CN113931402B

CN113931402B - Assembly type building structure

Info

Publication number: CN113931402B
Application number: CN202111236781.0A
Authority: CN
Inventors: 樊洪坤; 徐超; 李梦金
Original assignee: Zhejiang Yaohua Planning And Architectural Design Co ltd
Current assignee: Zhejiang Yaohua Planning And Architectural Design Co ltd
Priority date: 2021-10-23
Filing date: 2021-10-23
Publication date: 2022-12-06
Anticipated expiration: 2041-10-23
Also published as: CN113931402A

Abstract

The application discloses assembly type structure, it includes a plurality of ceramic tile body, is used for connecting fossil fragments and the coupling mechanism of multiunit setting on fossil fragments on outer facade, be connected with the inner panel on the ceramic tile body, be provided with a plurality of connecting holes that are used for supplying the inner panel to insert and establish on fossil fragments, coupling mechanism sets up the locking rack on fossil fragments including rotating the locking gear of connection on fossil fragments and sliding, the extending direction of the slip direction perpendicular to connecting hole of locking rack, locking rack and locking gear meshing, offer on the lateral wall of inner panel and be used for supplying locking rack tip to insert the locking groove of establishing. This application has the effect of convenient to detach ceramic tile.

Description

Assembly type building structure

Technical Field

The application relates to the technical field of constructional engineering, in particular to an assembly type building structure.

Background

The fabricated building is a building which is fabricated by transferring a large amount of field operation work in the traditional construction mode to a factory, processing and manufacturing building components and accessories in the factory, transporting the components and accessories to a building construction site, and assembling and installing the components and accessories on the site in a reliable connection mode.

In the related art, in order to beautify the outer vertical surface of a building, an assembled ceramic tile wall surface is often installed on the outer vertical surface. When installing the ceramic tile, need to coat cement on the facade of building now, then paste the ceramic tile on the facade of building again.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: when one of the ceramic tiles is damaged and needs to be replaced and maintained, the ceramic tile is difficult to take down and needs to be improved.

Disclosure of Invention

In order to facilitate the dismantlement ceramic tile, this application provides an assembly type structure.

The application provides an assembled building structure adopts following technical scheme:

the utility model provides an assembly type building structure, includes a plurality of ceramic tile bodies, is used for connecting fossil fragments and the coupling mechanism of multiunit setting on fossil fragments on outer facade, be connected with the inner panel on the ceramic tile body, be provided with a plurality of connecting holes that are used for supplying the inner panel to insert and establish on the fossil fragments, coupling mechanism sets up the locking rack on fossil fragments including rotating the locking gear of connection on fossil fragments and sliding, the extending direction of the slip direction perpendicular to connecting hole of locking rack, locking rack and locking gear meshing, offer on the lateral wall of inner panel and be used for supplying locking rack tip to insert the locking groove of establishing.

Through adopting above-mentioned technical scheme, when installing the ceramic tile body, fix fossil fragments on outer facade earlier, insert the inner panel in the connecting hole again, then rotate the locking gear and slide to the direction that is close to the inner panel with drive locking rack, insert the locking groove until the tip of locking rack to the restriction inner panel shifts out the connecting hole, and then makes the ceramic tile body fixed on outer facade.

When the ceramic tile body damages and needs to be changed, the locking gear is rotated to shift out the locking groove with the driving rack, the ceramic tile body can be taken down from the keel, and the new ceramic tile body and the inner plate can be replaced.

Through adopting above-mentioned structure for damaged tile body can change alone, and only need rotate when dismantling locking gear can, easy and simple to handle, the staff of being convenient for dismantles the ceramic tile.

Optionally, still including setting up the heat preservation pad in the connecting hole, coupling mechanism is still including sliding the spacing rack that sets up on fossil fragments, the extending direction of the slip direction perpendicular to connecting hole of spacing rack, spacing rack and locking gear keep away from the meshing of one side of locking rack, offer on the terminal surface that tile body was kept away from to the inner panel and be used for supplying spacing rack to insert the groove of stepping down of establishing, the groove of stepping down is linked together with the lateral wall of inner panel.

