CN220433915U - Novel assembled building element and foundation connected node - Google Patents

Abstract

The utility model discloses a novel assembled building component and foundation connection node, which comprises a prefabricated outer foundation component, a prefabricated outer wallboard, a prefabricated outer floor slab, a prefabricated inner wallboard, a prefabricated inner foundation component and a prefabricated inner floor slab, wherein the prefabricated inner foundation component is provided with concave grooves, the prefabricated inner floor slab and the prefabricated outer floor slab are respectively provided with a convex block, the convex blocks are embedded into the concave grooves of the corresponding prefabricated inner foundation component, a clamping groove is formed between two opposite end surfaces of the embedded prefabricated inner floor slab and the prefabricated outer building, the prefabricated inner wallboard is inserted into the clamping groove, the bottom end surface of the prefabricated inner wallboard is placed on the platform surface of the prefabricated inner foundation component, and the prefabricated inner wallboard is clamped by the prefabricated inner floor slab and the prefabricated outer floor slab so as to control the transverse displacement of the prefabricated inner wallboard. The inner side of the prefabricated outer foundation member and the prefabricated outer floor slab can be connected in the same type, and the structure of the utility model is convenient to install and disassemble, so that the production efficiency is improved, and the construction period is effectively shortened.

Description

Novel assembled building element and foundation connected node

Technical Field

The utility model relates to the field of assembled buildings, in particular to a novel connecting node of an assembled building component and a foundation.

Background

Along with the continuous deep popularization of the building industrialization process, the assembled building is continuously popularized, and the assembled building is to replace the field operation work in the traditional construction mode by manufacturing components in factories, and mainly comprises a prefabricated assembled reinforced concrete structure, a modern wood structure, a steel structure building and the like, because the assembled building adopts standardized design and factory production, and is applied in assembled construction, information management and intelligence, the assembled building is a great trend of the development of the future building industry.

The key of the fabricated building is the assembled connection between the prefabricated components. At present, the components in the assembled building are mostly connected by grouting steel sleeves, and the mode is that the steel bars and the sleeves are connected by grouting, and the steel bars at the two ends of the sleeves are in friction and mechanical engagement with the steel bars and the sleeves through grouting materials to achieve the purpose of transmitting force. But the steel bar sleeve grouting process is complicated, and the steel bar sleeve grouting process cannot be conveniently and rapidly installed and disassembled.

Disclosure of Invention

Aiming at the problems, the utility model aims to provide a novel connecting node for an assembled building component and a foundation, and the connecting structure has the characteristics of convenient installation and disassembly and quickening the construction speed.

In order to achieve the above object, the technical scheme of the present utility model is as follows:

the utility model provides a novel assembled building element and basis connected node which characterized in that, including prefabricated outer foundation element, prefabricated side fascia, prefabricated outer floor, prefabricated interior wallboard, prefabricated interior foundation element, prefabricated interior floor.

The left and right sides of prefabricated interior foundation component is equipped with the concave groove respectively, places the cushion in the concave groove, and the floor all is equipped with the lug with the both ends of prefabricated interior floor, the floor left end lug with the concave groove looks adaptation in the prefabricated interior foundation component right side, the embedding of floor left end lug in the prefabricated interior foundation component right side concave groove, the outer floor right end lug of prefabrication with the concave groove looks adaptation in the foundation component left side in the prefabrication, the embedding of floor right end lug outside the prefabrication in the foundation component left side in, the floor right side terminal surface is higher than in the prefabrication in the floor left side after the embedding is higher than the foundation component platform face in the prefabrication, forms a draw-in groove between floor right side terminal surface in the prefabrication outside and the prefabrication, inserts prefabricated interior wallboard in the draw-in groove, its bottom terminal surface is placed on the foundation component platform face in the prefabrication, and the wallboard is passed through in the prefabrication outside floor and the prefabrication.

The bottom of prefabricated exterior wall panel sets up outside lug, prefabricated exterior foundation component outer end plane is higher than prefabricated exterior foundation component platform surface, and prefabricated exterior foundation component outer end side direction is provided with the concave groove with the right side, places the cushion in the concave groove, prefabricated exterior foundation component outer end side direction concave groove with the outside lug looks adaptation of prefabricated exterior wall panel bottom, prefabricated exterior foundation component right side concave groove and prefabricated exterior floor left end lug looks adaptation, with the outside lug embedding prefabricated exterior foundation component outer end side direction concave groove in of prefabricated exterior wall panel bottom, prefabricated exterior wall panel bottom terminal surface is placed on prefabricated exterior foundation component platform surface, prefabricated exterior floor left end lug embedding prefabricated exterior foundation component right side concave groove, prefabricated exterior wall panel passes through prefabricated exterior floor and prefabricated exterior foundation component control its horizontal displacement.

In the preferred embodiment of the utility model, the prefabricated external wall panel and the prefabricated internal wall panel are internally provided with cavities, and the cavities are internally filled with heat insulation materials.

The utility model has the beneficial effects that:

1. the prefabricated floor slab and the prefabricated foundation component are connected simply and conveniently, the protruding blocks arranged on the prefabricated floor slab are embedded into the corresponding concave grooves arranged on the prefabricated foundation component, and construction is rapid and convenient.

