CN219060360U - Assembled building beam slab - Google Patents

Abstract

The application provides an assembled building beam slab, which comprises a connecting block, the slot has been seted up on the connecting block, swing joint has the inserted block in the slot, be connected with the beam slab body on the inserted block, beam slab body offsets with the connecting block activity, be provided with the positioning mechanism that is used for fixed inserted block in the connecting block, still be provided with the bracing mechanism that is used for supporting the beam slab body in the connecting block, bracing mechanism links to each other with positioning mechanism, still set up the passageway of pouring that is used for pouring concrete on the connecting block, pour passageway and slot intercommunication each other. This application simple structure is convenient for accelerate the installation rate of beam slab, improves the stability of beam slab installation, and then improves the efficiency of construction and the construction effect of staff to the building.

Description

Assembled building beam slab

Technical Field

The utility model relates to the technical field of assembled buildings, in particular to an assembled building beam slab.

Background

The assembled beam plate structure fully embodies the advantages of light dead weight, good earthquake resistance, short construction period and high benefit, has the characteristics of integration, industrialization and standardization, can realize the aim of high quality and low pollution of the building through fine manufacturing, on-site high-quality installation and construction informatization management of factories, accords with the sustainable development concept, and is a green building system adapting to the development trend of the building, and has great potential in the future building market due to the advantages of the assembled beam plate structure.

The Chinese patent with the patent number of CN202120802544.5 discloses an assembled beam plate connecting structure, which reduces the transverse stretching damage of the beam plate by arranging a supporting device and a pressing fixing component. But in the specific construction use, this structure is comparatively complicated for the installation step of beam slab is comparatively loaded down with trivial details, and stability is relatively poor, influences the staff to the efficiency of construction of building, can not satisfy people's user demand.

Therefore, the improvement is made by us, and an assembled building beam slab is provided.

Disclosure of Invention

The utility model aims at: the problems of low construction efficiency and poor construction stability of the existing beam plate installation are solved.

In order to achieve the above object, the present utility model provides the following technical solutions:

an assembled building beam slab to ameliorate the above problems.

The application is specifically such that:

the connecting block is internally provided with a diagonal bracing mechanism used for supporting the beam plate body, the diagonal bracing mechanism is connected with the positioning mechanism, a pouring channel used for pouring concrete is further formed in the connecting block, and the pouring channel is mutually communicated with the slot.

As the preferred technical scheme of this application, positioning mechanism includes the screw thread setting first screw rod on the connecting block, the end connection of first screw rod has the knob, set up on the inserted block with first screw rod matched with screw.

As the preferred technical scheme of this application, bracing mechanism is including rotating the second screw rod that sets up on the connecting block, the screw thread is provided with the sleeve on the second screw rod, it is provided with the connecting rod to rotate on the sleeve, telescopic one end swing joint has the fagging to keep away from the connecting rod, fagging offsets with the beam slab body activity, the fagging slides and sets up in the connecting block.

As the preferred technical scheme of this application, set firmly driven gear on the second screw rod, sliding connection has the driving gear who is connected with driven gear meshing on the first screw rod, be provided with the gib block on the driving gear, set up on the first screw rod with gib block matched with guide way.

As the preferable technical scheme of this application, pour the passageway and pour mouthful including the toper and be used for the intercommunication toper to pour mouthful and the circulation groove of slot.

As the preferred technical scheme of this application, the sand grip of the outside evenly distributed of inserted block, the one end and the slot inner wall activity of inserted block are kept away from to the sand grip offset.

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

in the scheme of the application:

1. the positioning mechanism is matched with the diagonal bracing mechanism, so that the beam plate body is quickly installed, the beam plate installation rate is accelerated, the beam plate installation stability is improved, and the construction efficiency and the construction effect of workers on a building are improved;

2. through pouring the concrete in pouring the passageway, make the concrete get into the slot and carry out the secondary fixedly to the inserted block and the connecting block, and then realize the fixed of being connected of beam slab body and connecting block, and be provided with evenly distributed's sand grip on the inserted block, can improve the frictional force between inserted block and the concrete, avoid the inserted block not hard up, improve the stability that beam slab body and connecting block are connected.

Drawings

FIG. 1 is a schematic structural diagram provided herein;

FIG. 2 is a schematic cross-sectional view of the present application;

FIG. 3 is an enlarged schematic view of part A of FIG. 2 provided herein;

fig. 4 is a schematic view of the external structure of the plug provided in the present application.

