CN220080469U - Split-level suspended ceiling structure - Google Patents

Abstract

The utility model relates to a staggered ceiling structure, which comprises vertical ceiling plates, transverse ceiling plates and structural members, wherein the vertical ceiling plates are arranged in the vertical direction, and the transverse ceiling plates are arranged in the transverse direction. The upper wing part of the structural member replaces an inner layer gypsum board in the prior art, and the main body part of the structural member and the vertical ceiling board form a split-layer suspended ceiling structure together, so that the split-layer suspended ceiling structure can be formed without arranging at least two layers of vertical gypsum boards as in the prior art; meanwhile, the structural part provided by the utility model is provided with the lamp groove, so that the lamp belt can be conveniently installed.

Description

Split-level suspended ceiling structure

Technical Field

The utility model relates to the technical field of interior decoration, in particular to a split-layer type suspended ceiling structure.

Background

The suspended ceiling is the most important part in the design of living room or bedroom space, can well conceal pipelines, electric equipment and the like, can achieve the best ornamental value, and bears the function of beautifying the space. With the development of interior decoration technology, "double eyelid" suspended ceilings are becoming increasingly popular with ordinary consumers. The so-called double-eyelid suspended ceiling is developed on the basis of a single-side suspended ceiling, and adopts a design of staggering the positive angle level so that the vertical length of an inner layer is longer than that of an outer layer, namely, a certain height difference exists between the outer layer and the inner layer, and the suspended ceiling looks like the double-eyelid suspended ceiling, so that the suspended ceiling is called as the double-eyelid suspended ceiling.

The current common practice for "double-eyelid" ceilings is to build a basic shape from two layers of vertical plasterboards stacked in the transverse direction of the house, while arranging the transverse plasterboards 3, making a circle along the whole house head space, with a certain height difference between the two layers of plasterboards, as shown in figure 1 of the description. The suspended ceiling adopting the method has the advantages of large consumption of gypsum boards, more parts and complex assembly procedures. Moreover, the suspended ceiling is not provided with the lamp slots, but one or more lamp slots for arranging the lamp strips are manually drawn out on the part of the inner gypsum board 2, which is exposed out of the outer gypsum board 1, in the process of installing the double-layer gypsum board, so that the construction workload of the whole suspended ceiling is greatly increased, the construction efficiency is reduced, and the construction period is delayed.

In view of this, it is necessary to design a split-level suspended ceiling structure that is simple in structure and easy to assemble, and at the same time, makes it easy to install the light strip.

Disclosure of Invention

In view of this, the utility model provides a split-level suspended ceiling structure, which has a simple structure, is convenient to assemble, and can facilitate the installation of the lamp strip due to the fact that the lamp groove is arranged on the structural member.

The utility model discloses a staggered ceiling structure, which comprises vertical ceiling plates, transverse ceiling plates and structural members, wherein the vertical ceiling plates are arranged in the vertical direction, the transverse ceiling plates are arranged in the transverse direction, the transverse outer side surfaces of the transverse ceiling plates do not exceed the transverse inner side surfaces of the vertical ceiling plates in the transverse width direction of the transverse ceiling plates, and the vertical staggered distance is reserved between the vertical lower side surfaces of the transverse ceiling plates and the vertical lower side surfaces of the vertical ceiling plates in the vertical direction; the structural member comprises an upper wing part, a main body part and a lower wing part, wherein the upper wing part is fixedly connected with the vertical ceiling plate, the lower wing part is fixedly connected with the horizontal ceiling plate, and the main body part is connected between the upper wing part and the lower wing part. In the present utility model, the vertical direction means a direction perpendicular to a room, the lateral direction means a direction perpendicular to a room, and the lateral width direction means a direction perpendicular to the room and a direction perpendicular to a ceiling board. In the utility model, the vertical ceiling boards are arranged in the vertical direction of the house relative to the ceiling of the house, and the horizontal ceiling boards are arranged in the horizontal direction of the house relative to the vertical wall surface of the house. In the present utility model, the outer side means a side away from a vertical wall surface of a house in a lateral direction, the inner side means a side relatively close to the vertical wall surface of the house in the lateral direction, the lower side means a side away from a ceiling of the house in the vertical direction, and the upper side means a side close to the ceiling of the house in the vertical direction.