By adopting the technical scheme, the heat insulation pad arranged in the connecting hole plays a role in keeping warm for the whole building. Because the limiting rack is meshed with one side, far away from the locking rack, of the locking gear, when the locking gear rotates towards one direction, the limiting rack moves towards the connecting hole, and when the locking gear rotates towards the other direction, the locking rack moves towards the connecting hole.

When the tile body is disassembled, the locking gear is firstly rotated to drive the locking rack to move out of the locking groove and the limiting rack to stretch into the abdicating groove. Because the groove of stepping down sets up on the terminal surface that the ceramic tile body was kept away from to the inner panel, and the lateral wall of groove and inner panel of stepping down to being linked together for the ceramic tile body of treating to change can be taken off. At this moment, spacing rack has played the effect that blocks, has restricted that the heat preservation pad is deviate from the connecting hole for the staff need not to support the heat preservation pad, helps the staff to carry new ceramic tile body. After the inner plate on the new ceramic tile body is installed into the connecting hole, the locking gear is reversely rotated, the locking rack is inserted into the locking groove to connect the inner plate and the keel, and the inner plate plays a role in blocking so as to limit the heat-insulating pad from being separated from the connecting hole.

Through the structure, the working personnel do not need to support the heat-insulating pad, and the simplicity of the ceramic tile body during installation or disassembly is improved.

Optionally, the locking gear is divided into a toothed portion and a non-toothed portion along the circumferential direction, gear teeth are arranged on the circumferential side wall of the toothed portion, the circumferential side wall of the non-toothed portion is smooth, and the toothed portion is used for being meshed with the locking rack or the limiting rack.

By adopting the technical scheme, when the tile body is installed on the keel, the locking gear is rotated to enable the toothed part to be meshed with the locking rack, so that the locking rack is driven to be inserted into the locking groove; when the tile body is replaced, the locking gear is rotated to enable the toothed part to be meshed with the locking rack firstly and then meshed with the limiting rack, so that the locking rack is driven to be drawn out of the locking groove, and the limiting rack is driven to be inserted into the abdicating groove; when the heat preservation cushion is installed, the locking gear is rotated to enable the locking rack and the limiting rack to move out of the connecting hole, and at the moment, the toothed part rotates to a position between the limiting rack and the locking rack. Through the locking gear of this application, can only drive locking rack or spacing rack and remove to make locking rack and spacing rack all can not play the interference to the installation that keeps warm and fill up, help the staff to install the heat preservation and fill up.

Optionally, the last eccentric feedback piece that is provided with of locking gear, be provided with the touch piece on the fossil fragments, the tip of touch piece is located the rotation route of feedback portion, when the touch piece is contradicted with one of them side wall of feedback piece, the locking rack stretches into in the locking groove, when the touch piece is contradicted with the opposite side lateral wall of feedback piece, spacing rack stretches into in the groove of stepping down.

Through adopting above-mentioned technical scheme, because the inner panel inserts in the connecting hole when installing the ceramic tile body for whether staff is difficult to observe the locking piece and inserts the locking groove completely, or whether spacing rack inserts the groove of stepping down completely. Through feedback piece and touch piece for during staff rotating gear, rotate to feedback piece and touch piece conflict, insert the locking groove for the locking rack, or spacing rack inserts the groove of stepping down, help the staff to judge whether the installation of ceramic tile body finishes, improved the stability after the ceramic tile body is installed to fossil fragments.

Optionally, a plurality of sealing strips are arranged on the keel, and the sealing strips are located between the two adjacent ceramic tile bodies.

Through adopting above-mentioned technical scheme, the sealing strip has played the effect that blocks water, has restricted during the rainwater gets into the clearance between two ceramic tile bodies, has further improved this application assembly type structure's the performance that blocks water, has improved the protection effect that blocks water to the facade.

Optionally, a hexagonal block is arranged on the sealing strip, a rotating shaft is connected to the keel in a rotating mode, the locking gear is fixed to the rotating shaft, and a hexagonal groove used for the insertion of the hexagonal block is formed in the rotating shaft.