2. The prefabricated wallboard can be clamped by two transversely adjacent prefabricated floors to control the transverse displacement of the prefabricated wallboard, and the construction is fast and convenient.

3. The structure has the advantages of convenience in installation and disassembly, greatly improves the production efficiency, and effectively shortens the construction period.

The features of the present utility model will be apparent from the following detailed description of the preferred embodiments, taken in conjunction with the accompanying drawings.

Drawings

Fig. 1 is a schematic view of the joint connection of the assembled building.

Fig. 2 is a top view of a prefabricated exterior wall panel.

Fig. 3 is a top view of a prefabricated interior wall panel.

Fig. 4 is a schematic illustration of the connection of the prefabricated outer foundation element to the prefabricated outer wall panel and the prefabricated outer floor panel.

Fig. 5 is a schematic illustration of the connection of the prefabricated interior foundation elements to the prefabricated interior wall panels and to the prefabricated interior and exterior floor panels.

Wherein 1 is a prefabricated outer foundation member, 2 is a prefabricated outer wall plate, 3 is a prefabricated outer floor plate, 4 is a prefabricated inner wall plate, 5 is a prefabricated inner foundation member, 6 is a prefabricated inner floor plate, 1-1 is a prefabricated outer foundation member outer end lateral concave groove, 1-2 is a prefabricated inner wall plate bottom end surface, 1-3 is a prefabricated outer foundation member outer end plane, 1-4 is a prefabricated outer foundation member flat surface, 2-1 is a prefabricated outer wall plate bottom end outward convex block, 2-2 is a prefabricated outer wall plate cavity, 2-3 is a prefabricated outer wall plate bottom end surface, 3-1 is a prefabricated outer floor plate left end convex block, 3-2 is a prefabricated outer floor plate right end convex block, 3-3 is a prefabricated outer floor plate left side end surface, 3-4 is a prefabricated outer floor plate right side end surface, 4-1 is a prefabricated inner wall plate cavity, 4-2 is a prefabricated inner wall plate bottom end surface, 5-1 is a prefabricated inner foundation member left side concave groove, 5-2 is a prefabricated inner foundation member right side concave groove, 5-3 is a prefabricated inner foundation member flat surface, 6-1 is a prefabricated inner floor plate left end convex block, and 6-2 is prefabricated inner floor plate left end surface.

Detailed Description

The technical scheme of the present utility model will be described below with reference to the accompanying drawings. It will be apparent that the described embodiments are only some, but not all, of the implementations of the present application; and the structures shown in the drawings are merely schematic and do not represent a physical object. It is intended that all other embodiments obtained by those skilled in the art based on these embodiments of the present utility model fall within the scope of the present application.

It is noted that the term "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other identical or equivalent elements in a process, method, article, or apparatus that comprises the element.

The terms "upper", "lower", "inner", "outer", and the like do not constitute absolute spatial relationship limitations, but rather are a concept of relative position. As will be appreciated by those skilled in the art.

Referring to fig. 1, a schematic view of the joint connection of the whole assembled building is shown. The prefabricated building mainly comprises a prefabricated outer foundation member 1, a prefabricated outer wallboard 2, a prefabricated outer floor slab 3, a prefabricated inner wallboard 4, a prefabricated inner foundation member 5 and a prefabricated inner floor slab 6; part of the detailed description is as follows:

referring to fig. 2 and 3, the bottom end of the prefabricated external wall panel 2 is provided with an outward bump 2-1 at the bottom end of the prefabricated external wall panel, and a prefabricated external wall panel cavity 2-2 is arranged inside the prefabricated external wall panel 2. The prefabricated inner wallboard 4 is internally provided with a prefabricated inner wallboard cavity 4-1. The heat insulation material can be filled in the cavity, the weight of the wall body can be reduced, the cost is effectively reduced, and the construction difficulty of hoisting and installation is reduced.

Referring to fig. 4, concave grooves are formed in the lateral direction and the right side of the outer end of the prefabricated outer foundation member 1, and are respectively a lateral concave groove 1-1 of the outer end of the prefabricated outer foundation member, a right side concave groove 1-2 of the prefabricated outer foundation member, and an outer end plane 1-3 of the prefabricated outer foundation member is higher than a plane surface 1-4 of the prefabricated outer foundation member. The outer protruding block is arranged at the bottom end of the prefabricated outer wall plate 2 and is the outer protruding block 2-1 at the bottom end of the prefabricated outer wall plate, the lateral concave groove 1-1 at the outer end of the prefabricated outer base member is matched with the outer protruding block 2-1 at the bottom end of the prefabricated outer wall plate, the outer protruding block 2-1 at the bottom end of the prefabricated outer wall plate is embedded into the lateral concave groove 1-1 at the outer end of the prefabricated outer base member, the end face 2-3 at the bottom of the prefabricated outer wall plate is placed on the flat table surface 1-4 of the prefabricated outer base member, and the installation is very convenient. The left side of the prefabricated outer floor slab 3 is provided with a prefabricated outer floor slab left end lug 3-1, the size and shape of the wedge-shaped surface of the prefabricated outer floor slab left end lug 3-1 are matched with those of the wedge-shaped surface of the prefabricated outer foundation member right side concave groove 1-2, a cushion block is placed in the prefabricated outer foundation member right side concave groove 1-2, the prefabricated outer floor slab left end lug 3-1 is embedded into the prefabricated outer foundation member right side concave groove 1-2, after the prefabricated outer floor slab left end surface 3-3 is higher than the prefabricated outer wall plate bottom end surface 2-3, the prefabricated outer floor slab 3 and the prefabricated outer foundation member 1 clamp the prefabricated outer wall plate 2, and the transverse displacement of the prefabricated outer wall plate 2 can be effectively controlled.

