CN117306763A - Dynamic deformation suspended ceiling method and suspended ceiling structure thereof - Google Patents

Abstract

The invention discloses a dynamic deformation suspended ceiling method and a suspended ceiling structure thereof, wherein the suspended ceiling method comprises the steps that two sides of a main keel are movably installed with two square ducts, and an auxiliary keel is connected with the square ducts through a telescopic structure to drive Fang Tongzuo to swing right; a plurality of deformable and bendable aluminum plate groups are movably arranged between the lower ends of the two square brackets, and the bottoms of the auxiliary keels are connected through a telescopic structure and drive the end parts of the aluminum plate groups to move up and down, so that the bending parts in the middle of the aluminum plate groups are bent; the square tube is provided with a second aluminum plate, three-dimensional decorations are arranged on the aluminum plate group and the second aluminum plate, and the decorations on the second aluminum plates on the two sides are matched with the decorations on the lower aluminum plate group to form a decoration structure which is arranged around the two sides and the bottom of the auxiliary keel; and driving the movement of the square tube and the aluminum plate group according to the gap of the telescopic structure or continuous telescopic driving, and realizing the deformation of the decorative structure so as to form the dynamic deformation of the suspended ceiling. The invention can freely adjust the working state of the telescopic structure, drives the surface of the suspended ceiling to stretch, bend and move, and further realizes the effect of dynamic deformation of the surface decoration structure of the suspended ceiling.

Description

Dynamic deformation suspended ceiling method and suspended ceiling structure thereof

Technical Field

The invention relates to the technical field of suspended ceiling structures, in particular to a dynamic deformation suspended ceiling method and a suspended ceiling structure thereof.

Background

In the present architectural design, as different types of buildings exist, the requirements of the structure or the design beauty of the buildings need to be met, and a plurality of suspended ceilings with special-shaped structures exist. But the design of building structure can not be completely adapted when the present common dysmorphism furred ceiling is installed, needs to additionally process the modification to the furred ceiling, and is inconvenient inadequately to current furred ceiling is fixed at the post-installation structure, can not warp the regulation, and the form is fixed and boring, and is not flexible enough. Therefore, it is necessary to provide a dynamic deformation suspended ceiling method and suspended ceiling structure which are convenient for adapting to different structures for installation, improve the construction efficiency and are more attractive.

Disclosure of Invention

The invention provides a dynamic deformation suspended ceiling method and a suspended ceiling structure thereof, which are used for solving the problems in the background technology.

In order to solve the problems, the invention adopts the following technical scheme:

a dynamic deformation suspended ceiling method comprises the following steps:

s1, two sides of a main keel are movably mounted with the upper ends of two square brackets respectively, and an auxiliary keel below the main keel is connected with the middle parts of the two square brackets through a telescopic structure to drive the square brackets to swing left and right by taking a connecting point connected with the main keel as a fulcrum and taking the inner sides of the two sides as an included angle;

s2, a plurality of deformable and bendable aluminum plate groups are movably arranged between the lower ends of the two square tubes, and the bottoms of the auxiliary keels are connected through a telescopic structure and drive the end parts of the aluminum plate groups to move up and down, so that the bending parts in the middle of the aluminum plate groups are bent;

s3, mounting a second aluminum plate on the square tube, and arranging three-dimensional decorations or pattern decorations on the aluminum plate group and the second aluminum plate group, wherein the decorations on the second aluminum plate group on two sides and the decorations on the aluminum plate group below are matched to form a decoration structure arranged around two sides and the bottom of the auxiliary keel;

s4, driving the square tubes and the aluminum plate groups to move according to the gaps of the telescopic structure or continuous telescopic driving, and realizing the deformation of the decorative structure so as to form the dynamic deformation of the suspended ceiling.

Preferably, the suspended ceiling structure for the dynamic deformation suspended ceiling method comprises a main keel and an auxiliary keel arranged below the main keel, wherein two square tubes are movably arranged on the left side and the right side of the bottom of the main keel, the two square tubes are far away from the end parts of the main keel and are connected with each other through a plurality of movable bending aluminum plate groups, the aluminum plate groups are arranged below the auxiliary keel, telescopic structures which are movably connected with the square tubes and the aluminum plate groups in one-to-one correspondence are respectively arranged on the two sides and the bottom of the auxiliary keel, the bending parts of the aluminum plate groups are connected with the telescopic ends of the telescopic structures, and the telescopic structures, the square tubes and the aluminum plate groups form a multi-fold-surface suspended ceiling structure capable of freely changing forms.

