated ceramic brick located at one end in the same layer is provided with an installation groove, the installation groove is matched with the square steel pipe, and a ceramic brick gap is formed between the perforated ceramic brick located at the other end and the square steel pipe.

The square steel pipe can be hidden between a building wall and the perforated ceramic brick due to the fact that the square steel pipe is matched with the mounting groove, attractiveness is improved, and meanwhile the square steel pipe is prevented from being corroded by rainwater.

According to the preferable technical scheme, when the prefabricated unit wall body is installed, ceramic brick gaps of the prefabricated unit wall body adjacent to each other in the horizontal direction are spliced and aligned to form a ceramic brick installation groove, a filled ceramic brick is installed at the ceramic brick installation groove, and the filled ceramic brick and the steel square pipe are fixed through steel pins.

Further technological effect sets up and fills ceramic brick and has guaranteed overall structure's integrality for overall structure satisfies the design requirement.

Compared with the prior art, the invention has the beneficial effects that:

(1) the invention makes the perforated ceramic bricks and the steel frame into the prefabricated unit wall body in the factory stage, has high processing precision, simple and convenient field installation and high construction speed, and greatly shortens the construction period.

(2) According to the invention, the adjacent ceramic bricks are fixed by the positioning pins, so that the integral structure is more compact and firm, and the safety of the ceramic brick curtain wall is greatly enhanced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of a steel frame in the prefabricated unit wall structure according to the present invention.

Fig. 2 is a schematic structural view of perforated ceramic bricks in the prefabricated unit wall structure.

Fig. 3 is a front view of a positioning structure in the prefabricated unit wall structure according to the present invention.

Fig. 4 is a top view of a positioning structure in the prefabricated unit wall structure according to the present invention.

Fig. 5 is a schematic view of an assembly structure of perforated ceramic bricks in the wall structure of the prefabricated units according to the present invention.

Fig. 6 is a front view of the adjustable ceramic brick dry hanging device of the present invention.

Fig. 7 is a partial enlarged sectional view along a-a of fig. 6.

Fig. 8 is a sectional view taken along the direction B-B of fig. 6.

Fig. 9 is a sectional view taken along the direction C-C of fig. 6.

Fig. 10 is a schematic structural view of a steel support in the adjustable ceramic brick dry hanging device of the present invention.

Wherein the reference numerals are specified as follows: the prefabricated unit wall body comprises a steel square pipe 1, angle steel 2, a horizontal plane 3, a vertical plane 4, a positioning hole 5, a perforated ceramic tile 6, a nylon gasket 7, a positioning pin 8, a pore 9, cement mortar 10, a filling ceramic tile 11, a Hafen groove building wall body 12, a Hafen groove embedded part 13, a steel support 14, a prefabricated unit wall body 15, a steel frame 16, a positioning structure 17, a T-shaped bolt 18, a steel bracket 19, a switching frame 20, a square upright post 21, a seal head steel plate 22, a connecting post 23, a reinforcing plate 24, a connecting bolt 25, an adjusting bolt 26, an adjusting nut 27, a buffer gasket 28 and a long waist hole 29.

Detailed Description

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

Example 1

This embodiment provides a prefabricated unit wall structure, and this prefabricated unit wall 15 accomplishes at the stage preparation of mill, including steel frame 16, foraminiferous ceramic brick 6 and location structure 17, and whole prefabricated unit wall 15's width is 1000mm, and the height is 3900 mm.

As shown in fig. 1, the steel frame 16 includes a square steel tube 1 and an angle steel 2, and the surfaces of the square steel tube 1 and the angle steel 2 are plated with a zinc protective layer. The length of the cross section of steel square pipe 1 is 100mm, and the width is 50mm, and thickness is 8mm, and the cross section of angle steel 2 is the L type, and the length of its horizontal end is 100mm, and the length of vertical end is 40mm, and thickness is 4 mm. The parallel arrangement of steel square pipe 1 is 2, and angle steel 2 sets up to 7, and angle steel 2 welds between 2 steel square pipe 1, and the distance between the adjacent angle steel 2 from top to bottom is decided with actual conditions, is about 630 mm.