In the utility model, an inverted L-shaped or step-shaped staggered structure is formed between the main body part of the structural member, the vertical ceiling plate and the horizontal ceiling plate together; specifically, the main body portion of the structural member, the vertical underside of the vertical ceiling plate and the lateral outside of the lateral ceiling plate together enclose an inverted L-shape or a step shape to form a staggered floor. By staggered floor is meant that there is a height drop between the vertical underside of the vertical ceiling tile and the vertical underside of the horizontal ceiling tile, in the present utility model the vertical underside of the vertical ceiling tile is located lower than the vertical underside of the horizontal ceiling tile.

By means of the inverted L-shaped staggered floor in the utility model, the utility model can realize a double eyelid suspended ceiling structure which is frequently used in the existing house decoration. In further embodiments, even a "tri-eyelid" or "multi-eyelid" suspended ceiling structure can be formed by means of the formed inverted step-shaped staggered layer, where multi-eyelid refers to a staggered layer structure of more than tri-eyelid. In the process, a double-eyelid suspended ceiling structure is formed without stacking two or more vertical suspended ceiling boards (usually double-layer gypsum boards in the prior art), so that materials are saved, and the construction efficiency is improved.

In the utility model, the main body part of the structural member is provided with a lamp groove for arranging the lamp strip, and the opening of the lamp groove faces to the lateral outside and does not exceed the lateral outside surface of the lateral ceiling plate. The structural part provided by the utility model is provided with the lamp groove, so that the lamp belt can be conveniently installed.

By means of the structural member with the lamp groove, the lamp belt can be directly installed while the split-layer suspended ceiling structure is formed. Compared with the prior art that the lamp groove is required to be manually manufactured on the inner gypsum board, the condition of installing the formed lamp groove is greatly saved, and the lamp belt (usually an LED lamp belt) is convenient to install, so that the final suspended ceiling is attractive and elegant in appearance.

In the utility model, a transverse staggered distance is arranged between the transverse outer side surface of the transverse suspended ceiling and the transverse inner side surface of the vertical suspended ceiling.

In the present utility model, the upper wing portion abuts against the lateral inner side of the vertical ceiling in a manner that forms a lateral stack, and/or the lower wing portion abuts against the vertical upper side of the vertical ceiling in a manner that forms a vertical stack.

In the utility model, the split-level suspended ceiling structure further comprises a vertical keel, wherein the vertical keel is parallel to the vertical suspended ceiling plate, and the upper wing part is clamped and fixed between the vertical keel and the vertical suspended ceiling plate.

In the present utility model, the split-level ceiling structure further includes a transverse keel parallel to the transverse ceiling panel, the lower wing portion being clamped between the transverse keel and the transverse ceiling panel.

In the utility model, the lamp groove is formed by bending the main body part of the structural member.

In the utility model, the lamp groove is formed by the lower bending section of the main body part of the structural part and the vertical upper side surface of the transverse ceiling plate.

In the utility model, the structural member is an integrally formed structure; alternatively, the upper wing part and the lower wing part are independent parts and are fixedly connected with the main body part respectively.

In the present utility model, the structural member is made of an aluminum alloy material or a galvanized sheet material.

The beneficial effects are that: in the staggered ceiling structure, the upper wing part of the structural part is used for replacing an inner layer gypsum board in the prior art, and the main body part of the structural part and the vertical ceiling board form the staggered ceiling structure together, so that the staggered ceiling structure can be formed without arranging at least two layers of vertical gypsum boards as in the prior art.

The split-level ceiling construction of the present utility model is disclosed in detail below in conjunction with the embodiments shown in the drawings and the reference numerals.

Drawings

Figure 1 shows a prior art split-level "double eyelid" ceiling construction.

Fig. 2 is a schematic structural diagram of a first embodiment of a split-level ceiling structure according to the present utility model.