Preferably, each aluminum plate group comprises two aluminum plates I, hinges are arranged on two side edges of each aluminum plate I, and the two aluminum plates I of the same aluminum plate group are movably connected through the hinges. The included angle between the two aluminum plates can be freely adjusted through the hinge, so that the effect of movably bending the aluminum plate group is achieved.

Preferably, each telescopic structure comprises a first movable plate arranged on the auxiliary keel, the first movable plate is movably connected with the fixed end of an air cylinder through a rotating shaft, a second movable plate is arranged on the square tube, and the second movable plate is movably connected with the movable end of the air cylinder through the rotating shaft. The square tube is driven to swing through the operation of the air cylinder, and the first movable plate, the second movable plate and the rotating shaft enable connection points between all parts of the air cylinder to flexibly rotate when the air cylinder stretches out and stretches back, so that clamping is prevented. Each cylinder is connected with a controller respectively, and the effect of real-time adjustment cylinder expansion is realized through the controller.

Preferably, each aluminum plate group is movably connected with the movable end of the corresponding cylinder through a hinge on the aluminum plate I at two sides. The hinge is movably connected with the air cylinder, and when the air cylinder stretches out and draws back, the matching direction is opened inwards or outwards to swing, so that the aluminum plate group presents a planar or glass-shaped structure with multiple angles.

Preferably, the main joist is provided with a movable plate III corresponding to the upper end of each square tube, the upper end of each square tube is movably connected with the movable plate III through a rotating shaft, the side surface of each square tube facing outwards is provided with an aluminum plate II, and the lower end of each aluminum plate II is movably connected with a hinge at one end of an adjacent aluminum plate. The second aluminum plate is used for shielding the square tube and is connected with the first aluminum plate, so that the second aluminum plate and the first aluminum plate form a linkage effect when the square tube swings.

Preferably, an organ protection cover is arranged between the adjacent aluminum plate groups. Through the scalable beta structure of organ protection casing, can remain the effect that shields the gap all the time when aluminum plate group is in the state of plane or each angle buckling for the expansion end of protection cylinder prevents that the cylinder from exposing outside.

Preferably, the first aluminum plate can be an aluminum plate or a screen plate with hollowed patterns, and decorative structures are arranged on the opposite side surfaces of the first aluminum plate and the second aluminum plate and the opposite side surfaces of the auxiliary keels. The lighting effect is provided, different patterns can be irradiated by matching with the hollowed-out aluminum plate, and the attractiveness is improved.

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

according to the method, the telescopic structures are arranged on the two sides and the bottom of the auxiliary keel to drive the square through and the aluminum plate groups at the bottom of the two sides to carry out telescopic deformation, so that the aluminum plate groups at the bottom can be bent to different degrees according to the working state of the telescopic structures connected with the square through, the aluminum plate II on the square through at the two sides is matched with the aluminum plate I of each aluminum plate group below to form an integral suspended ceiling, and the effect of adjusting the telescopic structure working clearance telescopic or continuous movement state in real time to enable the aluminum plate I and the decoration structure on the surface of the aluminum plate II to carry out deformation movement is achieved by matching with the controller, so that the dynamic deformation suspended ceiling is realized;

according to the structure of the suspended ceiling, except for the suspended ceiling with dynamic demand change, the plurality of movable bent aluminum plate groups are connected between the lower ends of the two square ducts, the Fang Tongzuo right swing and the up-and-down movement of the bending parts of the aluminum plate groups are driven by the telescopic structure, so that the aluminum plate groups can present planar structure suspended ceilings or multi-angle bending wavy suspended ceilings according to the working state of the telescopic structure, the structure of the suspended ceiling of a building with different structures can be effectively adapted to be installed, the positions of the aluminum plate groups and the square ducts can be quickly adjusted through the telescopic structure, the installation is convenient, and the construction efficiency is improved;

an organ protection cover is arranged between the aluminum plate groups, and the telescopic folding structure of the organ protection cover can always keep the effect of shielding gaps when the aluminum plate groups are in a plane or bending state at various angles, so that the gaps after installation are reduced, and the attractiveness of a suspended ceiling is improved.