Through adopting above-mentioned technical scheme, when installing or dismantling ceramic tile body, insert hexagonal groove with the hexagonal spanner, help the staff to rotate locking gear through the rotation axis. After tile body installed on fossil fragments, shielded the clearance between two tile body through the sealing strip to insert the hexagonal groove with the hexagonal piece, thereby through rotation axis restriction locking gear revolve, further improved tile body and installed the stability after to fossil fragments.

Optionally, the hexagonal block has elasticity, and a sectional area of the hexagonal block is slightly larger than a sectional area of the hexagonal groove.

Through adopting above-mentioned technical scheme, during the installation sealing strip, rotate the rotation axis earlier so that locking tooth strip inserts locking groove, touching piece and feedback piece conflict, then insert the hexagonal piece hexagonal groove again, the hexagonal piece takes place to deform and supports the cell wall in tight hexagonal groove in-process that inserts the hexagonal groove to the effect of connecting sealing strip and rotation axis has been played. Through the structural installation sealing strip, the structure is simple and convenient, and the simplicity of the worker for dismounting the tile body is further improved.

Optionally, a water blocking groove is formed in the sealing strip, a water blocking block is arranged on the sealing strip, the water blocking block and the water blocking groove are respectively located at two ends of the sealing strip, and when the sealing strip is installed on the keel, one of the water blocking blocks on the sealing strip is inserted into the water blocking groove of the adjacent sealing strip.

Through adopting above-mentioned technical scheme, when installing the sealing strip to the fossil fragments, the piece that blocks water on one of them sealing strip is inserted and is established in the water blocking groove on another block water piece. The water blocking block and the water blocking groove enable rainwater to be difficult to enter a gap between the two sealing strips, and the waterproof protection effect on the external vertical face is further improved.

Optionally, an extension strip is arranged on the side wall, close to the tile body, of the sealing strip.

By adopting the technical scheme, after the sealing strip is installed, the extension strip shields the gap between the sealing strip and the tile body, and the waterproof protection effect on the outer vertical surface is further improved.

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

when the ceramic tile body is installed, the keel is fixed on the outer vertical surface, the inner plate is inserted into the connecting hole, and then the locking gear is rotated to drive the locking rack to be inserted into the locking groove, so that the ceramic tile body is fixed on the outer vertical surface; when the tile body is damaged and needs to be replaced, the locking gear is rotated to drive the rack to move out of the locking groove, and the tile body can be taken down from the keel; through adopting above-mentioned structure, dismouting ceramic tile body only need rotate the locking gear can, the staff of being convenient for dismantles the ceramic tile.

When the tile body is disassembled, the locking gear is firstly rotated to drive the locking rack to move out of the locking groove and the limiting rack to extend into the abdicating groove, so that even if the tile body is disassembled, the limiting rack also plays a role of blocking, the heat-insulating pad is limited from being separated from the connecting hole, a worker does not need to support the heat-insulating pad, the worker is facilitated to carry a new tile body, and the simplicity of disassembling and assembling the tile by the worker is further improved;

the hexagonal block not only plays a role in connecting the sealing strip with the rotating shaft, but also limits the rotation of the rotating shaft, so that the stability of the tile body after being installed on the keel is improved.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a schematic diagram of an explosive structure according to an embodiment of the present application.

Fig. 3 is a partial structural schematic diagram for highlighting a gear groove in the embodiment of the present application.

Fig. 4 is an enlarged schematic view at a in fig. 3.

FIG. 5 is a partial schematic view showing a locking groove and a relieving groove.

Fig. 6 is an enlarged schematic view at B in fig. 2.