As shown in fig. 2, the perforated ceramic tile 6 is a conventional hollow brick, and the upper surface and the lower surface of the perforated ceramic tile 6 are provided with positioning holes 5, wherein the positioning holes 5 on the upper surface and the positioning holes 5 on the lower surface are symmetrically arranged, 2 groups of positioning holes 5 are arranged on each surface, and the 2 groups of positioning holes 5 are symmetrically arranged along the central line of the perforated ceramic tile 6. Each group of positioning holes 5 comprises 4 positioning holes, the connecting line of the 4 positioning holes 5 is square, and each group of positioning holes 5 corresponds to one positioning structure 17.

As shown in fig. 3-4, the positioning structure 17 includes a nylon gasket 7 and a positioning pin 8, the positioning pin 8 is also made of nylon, the positioning pin 8 and the nylon gasket 7 are integrally formed, the thickness of the nylon gasket 7 is 4mm, the two sides of the nylon gasket 7 are respectively provided with 4 positioning pins 8, the diameter of the positioning pin 8 is 8mm, the connecting line of the 4 positioning pins 8 is square and corresponds to the position of the positioning hole 5, wherein the surface of the nylon gasket 7 is also uniformly provided with a plurality of pores 9 in a penetrating manner, and the diameter of the pores 9 is 4 mm.

The horizontal plane 3 of the angle steel 2 in the steel frame 16 is also provided with a positioning hole 5 for positioning connection with the perforated ceramic bricks 6, the perforated ceramic bricks 6 positioned at the lowest layer are placed on the horizontal plane 3 of the angle steel 2 between every two adjacent angle steels 2, and the lower end surfaces of the perforated ceramic bricks and the angle steel 2 are fixed through nylon gaskets 7 and positioning pins 8. As shown in fig. 5, the perforated ceramic tiles 6 adjacent to each other up and down are staggered, cement mortar 10 is filled between the perforated ceramic tiles 6 adjacent to each other up and down, the thickness of the cement mortar 10 is 10mm, and the perforated ceramic tile 6 on the uppermost layer and the perforated ceramic tile 6 on the uppermost end and the angle iron 2 are fixed by a positioning pin 8 and a nylon gasket 7. Because foraminiferous ceramic brick 6 is crisscross the setting, except the topside and the foraminiferous ceramic brick 6 of lower floor, the foraminiferous position of all the other positions department all passes through locating pin 8 with adjacent 4 foraminiferous ceramic bricks from top to bottom fixed, has improved overall structure's stability, and it has cement mortar 10 to fill equally between the adjacent foraminiferous ceramic brick 6 of horizontal direction, and the packing thickness of cement mortar 10 is 10 mm. Crisscross foraminiferous ceramic brick 6 that sets up must lead to prefabricated unit wall body 15's vertical edge to be the cusp, consequently, has seted up the mounting groove on the foraminiferous ceramic brick 6 that is located the one end of being close to angle steel 2 facade 4 in the same layer, and the mounting groove sets up in foraminiferous ceramic brick 6 one side of being close to angle steel 2 facade 4, mounting groove and steel square pipe 1 phase-match, and 1 block in the mounting groove is managed in steel square, the foraminiferous ceramic brick 6 that is located the other end with form the ceramic brick gap between the steel square pipe 1, when the installation, the ceramic brick gap concatenation between the adjacent prefabricated unit wall body 15 forms a ceramic brick mounting groove for the ceramic brick 11.

Example 2

The embodiment is a construction process of embodiment 1, and specifically includes the following steps:

step one, welding a steel frame 16; preparing 2 steel square pipes 1 with the same structure and 7 angle steels 2 with the same structure, welding the angle steels 2 among the 2 steel square pipes 1, and forming positioning holes 5 in horizontal planes 3 of the angle steels 2;

step two, manufacturing a perforated ceramic brick 6; the upper end surface and the lower end surface of the ceramic brick are provided with positioning holes 5 which are symmetrical to each other;

step three, manufacturing a positioning structure 17; the positioning structure 17 comprises a nylon gasket 7 and positioning pins 8, and the positioning pins 8 are arranged on two sides of the nylon gasket 7;

step four, manufacturing a prefabricated unit wall 15; placing a nylon gasket 7 of a positioning structure 17 on a horizontal plane 3 of a lower angle steel 2, inserting a positioning pin 8 on the lower end face of the nylon gasket 7 into a positioning hole 5 of the angle steel 2, laying a perforated ceramic brick 6 on the upper end face of the nylon gasket 7, and inserting the positioning pin 8 on the upper end face of the nylon gasket 7 into the positioning hole 5 on the lower end face of the perforated ceramic brick 6;