Drawings

FIG. 1 is a schematic cross-sectional view of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of the portion A of the present invention;

FIG. 3 is an enlarged schematic view of the portion B of the present invention;

the novel multifunctional ceiling lamp comprises a main keel, a secondary keel, a square tube 3, an aluminum plate group 4, an aluminum plate I41, a hinge 42, a telescopic structure 5, an air cylinder 51, a movable plate I52, a movable plate II 53, a movable plate III 54, a rotary shaft 55, a lamp 6, an organ-7 protective cover 8, an aluminum plate II, a square tube A and a telescopic structure connecting part, and an aluminum plate I and a telescopic structure connecting part.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-3, in a first embodiment, a method for dynamically deforming a suspended ceiling includes the steps of:

s1, two sides of a main keel 1 are movably arranged at the upper ends of two square ducts 3 respectively, a subsidiary keel 2 below the main keel 1 is connected with the middle parts of the square ducts 3 at two sides through a telescopic structure 5, and the square ducts 3 are driven to swing left and right by taking a connection point connected with the main keel 1 as a fulcrum and taking the inner sides of the two sides as an included angle;

s2, a plurality of deformable and bendable aluminum plate groups 4 are movably arranged between the lower ends of the two square tubes 3, the bottoms of the auxiliary keels 2 are connected through a telescopic structure 5 and drive the end parts of the aluminum plate groups 4 to move up and down, so that the bending parts in the middle of the aluminum plate groups 4 are bent;

s3, mounting a second aluminum plate 8 on the square tube 3, arranging three-dimensional decorations or pattern decorations on the aluminum plate group 4 and the second aluminum plate 8, and matching the decorations on the second aluminum plate 8 on the two sides with the decorations on the aluminum plate group 4 below to form a decoration structure arranged around the two sides and the bottom of the auxiliary keel 2;

s4, driving the square tubes 3 and the aluminum plate group 4 to move according to the gap of the telescopic structure 5 or continuous telescopic driving, and realizing the deformation of the decorative structure so as to form the dynamic deformation of the suspended ceiling.

A suspended ceiling structure for the dynamic deformation suspended ceiling method comprises a main keel 1 and an auxiliary keel 2 positioned below the main keel 1, wherein two square tubes 3 are movably arranged on the left side and the right side of the bottom of the main keel 1, the two square tubes 3 are far away from the end parts of the main keel 1 and are connected with each other through a plurality of movable bent aluminum plate groups 4, the aluminum plate groups 4 are positioned below the auxiliary keel 2, telescopic structures 5 which are movably connected with the square tubes 3 and the aluminum plate groups 4 in one-to-one correspondence are respectively arranged on the two sides and the bottom of the auxiliary keel 2, the bending parts of the aluminum plate groups 4 are connected with the telescopic ends of the telescopic structures 5, and the telescopic structures 5, the square tubes 3 and the aluminum plate groups 4 form a multi-fold suspended ceiling structure capable of freely changing forms.

Each aluminum plate group 4 comprises two aluminum plates 41, hinges 42 are arranged on two side edges of each aluminum plate 41, and the two aluminum plates 41 of the same aluminum plate group 4 are movably connected through the hinges 42. The included angle between the two aluminum plates 41 can be freely adjusted through the hinge 42, so that the effect of movably bending the aluminum plate group 4 is achieved.

Each telescopic structure 5 comprises a first movable plate 52 arranged on the auxiliary keel 2, the first movable plate 52 is movably connected with the fixed end of the air cylinder 51 through a rotating shaft 55, a second movable plate 53 is arranged on the square tube 3, and the second movable plate 53 is movably connected with the movable end of the air cylinder 51 through the rotating shaft 55. The square tube 3 is driven to swing through the operation of the air cylinder 51, and the first movable plate 52, the second movable plate 53 and the rotating shaft 55 enable connection points among all parts of the air cylinder 51 to flexibly rotate when the air cylinder stretches and contracts, so that clamping is prevented. Each cylinder 51 is connected with a controller, and the effect of adjusting the expansion and contraction of the cylinder in real time is realized through the controller.