Description of the reference numerals:

1. a keel; 11. a cross beam; 12. a stringer; 121. a first sliding groove; 122. a second sliding groove; 123. a rotating tank; 124. a first rack slot; 125. a second rack groove; 13. connecting holes; 14. a heat-insulating pad; 2. a tile body; 21. an inner plate; 211. a locking groove; 212. a yielding groove; 3. a connecting mechanism; 31. a rotating shaft; 311. a hexagonal groove; 32. locking the gear; 321. a toothed portion; 322. no tooth part; 333. a feedback block; 334. a touch block; 33. locking the rack; 34. a limiting rack; 35. a locking block; 36. a limiting block; 4. a sealing strip; 41. an elongate strip; 42. a water blocking tank; 43. a water blocking block; 44. a hexagonal block.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses an assembly type building structure. Referring to fig. 1 and 2, the prefabricated building structure includes a keel 1 for being fixed on an external vertical surface, a plurality of tile bodies 2, a plurality of sets of connecting mechanisms 3 provided on the keel 1, and a plurality of sealing strips 4 provided on the keel 1.

Referring to fig. 2 and 3, the keel 1 includes a plurality of cross beams 11 and a plurality of longitudinal beams 12, the cross beams 11 and the longitudinal beams 12 are arranged in a cross shape to form a plurality of connecting holes 13, and the cross beams 11 and the longitudinal beams 12 are welded and fixed. Each cross beam 11 extends in the horizontal direction and each longitudinal beam 12 extends in the vertical direction. The connecting hole 13 is internally provided with a heat insulation pad 14, and the heat insulation pad 14 is a rock wool heat insulation board so as to play a heat insulation role for the building.

Referring to fig. 3 and 4, the connecting mechanism 3 is disposed on the side member 12, and the connecting mechanism 3 includes a rotating shaft 31, a locking gear 32, a locking rack 33, a stopper rack 34, a locking block 35, and a stopper 36. The end surface of the longitudinal beam 12 close to the connecting hole 13 is provided with a first sliding groove 121 and a second sliding groove 122, and the extending directions of the first sliding groove 121 and the second sliding groove 122 are both perpendicular to the extending direction of the connecting hole 13. The end surface of the longitudinal beam 12 away from the outer vertical surface is provided with a rotating groove 123, and the first sliding groove 121 and the second sliding groove 122 are respectively located on the upper side and the lower side of the rotating groove 123 in the vertical direction. A first rack groove 124 communicated with the rotating groove 123 is formed on a groove wall of the first sliding groove 121 close to the rotating groove 123, and a second rack groove 125 communicated with the rotating groove 123 is formed on a groove wall of the second sliding groove 122 close to the rotating groove 123.

Referring to fig. 4, the rotating shaft 31 and the locking gear 32 are both disposed in the rotating groove 123, the rotating shaft 31 is rotatably connected to a groove wall of the rotating groove 123, and the locking gear 32 is fixed to the rotating shaft 31 in a sleeved manner. The locking gear 32 is divided into a toothed portion 321 and a non-toothed portion 322 along the circumferential direction, gear teeth are uniformly distributed on the circumferential side wall of the toothed portion 321, and the circumferential side wall of the non-toothed portion 322 is smooth.

Referring to fig. 4, the first rack slot 124 has a slot width smaller than that of the first sliding slot 121, and the second rack slot 125 has a slot width smaller than that of the second sliding slot 122. The locking rack 33 is slidably disposed in the first rack slot 124, and the locking rack 33 is configured to engage with the toothed portion 321. The locking block 35 is slidably disposed in the first sliding groove 121, and the locking block 35 is fixedly connected to the locking rack 33. The limit rack 34 is slidably disposed in the second rack groove 125, and the limit rack 34 is configured to engage with the toothed portion 321. The limiting block 36 is slidably disposed in the second sliding groove 122, and the limiting block 36 is fixedly connected with the limiting rack 34. When the toothed portion 321 is engaged with the lock rack 33, the stopper rack 34 is offset from the toothed portion 321.

Referring to fig. 4 and 5, an inner plate 21 is fixedly connected to a side wall of the tile body 2, a sectional area of the tile body 2 is larger than a sectional area of the inner plate 21, and the connecting hole 13 is used for the inner plate 21 to be inserted. The two opposite side walls of the inner plate 21 are both provided with locking grooves 211. One of the locking grooves 211 is located at the top end of the sidewall of the inner plate 21, and the other locking groove 211 is located at the bottom end of the sidewall of the inner plate 21. The locking groove 211 is for inserting the end of the locking block 35 and the locking rack 33.