Fig. 3 is a schematic structural diagram of a second embodiment of a split-level ceiling structure according to the present utility model.

Fig. 4 is a schematic structural diagram of a third embodiment of a split-level ceiling structure according to the present utility model.

Fig. 5 is a schematic structural diagram of a fourth embodiment of a split-level ceiling structure according to the present utility model.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. 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, in the embodiments of the present utility model, all directional indicators (such as up, down, left, right, front, and rear … …) are merely used to explain the relative positional relationship, movement conditions, and the like between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicators are correspondingly changed.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be regarded as not exist and not within the protection scope of the present utility model.

The utility model provides a staggered ceiling structure which comprises a vertical ceiling plate 4 and a horizontal ceiling plate 5, wherein the vertical ceiling plate 4 and the horizontal ceiling plate 5 are plasterboards, and of course, the skilled person will understand that the vertical ceiling plate 4 and the horizontal ceiling plate 5 can be made of other building ceiling decoration materials. In the staggered ceiling structure of the present utility model, the vertical ceiling panels 4 are arranged in the vertical direction, the lateral ceiling panels 5 are arranged in the lateral direction, the lateral outer side faces of the lateral ceiling panels 5 do not exceed the lateral inner side faces of the vertical ceiling panels 4 in the lateral width direction of the lateral ceiling panels 5, and a vertical staggered distance h is provided between the vertical lower side faces of the lateral ceiling panels 5 and the vertical lower side faces of the vertical ceiling panels 4 in the vertical direction.

The split-level suspended ceiling structure also comprises a structural member 6, wherein the structural member 6 is made of galvanized sheet materials or aluminum alloy materials by integral molding and comprises an upper wing part 6-1, a main body part 6-3 and a lower wing part 6-2, wherein the upper wing part 6-1 is fixedly connected with the vertical suspended ceiling plate 4, the lower wing part 6-2 is fixedly connected with the transverse suspended ceiling plate 5, and the main body part 6-3 is connected between the upper wing part 6-1 and the lower wing part 6-2.

A lamp recess 7 for the arrangement of a lamp strip 8 is provided in the main body portion 6-3 of the structural member 6, the opening of the lamp recess 7 facing laterally outwards and not exceeding the laterally outer side of the lateral ceiling tile 5. The lamp groove 7 is used for installing an LED lamp strip 8, and after the lamp strip 8 is installed, an inverted L-shaped or step-shaped lamp strip cover plate, a main body part 6-3 of the structural member 6, a vertical lower side surface of the vertical ceiling plate 4 and a horizontal outer side surface of the horizontal ceiling plate 5 are jointly enclosed to form a staggered layer.

In a preferred embodiment, a lateral staggered distance d is provided between the lateral outer side of the lateral suspended ceiling and the lateral inner side of the vertical suspended ceiling.

In a preferred embodiment, the upper wing portion 6-1 abuts against the laterally inner side of the vertical ceiling tile 4 in a manner that forms a lateral stack. The split-level ceiling structure further includes a vertical keel 10, the vertical keel 10 is parallel to the vertical ceiling plate 4, and the upper wing portion 6-1 is clamped and fixed between the vertical keel 10 and the vertical ceiling plate 4, and may also be fixed on one side of the vertical keel. The fastening of the vertical keel 10, the upper wing portion 6-1 of the structural member 6 and the vertical ceiling plate 4 is achieved by means of screws, and the connection between the vertical keel 10 and the upper wing portion 6-1 of the structural member may also be welded or riveted, as will be appreciated by those skilled in the art, and may be achieved by other existing means of connection. In addition, the vertical keel 10 is secured to the ceiling of the house by a top keel 11.

In a preferred embodiment the lower wing part 6-2 abuts against the vertically upper side of the transverse ceiling tile 5 in a manner that forms a vertical stack. The split-level ceiling structure further includes a transverse keel 12, the transverse keel 12 being parallel to the transverse ceiling panel 5, the lower wing portion 6-2 being clamped between the transverse keel 12 and the transverse ceiling panel 5. The fastening of the transverse keels 12, the lower wing sections 6-2 of the structural members 6 and the transverse ceiling panels 5 is achieved by screws, and the connection between the transverse keels 12 and the lower wing sections 6-2 of the structural members may also be welded or riveted, as will be appreciated by those skilled in the art, and may be achieved by other existing means of connection. In addition, the transverse keels 12 are secured to the vertical walls of the house by edge keels 13.