The figures indicate:

1. a connecting block; 2. a slot; 3. inserting blocks; 301. a screw hole; 4. a beam plate body; 5. a positioning mechanism; 501. a first screw; 502. a knob; 503. a drive gear; 5031. a guide bar; 504. a guide groove; 6. a diagonal bracing mechanism; 601. a second screw; 602. a sleeve; 603. a connecting rod; 604. a supporting plate; 605. a driven gear; 7. pouring the channel; 701. a conical pouring port; 702. a flow channel; 8. a convex strip.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model.

Thus, the following detailed description of the embodiments of the utility model is not intended to limit the scope of the utility model, as claimed, but is merely representative of some embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, under the condition of no conflict, the embodiments of the present utility model and the features and technical solutions in the embodiments may be combined with each other.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

As shown in fig. 1, fig. 2, fig. 3 and fig. 4, this embodiment provides an assembled building beam slab, including connecting block 1, slot 2 has been seted up on the connecting block 1, swing joint has inserted block 3 in the slot 2, be connected with beam slab body 4 on the inserted block 3, beam slab body 4 offsets with the connecting block 1 activity, be provided with the positioning mechanism 5 that is used for fixed inserted block 3 in the connecting block 1, still be provided with in the connecting block 1 and be used for supporting beam slab body 4's diagonal bracing mechanism 6, diagonal bracing mechanism 6 links to each other with positioning mechanism 5, still set up the pouring passageway 7 that is used for pouring concrete on the connecting block 1, pouring passageway 7 communicates each other with slot 2.

Specifically, during beam slab installation, make the inserted block 3 on the beam slab body 4 insert in the slot 2 on the connecting block 1, later through driving positioning mechanism 5 action, make positioning mechanism 5 fix a position the inserted block 3, and when positioning mechanism 5 action, diagonal bracing mechanism 6 synchronous motion carries out the inclined support to the bottom of beam slab body 4, finally through pouring concrete into in the passageway 7, realize that the inserted block 3 is fixed again with connecting block 1, this application simple structure, the installation rate of beam slab is convenient for accelerate, the stability of beam slab installation is improved, and then the improvement staff is to the efficiency of construction and the construction effect of building.

As shown in fig. 1, 2, 3 and 4, as a preferred embodiment, based on the above manner, the positioning mechanism 5 further includes a first screw 501 screwed on the connection block 1, a knob 502 is connected to an end of the first screw 501, and a screw hole 301 matched with the first screw 501 is formed in the insert block 3; through rotating knob 502, make knob 502 drive first screw rod 501 and rotate, because first screw rod 501 and connecting block 1 screw thread setting, make first screw rod 501 remove relatively connecting block 1, make in the screw 301 of first screw rod 501 screw in inserted block 3, realize the preliminary fixed of inserted block 3 and connecting block 1.

As shown in fig. 2 and 3, as a preferred embodiment, further, the diagonal bracing mechanism 6 comprises a second screw 601 rotatably arranged on the connecting block 1, a sleeve 602 is arranged on the second screw 601 in a threaded manner, a connecting rod 603 is rotatably arranged on the sleeve 602, one end of the connecting rod 603 away from the sleeve 602 is movably connected with a supporting plate 604, the supporting plate 604 is movably abutted against the beam plate body 4, and the supporting plate 604 is slidably arranged in the connecting block 1; specifically, by rotating the second screw 601, the sleeve 602 on the second screw 601 moves, and when the sleeve 602 moves, the connecting rod 603 is driven to move, so that the connecting rod 603 drives the supporting plate 604 to slide in the connecting block 1, and the supporting plate 604 supports the bottom of the beam plate body 4.

As shown in fig. 2 and 3, in the above-mentioned preferred embodiment, further, a driven gear 605 is fixed on the second screw 601, a driving gear 503 engaged with the driven gear 605 is slidingly connected to the first screw 501, a guide bar 5031 is provided on the driving gear 503, and a guide groove 504 matched with the guide bar 5031 is provided on the first screw 501; specifically, when the first screw 501 rotates, the driving gear 503 is driven to rotate by the guide bar 5031, so that the driving gear 503 is meshed with the driven gear 605 on the second screw 601, the second screw 601 rotates, and the diagonal bracing mechanism 6 is further operated.

As shown in fig. 1 and 2, as a preferred embodiment, further, the pouring channel 7 includes a tapered pouring port 701 and a flow channel 702 for communicating the tapered pouring port 701 with the slot 2; specifically, the setting of toper pouring mouth 701 is convenient for the pouring of concrete, and the concrete gets into and gets into inside slot 2 through the circulation groove 702 from toper pouring mouth 701, fixes inserted block 3 and connecting block 1.