Referring to fig. 4 and 5, two yielding grooves 212 are formed in the side wall of the inner plate 21 away from the tile body 2, one of the yielding grooves 212 is communicated with one side wall of the inner plate 21 having the locking groove 211, and the other yielding groove 212 is communicated with the other side wall of the inner plate 21 having the locking groove 211. The avoiding groove 212 is used for inserting the end parts of the limiting rack 34 and the limiting block 36.

Referring to fig. 3 and 5, the extending directions of the locking groove 211 and the relief groove 212 are perpendicular to the extending direction of the connecting hole 13.

Referring to fig. 4 and 5, the toothed portion 321 is eccentrically provided with a feedback block 333, and the feedback block 333 is fixedly connected to the toothed portion 321. A touch pad 334 is fixed to a wall of the rotation groove 123, and an end of the touch pad 334 is positioned on a rotation path of the feedback pad 333. When the touch block 334 collides with one side wall of the feedback block 333, the locking block 35 and the locking rack 33 extend into the locking groove 211; when the touch block 334 is abutted against the other side wall of the feedback block 333, the limit block 36 and the limit rack 34 extend into the receding groove 212.

Referring to fig. 1 and 6, each sealing strip 4 is arranged on the longitudinal beam 12, the sealing strips 4 are rubber strips with elasticity, the sealing strips 4 are located between two adjacent tile bodies 2 in the horizontal direction, and the sealing strips 4 are used for being embedded between two adjacent tiles. The sealing strip 4 has the extension strip 41 towards the homogeneous shaping on the lateral wall of two adjacent ceramic tile body 2 on the horizontal direction, has seted up on the roof of sealing strip 4 and has blocked water groove 42, and integrated into one piece has the piece 43 that blocks water on the diapire of sealing strip 4. When the seal strips 4 are mounted to the stringers 12, the water blocking block 43 on one of the seal strips 4 is inserted in the water blocking groove 42 of the adjacent seal strip 4.

Referring to fig. 3 and 6, two hexagonal blocks 44 are integrally formed on the side wall of the sealing strip 4 close to the longitudinal beam 12, a hexagonal groove 311 for embedding the hexagonal block 44 is formed on the side wall of the rotating shaft 31 far from the outer vertical surface, and the sectional area of the hexagonal block 44 is slightly larger than that of the hexagonal groove 311.

The implementation principle of an assembly type building structure of the embodiment of the application is as follows: replacing a damaged tile body 2 comprises the steps of:

the first step is as follows: the two sealing strips 4 adjacent to the damaged tile body 2 are removed.

The second step is that: the rotating shaft 31 is rotated by a hexagon wrench, the rotating shaft 31 drives the locking gear 32 to rotate, the toothed portion 321 is firstly meshed with the locking rack 33 and then meshed with the limiting rack 34, so that the locking rack 33 and the locking block 35 are driven to move out of the locking groove 211, the limiting rack 34 and the limiting block 36 to be inserted into the abdicating groove 212 until the feedback block 333 is abutted against the touch block 334 to limit the rotation of the locking gear 32.

The third step: the damaged tile body 2 is taken down and a new tile body 2 is taken out first, the inner plate 21 of the new tile body 2 is inserted into the connecting hole 13, then the rotating shaft 31 is rotated reversely by the hexagonal wrench to drive the locking gear 32 to rotate, so that the limiting rack 34 and the limiting block 36 are moved out of the abdicating groove 212, the locking rack 33 and the locking block 35 to be inserted into the locking groove 211, and the feedback block 333 is abutted against the touch block 334 to limit the rotation of the locking gear 32.

The fourth step: the sealing strip 4 is inserted into the gap between two adjacent tile bodies 2, and the hexagonal block 44 is embedded into the hexagonal groove 311 until the extension strip 41 is abutted against the tile bodies 2.