In addition, in the present utility model, when the structural member is made of galvanized sheet material, in order to facilitate subsequent coating of putty, a layer of glue is coated on the outer side surface of the main body portion of the structural member and a sticker is disposed.

With respect to the first embodiment of the structural member 6

Fig. 2 shows a schematic structural diagram of a first embodiment of the split-level ceiling structure of the present utility model. As shown in connection with fig. 2, in which the structural member 6 is integrally of a multi-layered stepped structure, the upper wing portion 6-1 is vertically arranged, and the upper wing portion 6-1 is held parallel to and abutted against the vertical ceiling plate 4 and is held and fixed between the vertical keel 10 and the vertical ceiling plate 4 by screws. The lower wing portion 6-2 is arranged laterally, the lower wing portion 6-2 being held parallel and in close proximity to the lateral ceiling 5 and being clamped between the lateral keel 12 and the lateral ceiling 5 by means of screws.

In the embodiment shown in fig. 2, the main body portion 6-3 of the structural member 6 is a W-shaped member comprising a first transverse section perpendicular to the upper wing portion 6-1, a first vertical section perpendicular to the first transverse section, a second transverse section perpendicular to the first vertical section and a second vertical section perpendicular to the second transverse section, wherein the first and second transverse sections are located at both ends of the first vertical section, respectively, and the second vertical section remains perpendicularly connected to the lower wing portion 6-2. In the main body portion 6-3 of this embodiment, the second transverse section and the second vertical section together form a lower bent section of the main body portion 6-3, which together with the vertically upper side of the transverse ceiling tile 5 encloses a light trough 7 for mounting a light strip 8. In this embodiment, a lamp holder 9 is provided in the lamp housing 7, and the led lamp strip 8 is mounted on the lamp holder 9.

In this embodiment, the first vertical section of the main body portion 6-3 remains in the same lateral position as the lateral outer side of the lateral ceiling tile 5 and the first lateral section remains in the same vertical position as the vertical lower side of the vertical ceiling tile 4 such that, after installation of the light fixture strip 8, the light fixture strip deck, the vertical lower side of the main body portion 6-3 vertical ceiling tile 4 and the lateral outer side of the lateral ceiling tile 5 together enclose an inverted L-shaped staggered structure.

Second embodiment concerning structural member 6

In the embodiment shown in fig. 3, the main body portion 6-3 of the structural member 6 is in an inverted L-shape, which includes a first transverse section and a first vertical section perpendicularly connected to the first transverse section, wherein the first transverse section is perpendicularly connected to the upper wing portion 6-1, the first vertical section is perpendicularly connected to the lower wing portion 6-2, the first vertical section is in a vertical plate-like structure, a lamp groove 7 which is laterally recessed (toward the wall) is provided thereon, and the led lamp strip 8 is installed in the lamp groove 7 and covered with a lamp strip cover plate 14.

In this embodiment, the first transverse section of the body portion 6-3 of the structural member 6 is maintained in the same vertical position as the vertically underside of the vertical ceiling tile 4 and the first vertical section is maintained in the same transverse position as the laterally outboard side of the horizontal ceiling tile 5 such that the vertically underside of the body portion 6-3 vertical ceiling tile 4 and the laterally outboard side of the horizontal ceiling tile 5 together enclose an inverted L-shaped staggered structure after installation of the light fixture strip 8.

Third embodiment concerning structural member 6

In the embodiment shown in fig. 4, the main body portion 6-3 of the structural member 6 includes a first vertical section and a first transverse section, the first transverse section is vertically connected with the upper wing portion 6-1, the lower end of the first vertical section is vertically connected with the lower wing portion 6-2, the connection between the upper portion of the first vertical section and the first transverse section is folded inwards to form a lamp groove 7 for installing the lamp strip 8 together with the first transverse section, and the lamp strip 8 is covered by a lamp strip cover plate 14 after being installed.