Each aluminum plate group 4 is movably connected with the movable end of the corresponding cylinder 51 through a hinge 42 on the aluminum plate 41 at two sides. The hinge 42 is movably connected with the air cylinder 51, and when the air cylinder 51 stretches out and draws back, the matching square tube 3 swings inwards or outwards, so that the aluminum plate group 4 presents a planar or multiple-angle glass-shaped structure.

The main joist 1 is provided with a movable plate III 54 corresponding to the upper end of each square tube 3, the upper end of each square tube 3 is movably connected with the movable plate III 54 through a rotating shaft 55, the outward side surface of each square tube 3 is provided with an aluminum plate II 8, and the lower end of each aluminum plate II 8 is movably connected with a hinge 42 at the end part of an adjacent aluminum plate I41. The second aluminum plate 8 is used for shielding the square tube 3 and is connected with the first aluminum plate 41, so that the second aluminum plate 8 and the first aluminum plate 41 form a linkage effect when the square tube 3 swings.

An organ protective cover 7 is arranged between the adjacent aluminum plate groups 4. Through the telescopic folding structure of the organ protection cover 7, the effect of shielding the gap can be always kept when the aluminum plate group 4 is in a plane or each angle bending state, and the telescopic folding structure is used for protecting the movable end of the air cylinder 51 and preventing the air cylinder 51 from being exposed.

The first aluminum plate 41 can be an aluminum plate or a screen plate with hollowed patterns, and decorative structures are arranged on the opposite side surfaces of the first aluminum plate 41 and the second aluminum plate 8 and the auxiliary keel 2. The decorative structures on the aluminum plate II 8 and the aluminum plate I41 form complete pattern decoration, and when the telescopic structure 5 drives the aluminum plate I41 and the aluminum plate II 8 to move, the decorative structures can deform along with the movement. And a lamp 6 is arranged at the bottom of the auxiliary keel 2. The lighting effect is provided, different patterns can be irradiated by matching with the hollowed-out aluminum plate one 41, and the attractiveness is improved.

In the installation process of the invention, the aluminum plate II 8 is installed on the square tubes 3, the two square tubes 3 are installed on the main joist 1 through the movable plate III 54, the air cylinders 51 are fixed on the auxiliary joist 2 through the movable plate I52, the aluminum plate group 4 is assembled on the ground in advance, the aluminum plate group 4 is connected with the aluminum plate II 8 and the air cylinders 51 through the hoisting and other modes, and meanwhile, the square tubes 3 are connected with the corresponding air cylinders 51. When the suspended ceiling structure is used, the telescopic length of the air cylinder 51 can be adjusted according to the needs, so that the two square ducts 3 swing inwards or outwards, the more the two square ducts 3 face outwards, the larger the distance between the bottom ends of the two square ducts 3 is, the larger the included angle between the first aluminum plates 41 is, the more the suspended ceiling formed by connecting the aluminum plate groups 4 is approaching and leveling, and otherwise, the smaller the included angle between the first aluminum plates 41 is, and the suspended ceiling formed by connecting the aluminum plate groups 4 is in a wavy suspended ceiling structure with different angles. The organ shield 7 can always maintain the effect of shielding the slit when the aluminum plate group 4 is in a flat or bent state at various angles. The hollowed-out aluminum plate 41 is matched with the lamp 6, so that indoor brightness can be improved, meanwhile, different patterns can be formed by light rays irradiated on the ground through the aluminum plate 41, and attractiveness is improved.

According to the invention, through the matching of the telescopic structure 5, the square tubes 3 and the aluminum plate groups 4, the effect of forming a planar suspended ceiling or a multi-angle wavy suspended ceiling by freely adjusting the angle is realized, the adaptability to suspended ceilings of different structures is good, and gaps among components caused by additional processing are effectively reduced.