Referring to fig. 5, concave grooves are provided at left and right sides of the prefabricated inner base member 5, respectively, a left concave groove 5-1 of the prefabricated inner base member, a right concave groove 5-2 of the prefabricated inner base member, a right side of the prefabricated outer floor 3 is provided with a right convex block 3-2 of the prefabricated outer floor, a wedge surface of the right convex block 3-2 of the prefabricated outer floor is adapted to a wedge surface of the left concave groove 5-1 of the prefabricated inner base member, a left convex block 6-1 of the prefabricated inner floor is provided at the left side of the prefabricated inner floor 6, a wedge surface of the left convex block 6-1 of the prefabricated inner floor is adapted to a wedge surface of the right concave groove 5-2 of the prefabricated inner base member, a cushion block is placed in the left concave groove 5-1 of the prefabricated inner base member and the right concave groove 5-2 of the prefabricated inner base member, the right end protruding block 3-2 of the prefabricated outer floor slab is embedded into the left concave groove 5-1 of the prefabricated inner foundation component, the left end protruding block 6-1 of the prefabricated inner floor slab is embedded into the right concave groove 5-2 of the prefabricated inner foundation component, after the embedding, the right end face 3-4 of the prefabricated outer floor slab and the left end face 6-2 of the prefabricated inner floor slab form a clamping groove, the bottom end face 4-2 of the prefabricated inner wall slab is placed on the platform face 5-3 of the prefabricated inner foundation component, after the placing is finished, the right end face 3-4 of the prefabricated outer floor slab and the left end face 6-2 of the prefabricated inner floor slab are higher than the bottom end face 4-2 of the prefabricated inner wall slab, and the transverse displacement of the prefabricated inner wall slab 4 can be controlled through the prefabricated outer floor slab 3 and the prefabricated inner floor slab 6.

Compared with the traditional construction mode requiring site construction pouring, the method does not need site construction operation, can finish the manufacture of the components in a factory, and has high component standardization degree and high construction speed.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides a novel assembled building element and basis connected node, includes prefabricated outer foundation element, prefabricated side fascia, prefabricated outer floor, prefabricated interior wallboard, prefabricated interior foundation element, prefabricated interior floor, its characterized in that;

the left and right sides of the prefabricated inner foundation component are respectively provided with concave grooves, the two ends of the prefabricated inner floor slab and the prefabricated outer floor slab are respectively provided with convex blocks, the left end convex blocks of the prefabricated inner floor slab are matched with the right concave grooves of the prefabricated inner foundation component, the left end convex blocks of the prefabricated inner floor slab are embedded into the right concave grooves of the prefabricated inner foundation component, the right end convex blocks of the prefabricated outer floor slab are embedded into the left concave grooves of the prefabricated inner foundation component, the right end face of the embedded prefabricated outer floor slab and the left end face of the prefabricated inner floor slab are higher than the plane surface of the prefabricated inner foundation component, a clamping groove is formed between the right end face of the prefabricated outer floor slab and the left end face of the prefabricated inner floor slab, the prefabricated inner wall slab is inserted into the clamping groove, and the bottom end face of the prefabricated inner wall slab is placed on the plane surface of the prefabricated inner foundation component.

2. The novel prefabricated building component and foundation connection node according to claim 1, wherein the bottom end of the prefabricated external wall panel is provided with an outward convex block, the outer end plane of the prefabricated external base component is higher than the plane surface of the prefabricated external base component, the outer side direction and the right side of the prefabricated external base component are provided with concave grooves, the outer side direction concave grooves of the prefabricated external base component are matched with the outward convex blocks at the bottom end of the prefabricated external wall panel, the right side concave grooves of the prefabricated external base component are matched with the left side convex blocks of the prefabricated external floor slab, the outward convex blocks at the bottom end of the prefabricated external wall panel are embedded into the outer side direction concave grooves of the prefabricated external base component, the bottom end surface of the prefabricated external wall panel is placed on the plane surface of the prefabricated external base component, and the left side convex blocks of the prefabricated external floor slab are embedded into the right side concave grooves of the prefabricated external base component.

3. The novel prefabricated building element and foundation connection node according to claim 1, wherein cavities are formed in the prefabricated inner wall panels and the prefabricated outer wall panels.

4. The novel prefabricated building component and foundation connection node according to claim 1, wherein the cushion block is placed in the concave groove.