When the heat insulation pad 14 is installed, the rotating shaft 31 can be rotated by a hexagonal wrench, so as to drive the locking gear 32 to rotate, so that the locking block 35 moves into the first sliding groove 121, the locking rack 33 moves into the first rack groove 124, the limiting block 36 moves into the second limiting groove, and the limiting rack 34 moves into the second rack groove 125, which is helpful for workers to install the heat insulation pad 14.

Through the structure, only need take off sealing strip 4 and rotate rotation axis 31 during dismouting ceramic tile body 2 can, easy and simple to handle, the staff of being convenient for dismantles the ceramic tile.

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

Claims

1. A fabricated building structure, characterized by: the ceramic tile fixing structure comprises a plurality of ceramic tile bodies (2), keels (1) used for being connected to an outer vertical surface and a plurality of groups of connecting mechanisms (3) arranged on the keels (1), wherein inner plates (21) are connected to the ceramic tile bodies (2), the keels (1) are provided with a plurality of connecting holes (13) used for inserting the inner plates (21), each connecting mechanism (3) comprises a locking gear (32) rotatably connected to the keels (1) and a locking rack (33) slidably arranged on the keels (1), the sliding direction of the locking rack (33) is perpendicular to the extending direction of the connecting holes (13), the locking rack (33) is meshed with the locking gear (32), and the side wall of each inner plate (21) is provided with a locking groove (211) used for inserting the end part of the locking rack (33);

the ceramic tile connecting mechanism is characterized by further comprising a heat insulation pad (14) arranged in the connecting hole (13), the connecting mechanism (3) further comprises a limiting rack (34) arranged on the keel (1) in a sliding mode, the sliding direction of the limiting rack (34) is perpendicular to the extending direction of the connecting hole (13), the limiting rack (34) is meshed with one side, away from the locking rack (33), of the locking gear (32), the inner plate (21) is far away from the end face of the ceramic tile body (2), a yielding groove (212) used for inserting the limiting rack (34) is formed in the end face of the inner plate (21), and the yielding groove (212) is communicated with the side wall of the inner plate (21);

the eccentric feedback piece (333) that is provided with on locking gear (32), be provided with touch piece (334) on fossil fragments (1), the tip of touch piece (334) is located the rotation route of feedback portion, when touch piece (334) contradicts with one of them side wall of feedback piece (333), locking rack (33) stretch into locking groove (211), when touch piece (334) contradicts with the opposite side wall of feedback piece (333), spacing rack (34) stretch into in the groove of stepping down (212).

2. A fabricated building structure according to claim 1, wherein: locking gear (32) are divided into along circumference and have tooth portion (321) and no tooth portion (322), be equipped with the teeth of a cogwheel on the circumference lateral wall that has tooth portion (321), the circumference lateral wall of no tooth portion (322) is smooth, have tooth portion (321) be used for with locking rack (33) or spacing rack (34) meshing.

3. A fabricated building structure according to claim 1, wherein: be provided with many sealing strips (4) on fossil fragments (1), sealing strip (4) are located between two adjacent ceramic tile body (2).

4. A fabricated building structure according to claim 3, wherein: be provided with hexagonal piece (44) on sealing strip (4), it is connected with rotation axis (31) to rotate on fossil fragments (1), locking gear (32) are fixed on rotation axis (31), offer on rotation axis (31) and be used for supplying hexagonal piece (44) to insert hexagonal groove (311) of establishing.

5. A fabricated building structure according to claim 4, wherein: the hexagonal block (44) has elasticity, and the sectional area of the hexagonal block (44) is slightly larger than that of the hexagonal groove (311).

6. A fabricated building structure according to claim 3, wherein: the sealing strip is characterized in that a water blocking groove (42) is formed in the sealing strip (4), water blocking blocks (43) are arranged on the sealing strip (4), the water blocking blocks (43) and the water blocking groove (42) are respectively located at two ends of the sealing strip (4), when the sealing strip (4) is installed on a keel (1), one of the water blocking blocks (43) on the sealing strip (4) is inserted into the water blocking groove (42) of the adjacent sealing strip (4).

7. A fabricated building structure according to claim 3, wherein: the side wall of the sealing strip (4) close to the tile body (2) is provided with an extending strip (41).