In the second embodiment, based on the first embodiment, the air cylinders 51 are preset in the controller to perform repeated telescopic movement respectively, so as to drive the square tube 3 and the aluminum plates 41 to perform regular repeated movement, so that the decorative structures on the aluminum plates 8 and 41 are deformed, and the effect that the suspended ceiling performs three-dimensional movement according to a certain rhythm is achieved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (9)

1. The dynamic deformation suspended ceiling method is characterized by comprising the following steps of:

s1, two sides of a main keel (1) are movably arranged at the upper ends of two square brackets (3) respectively, a secondary keel (2) below the main keel (1) is connected with the middle parts of the square brackets (3) at two sides through a telescopic structure (5), and the square brackets (3) are driven to swing left and right by taking a connecting point connected with the main keel (1) as a fulcrum and taking the inner sides of the two sides as included angles;

s2, a plurality of deformable and bendable aluminum plate groups (4) are movably arranged between the lower ends of the two square brackets (3), the bottoms of the auxiliary keels (2) are connected through telescopic structures (5) and drive the end parts of the aluminum plate groups (4) to move up and down, so that bending parts in the middle of the aluminum plate groups (4) are bent;

s3, mounting a second aluminum plate (8) on the square tube (3), and arranging three-dimensional decorations or pattern decorations on the aluminum plate group (4) and the second aluminum plate (8), wherein the decorations on the second aluminum plate (8) on two sides are matched with the decorations on the aluminum plate group (4) below to form a decoration structure which surrounds two sides and the bottom of the auxiliary keel (2);

s4, driving the square tubes (3) and the aluminum plate groups (4) to move according to the gaps of the telescopic structures (5) or continuous telescopic driving, and realizing the deformation of the decorative structures so as to form the dynamic deformation of the suspended ceiling.

2. A suspended ceiling structure for use in the dynamically-deforming suspended ceiling method of claim 1, wherein: including main joist (1) and be located auxiliary joist (2) of main joist (1) below, the left and right sides movable mounting of main joist (1) bottom has two square ducts (3), two square ducts (3) keep away from between the tip of main joist (1) through a plurality of movable aluminum plate group (4) interconnect of buckling, aluminum plate group (4) are located auxiliary joist (2) below, telescopic machanism (5) with each square duct (3) and each aluminum plate group (4) one-to-one swing joint are installed respectively to the both sides and the bottom of auxiliary joist (2), the flexible end that corresponds telescopic machanism (5) in the department of buckling of aluminum plate group (4) is connected, but form the multi-fold face furred ceiling structure of free transformation form between telescopic machanism (5), square duct (3) and each aluminum plate group (4).

3. A suspended ceiling structure as set forth in claim 2, wherein: each aluminum plate group (4) comprises two aluminum plates (41), hinges (42) are arranged on two side edges of each aluminum plate (41), and the two aluminum plates (41) of the same aluminum plate group (4) are movably connected through the hinges (42).

4. A suspended ceiling structure as set forth in claim 3, wherein: each telescopic structure (5) comprises a movable plate I (52) arranged on the auxiliary keel (2), the movable plate I (52) is movably connected with the fixed end of an air cylinder (51) through a rotating shaft (55), a movable plate II (53) is arranged on the square tube (3), the movable plate II (53) is movably connected with the movable end of the air cylinder (51) through the rotating shaft (55), and each air cylinder (51) is respectively connected with a controller.

5. The suspended ceiling structure of claim 4, wherein: each aluminum plate group (4) is movably connected with the movable end of the corresponding cylinder (51) through a hinge (42) on the aluminum plate one (41) at two sides.

6. The suspended ceiling structure of claim 4, wherein: the main joist (1) is provided with a movable plate III (54) corresponding to the upper ends of the square tubes (3), the upper ends of the square tubes (3) are movably connected with the movable plate III (54) through rotating shafts (55), the outward side surfaces of the square tubes (3) are provided with aluminum plate II (8), and the lower ends of the aluminum plate II (8) are movably connected with hinges (42) at the end parts of the adjacent aluminum plates I (41).

7. A suspended ceiling structure as set forth in claim 2, wherein: an organ protective cover (7) is arranged between the adjacent aluminum plate groups (4).

8. A suspended ceiling structure as set forth in claim 3, wherein: the aluminum plate I (41) can be an aluminum plate or a screen plate with hollowed patterns, and decorative structures are arranged on one side surface of the aluminum plate I (41) and one side surface of the aluminum plate II (8) opposite to the auxiliary keel (2).

9. A suspended ceiling structure as set forth in claim 2, wherein: and a lamp (6) is arranged at the bottom of the auxiliary keel (2).