As shown in fig. 1 and fig. 4, as a preferred embodiment, further, on the basis of the above manner, the convex strips 8 are uniformly distributed on the outer side of the insert block 3, and one end of the convex strip 8 away from the insert block 3 is movably abutted against the inner wall of the slot 2; specifically, the setting of sand grip 8 can improve the frictional force between inserted block 3 and the concrete, avoids inserted block 3 not hard up, improves the stability that beam slab body 4 and connecting block 1 are connected, and sand grip 8 interval sets up, and the circulation of concrete in slot 2 of being convenient for makes the concrete fill in the space between inserted block 3 and the slot 2, improves stability.

Specifically, this assembled building beam slab is during operation/during the use: when the beam slab is installed, the insert block 3 on the beam slab body 4 is inserted into the slot 2 on the connecting block 1, then the positioning mechanism 5 is driven to act, the knob 502 is rotated, the knob 502 drives the first screw 501 to rotate, the first screw 501 is arranged in the connecting block 1 in a threaded manner, the first screw 501 moves relative to the connecting block 1, the first screw 501 is screwed into the screw hole 301 of the insert block 3, preliminary fixing of the insert block 3 and the connecting block 1 is achieved, the driving gear 503 is driven to rotate through the guide bar 5031 when the first screw 501 rotates, the driving gear 503 is meshed with the driven gear 605 on the second screw 601, the second screw 601 rotates, the diagonal bracing mechanism 6 is further driven to act, the sleeve 602 on the second screw 601 is driven to move, the connecting rod 603 is driven to move when the sleeve 602 moves, the connecting rod 603 drives the supporting plate 604 to slide in the connecting block 1, the supporting plate 604 supports the bottom of the beam slab body 4, finally concrete is poured into the slot 701 from the conical opening and enters the slot 2 through the pouring channel 7, the concrete is fixed to the insert block 3 and the insert block 1 through the circulation slot 702, the setting of the insert block 3 and the connecting block 3 can be fixed, and the loose stability of the connecting block 1 is avoided, and the connection between the insert block 3 and the insert block 1 is improved. This application simple structure is convenient for accelerate the installation rate of beam slab, improves the stability of beam slab installation, and then improves the efficiency of construction and the construction effect of staff to the building.

All technical features in the embodiment can be freely combined according to actual needs.

The foregoing embodiments are preferred embodiments of the present utility model, and in addition, the present utility model may be implemented in other ways, and any obvious substitution is within the scope of the present utility model without departing from the concept of the present utility model.

Claims (6)

1. The utility model provides an assembled building beam slab, includes connecting block (1), its characterized in that, slot (2) have been seted up on connecting block (1), swing joint has inserted block (3) in slot (2), be connected with beam slab body (4) on inserted block (3), beam slab body (4) offset with connecting block (1) activity, be provided with in connecting block (1) and be used for fixed positioning mechanism (5) of inserted block (3), still be provided with in connecting block (1) diagonal bracing mechanism (6) that are used for supporting beam slab body (4), diagonal bracing mechanism (6) link to each other with positioning mechanism (5), still set up on connecting block (1) and be used for pouring passageway (7) of concrete, pour passageway (7) and slot (2) intercommunication each other.

2. The assembled building beam plate according to claim 1, wherein the positioning mechanism (5) comprises a first screw rod (501) arranged on the connecting block (1) in a threaded mode, a knob (502) is connected to the end portion of the first screw rod (501), and a screw hole (301) matched with the first screw rod (501) is formed in the inserting block (3).

3. The assembled building beam plate according to claim 2, wherein the diagonal bracing mechanism (6) comprises a second screw rod (601) rotatably arranged on the connecting block (1), a sleeve (602) is arranged on the second screw rod (601) in a threaded mode, a connecting rod (603) is rotatably arranged on the sleeve (602), one end, far away from the sleeve (602), of the connecting rod (603) is movably connected with a supporting plate (604), the supporting plate (604) is movably abutted against the beam plate body (4), and the supporting plate (604) is slidably arranged in the connecting block (1).

4. The assembled building beam plate according to claim 3, wherein a driven gear (605) is fixedly arranged on the second screw (601), a driving gear (503) in meshed connection with the driven gear (605) is connected to the first screw (501) in a sliding manner, a guide strip (5031) is arranged on the driving gear (503), and a guide groove (504) matched with the guide strip (5031) is formed in the first screw (501).

5. A fabricated building beam panel according to claim 1, characterized in that the pouring channel (7) comprises a conical pouring opening (701) and a flow channel (702) for communicating the conical pouring opening (701) with the slot (2).

6. The assembled building beam plate according to claim 1, wherein the protruding strips (8) are uniformly distributed on the outer side of the insertion block (3), and one end, away from the insertion block (3), of each protruding strip (8) is movably abutted against the inner wall of the insertion groove (2).

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