placing a nylon gasket 7 of a positioning structure 17 on the upper end face of the perforated ceramic brick 6, inserting a positioning pin 8 on the lower end face of the nylon gasket 7 into a positioning hole 5 on the upper surface of the perforated ceramic brick 6, pouring cement mortar 10 with the thickness of 10mm on the upper portion of the nylon gasket 7, paving the perforated ceramic brick 6 on the upper portion of the cement mortar 10 before the cement mortar 10 is dried, and inserting the positioning pin 8 on the upper end face of the nylon gasket 7 into the positioning hole 5 on the lower end face of the perforated ceramic brick 6; the cement mortar 10 is immersed on the lower-layer perforated ceramic brick 6 through the fine holes 9 on the nylon gasket 7, so that the connection between the upper-layer perforated ceramic brick 6 and the lower-layer perforated ceramic brick 6 is ensured to be stable;

step six, repeating the step five until the perforated ceramic bricks 6 are piled up to the upper angle steel 2, placing a nylon gasket 7 on the horizontal plane 3 of the upper angle steel 2, and enabling a positioning pin 8 on the lower end face of the nylon gasket 7 to penetrate through the upper angle steel 2 and a positioning hole 5 on the perforated ceramic brick 6 on the uppermost layer;

and seventhly, repeating the first step to the sixth step to finish the installation of the perforated ceramic bricks 6 on the steel frame 16.

Example 3

As shown in fig. 6-9, the present embodiment provides an adjustable ceramic brick dry hanging device, which includes a haunch embedded part 13, a steel support 14 and a prefabricated unit wall 15, wherein the haunch embedded part 13 is embedded in a building wall 12, and one side of a notch is exposed for connecting with the steel support 14.

As shown in fig. 10, the steel support 14 includes a T-bolt 18, a steel bracket 19, an adapter 20, a square column 21, and a connecting column 23, and a head of the T-bolt 18 is fastened into a C-shaped groove of the haifen groove embedded part 13. The steel bracket 19 is of a cuboid structure, one side of the steel bracket is fixedly connected with the Hufen groove embedded part 13 through a T-shaped bolt 18, the front and back positions of the prefabricated unit wall body 15 are adjusted by adjusting the position of the T-shaped bolt 18 in the C-shaped groove, and the T-shaped bolt 18 and the steel bracket 19 are fixed through nuts after the adjustment is completed.

The end of the steel bracket 19 opposite to the T-shaped bolt 18 is an open end, a reinforcing plate 24 extends downwards from one end of the lower base plate of the steel bracket 19 close to the T-shaped bolt 18, the reinforcing plate 24 and the lower base plate of the steel bracket 19 are of an integrated L-shaped steel structure, and the thickness of the reinforcing plate is 8 mm. The reinforcing plate 24 is attached to the building wall 12 after the steel bracket 19 is fixed to the Hafenz groove embedded part 13, so that the stability of the whole structure is improved. The lower bottom plate of the steel bracket 19 is provided with a long waist hole 29 in a penetrating way, the length direction of the long waist hole 29 is vertical to the length direction of the C-shaped groove, and the long waist hole 29 is arranged close to the open end. The adapter 20 is of a U-shaped structure and is arranged in the steel bracket 19, the bottom of the adapter 20 is fixed to the bottom of the steel bracket 19 through a connecting bolt 25, specifically, a bolt hole is formed in the bottom of the adapter 20, the connecting bolt 25 sequentially penetrates through the bolt hole in the adapter 20 and the elongated waist hole 29, a gasket is arranged on the lower end face of the elongated waist hole 29, and then the bolt is fixed through a nut, and the connecting bolt 25 is an M10 bolt. The front and rear positions of the prefabricated unit wall body 15 can be adjusted by adjusting the installation position of the connecting bolt 25 in the elongated waist hole 29.