Fourth embodiment concerning structural member 6

In the embodiment shown in fig. 2 to 4, the upper wing portion 6-1 and the lower wing portion 6-2 of the structural member 6 are each plate-shaped, and the structural member 6 is of an integrally formed structure, i.e., the upper wing portion 6-1, the lower wing portion 6-2 and the main body portion 6-3 of the structural member 6 are integrally formed, which facilitates manufacture and installation.

In the embodiment shown in fig. 5, the upper wing portion 6-1 and the main body portion 6-3 of the structural member 6 are integrally formed, while the lower wing portion 6-2 of the structural member 6 is of L-shaped configuration, the lateral sections 15 of the lower wing portion 6-2 are abutted against and secured to each other by the lateral ceiling, and the vertical sections 16 of the lower wing portion 6-2 are abutted against and connected to the main body portion 6-3 of the structural member 6 by welding, riveting, screwing or other conventional mechanical connection means. Of course, it will be appreciated by those skilled in the art that in other embodiments, the upper wing portion 6-1 could also be a separate component and be attached by welding, riveting, screwing or other existing mechanical attachment means.

In the embodiment shown in fig. 5, the lower end of the main body portion 6-3 of the structural member 6 exceeds the transverse section 15 of the lower wing portion 6-2 and covers the transverse outer side of the transverse ceiling tile for good protection and decoration.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (10)

1. A split-level ceiling structure, comprising:

a vertical ceiling plate arranged in a vertical direction;

a lateral ceiling plate arranged in a lateral direction; in the transverse width direction of the transverse suspended ceiling plate, the transverse outer side surface of the transverse suspended ceiling plate does not exceed the transverse inner side surface of the vertical suspended ceiling plate, and in the vertical direction, a vertical staggered distance is formed between the vertical lower side surface of the transverse suspended ceiling plate and the vertical lower side surface of the vertical suspended ceiling plate;

the structural member comprises an upper wing part, a main body part and a lower wing part, wherein the upper wing part is fixedly connected with the vertical ceiling plate, the lower wing part is fixedly connected with the horizontal ceiling plate, and the main body part is connected between the upper wing part and the lower wing part;

the main body part of the structural member, the vertical ceiling plate and the horizontal ceiling plate form an inverted L-shaped or step-shaped staggered structure together.

2. The split-level ceiling structure of claim 1, wherein the main body portion of the structural member is provided with a light channel for routing a light strip, the light channel opening toward the laterally outer side and not beyond the laterally outer side of the lateral ceiling panel.

3. The staggered ceiling structure of claim 1, wherein a lateral staggered distance is provided between a lateral outer side of the lateral ceiling and a lateral inner side of the vertical ceiling.

4. The split-level ceiling structure of claim 1, wherein the upper wing portion abuts against a laterally inner side of the vertical ceiling panel in a manner that forms a lateral stack;

and/or the lower wing portion abuts against a vertical upper side of the transverse ceiling panel in a manner that forms a vertical stack.

5. The split-level ceiling structure of claim 3, further comprising a vertical keel parallel to the vertical ceiling panel, the upper wing portion being clamped between the vertical keel and the vertical ceiling panel.

6. The split-level ceiling structure of claim 4, further comprising a transverse keel parallel to the transverse ceiling panel, the lower wing portion being clamped between the transverse keel and the transverse ceiling panel.

7. The split-level ceiling structure of claim 2, wherein the light trough is formed by a bent arrangement of the main body portion of the structural member itself.

8. The split-level ceiling structure of claim 2, wherein the light trough is defined by a lower bent section of the main body portion of the structural member and a vertically upper side of the transverse ceiling panel.

9. The split-level ceiling structure of claim 1, wherein the structural members are integrally formed;

or the upper wing part and the lower wing part are independent components and are fixedly connected with the main body part respectively.

10. The split-level ceiling structure of any one of claims 1 to 9, wherein the structural member is made of an aluminum alloy material or a galvanized sheet material.