The square column 21 is a hollow steel pipe structure with a cross section of 50 × 5mm, the square column 21 is arranged in the adapter frame 20, an end enclosure steel plate 22 is arranged at the top of the square column 21, an adjusting nut 27 is fixed on the end enclosure steel plate 22, an adjusting bolt 26 penetrates through the adjusting nut 27, the bottom end of the adjusting bolt 26 is in contact with the bottom side of the adapter frame 20, a buffer gasket 28 is arranged between the adapter frame 20, the buffer gasket 28 is made of PVC materials, and the thickness of the buffer gasket 28 is 2 mm. Because the bottom end of the adjusting bolt 26 is in contact with the bottom side of the adapter frame 20, when the adjusting bolt 26 is screwed, the adjusting bolt 26 cannot move up and down, the square upright post 21 moves up and down under the action of the thread, and because the adapter frame 20 has a limiting effect on the square upright post 21, the square upright post 21 cannot rotate while moving up and down, and the prefabricated unit wall body 15 can move up and down through the adjusting bolt 26. The connecting column 23 is a hollow steel pipe structure with 50 × 5mm, one end of the connecting column 23 is fixed on the side wall of the square column 21, the connecting column 23 is perpendicular to the square column 21, and the other end of the connecting column 23 is welded with the steel square pipe 1 of the prefabricated unit wall 15.

Each prefabricated unit wall body 15 is correspondingly provided with 4 steel supports 14 which are respectively arranged at the end parts of the two steel square pipes 1 on the prefabricated unit wall body 15.

Example 4

The embodiment provides a construction method of an adjustable ceramic brick dry hanging device, which comprises the following steps:

step one, burying a hafen groove embedded part 13 in a building wall body 12, wherein a notch of the hafen groove embedded part 13 is exposed;

step two, the head of the T-shaped bolt 18 is assembled in a C-shaped groove of the Hafenz groove embedded part 13;

step three, fixedly connecting the steel support 14 with the Hafen groove embedded part 13 through a T-shaped bolt 18;

welding the square steel pipe 1 of the prefabricated unit wall body 15 with the connecting column 23;

and step five, carrying out three-dimensional adjustment on the installation position of the prefabricated unit wall body 15 through the steel support 14.

Although the present invention has been described in detail with respect to the above embodiments, it will be understood by those skilled in the art that modifications or improvements based on the disclosure of the present invention may be made without departing from the spirit and scope of the invention, and these modifications and improvements are within the spirit and scope of the invention.

Claims (6)

1. The utility model provides a prefabricated unit wall structure of ceramic brick, its characterized in that, includes steel frame, foraminiferous ceramic brick and location structure, steel frame includes steel side pipe and angle steel, steel side pipe parallel arrangement is 2, the angle steel sets up to a plurality of and parallel arrangement in 2 between the steel side pipe, the up end and the lower terminal surface of foraminiferous ceramic brick, run through the horizontal plane of angle steel all is provided with the locating hole, location structure includes integrated into one piece's locating pin and nylon gasket, the locating pin symmetry set up in the both sides of nylon gasket, foraminiferous ceramic brick is piled up between adjacent angle steel, the nylon gasket sets up between the foraminiferous ceramic brick of adjacent from top to bottom or between foraminiferous ceramic brick and the angle steel, the locating pin set up in the locating hole, adjacent from top to bottom be provided with cement mortar between the foraminiferous.

2. The ceramic tile prefabricated unit wall structure according to claim 1, wherein the surfaces of the square steel pipes and the angle steel are plated with a zinc protective layer, and the sectional length of the square steel pipes is the same as the length of the horizontal plate of the angle steel.

3. A wall structure of a ceramic tile prefabrication unit as claimed in claim 1, wherein each of the perforated ceramic tiles is provided with 2 sets of positioning holes on the upper end surface and the lower end surface, the 2 sets of positioning holes are symmetrically arranged along the center line of the ceramic tile, each set of positioning holes comprises 4 positioning holes, and each set of positioning holes is provided with one corresponding positioning structure.

4. The wall structure of a pottery brick precast unit according to claim 3, wherein the perforated pottery bricks adjacent up and down are staggered, and cement mortar is disposed between the horizontally adjacent perforated pottery bricks.

5. The wall structure of a ceramic tile prefabrication unit as claimed in claim 4, wherein the perforated ceramic tile at one end of the same floor is provided with an installation groove at one side close to the vertical surface of the angle iron, the installation groove is matched with the square steel pipe, and a ceramic tile gap is formed between the perforated ceramic tile at the other end and the square steel pipe.

6. The wall structure of prefabricated ceramic units as claimed in claim 5, wherein when the prefabricated ceramic units are installed, ceramic tile gaps of the horizontally adjacent prefabricated ceramic units are spliced and aligned to form ceramic tile installation grooves, filling ceramic tiles are installed at the ceramic tile installation grooves, and the filling ceramic tiles are fixed to the steel square pipes through steel pins.

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