CN214834308U - Integrated ceiling radiation plate - Google Patents

Abstract

The utility model relates to an integral type furred ceiling radiation board, including fire prevention base plate, aluminum plate, gypsum board and radiant tube, fire prevention base plate top surface evenly distributed has many first vertical recesses and the first horizontal recess that parallel, and the aluminum plate lid closes at fire prevention base plate top surface and imbeds in first vertical recess and the first horizontal recess, and in radiant tube embedding second vertical recess and the horizontal recess of second, the gypsum board lid closed at the aluminum plate top surface. The utility model adopts an integrated structure, which eliminates the trouble of assembling, has high processing efficiency, good product quality, convenient stacking and low manufacturing cost; the fireproof substrate, the aluminum plate and the radiant tube adopt an embedded structure, so that the installation and the positioning are accurate and convenient, and the whole volume and weight are greatly reduced; fire prevention base plate, aluminum plate's special groove structure can be so that the radiant tube can adopt multiple coil pipe mode to can follow each direction as the mouth of pipe, lay for this integral type furred ceiling radiant panel provides convenience.

Description

Integrated ceiling radiation plate

Technical Field

The utility model relates to a radiation panel technical field especially relates to an integral type furred ceiling radiation plate.

Background

The radiation plate has become popular due to its features of energy saving, comfort, no occupation of room area, etc. However, the existing radiant panel generally adopts a split type assembling structure, a plurality of sets of dies are needed to be adopted for processing respectively during processing, then corresponding tools are adopted for combination, the processing efficiency is poor, a large amount of assembling time is needed, and in addition, because the radiant tube is not of a plate-shaped structure, the radiant tube is not easy to position and fix when being matched with other panels for installation, the integral structure is complex, and the volume is large.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure, simple to operate, the machine-shaping of being convenient for, the integral type furred ceiling radiation plate that the cost of manufacture is low.

The utility model discloses a realize through following technical scheme: an integrated ceiling radiation plate comprises a fireproof base plate, an aluminum plate, a gypsum plate and a radiation tube, wherein a plurality of parallel first longitudinal grooves and a plurality of first transverse grooves vertical to the first longitudinal grooves are uniformly distributed on the top surface of the fireproof base plate, the intersection of the first longitudinal groove and the first transverse groove is in arc transition, the aluminum plate covers the top surface of the fireproof substrate and is embedded into the first longitudinal groove and the first transverse groove, the embedded part forms a second longitudinal groove and a second transverse groove corresponding to the first longitudinal groove and the first longitudinal groove, and the second longitudinal grooves and/or the second transverse grooves positioned at the four corners of the aluminum plate extend out of the aluminum plate, the radiant tube is a plurality of continuous U-shaped structures, and the radiant tube is embedded in the second longitudinal groove and the second transverse groove, and the two ends of the radiant tube extend out of the aluminum plate, and the gypsum board covers the top surface of the aluminum plate.

Preferably, the fireproof substrate is a fireproof foam board.

In a preferred embodiment of the present invention, in order to facilitate the installation of the radiant tube, the top surface of the fireproof substrate has a plurality of parallel strip-shaped protrusions, the edges of the strip-shaped protrusions are arc-shaped surfaces, and a first longitudinal groove and a first transverse groove are formed between the strip-shaped protrusions;

the strip-shaped convex blocks comprise strip-shaped convex blocks arranged in the middle and short strip-shaped convex blocks arranged at two ends of the strip-shaped convex blocks.

In order to facilitate accurate positioning and avoid the movement of the aluminum plate, a convex hole which is sunken downwards is formed at the intersection of the second longitudinal groove and the second transverse groove.

A row of through holes penetrating through the aluminum plate are formed in the two sides of the aluminum plate respectively, the through holes are pilot holes in the aluminum plate stepping production process, and the same distance between every two steps is guaranteed.

The gypsum board top surface is equipped with the laser marking groove corresponding with radiant tube shape, and the pipeline position under the gypsum board can be markd in the laser marking groove, can not touch the pipeline when the fixed radiant panel of installation to avoid destroying the pipeline.

As a pipe outlet mode, two ends of the radiant tube extend out of the aluminum plate from the left side or the right side.

As another pipe outlet mode, two ends of the radiant tube extend out of the aluminum plate from the front side or the rear side.

For the convenience of assembly, the integrated ceiling radiating panel is combined into a module by four blocks.

The utility model has the advantages that:

(1) the fireproof base plate, the aluminum plate, the gypsum board and the radiant tube of the integrated ceiling radiant panel are all of an integrally formed structure, so that the trouble of assembling is avoided, the processing efficiency is high, the product quality is good, the stacking is convenient, and the manufacturing cost is low;

(2) the fireproof substrate, the aluminum plate and the radiant tube of the utility model adopt an embedded structure, the installation and the positioning are accurate and convenient, and the whole volume and the weight are greatly reduced;

(3) fire prevention base plate, aluminum plate's special groove structure can be so that the radiant tube can adopt multiple coil pipe mode to can follow each direction as the mouth of pipe, lay for this integral type furred ceiling radiant panel provides convenience.

Drawings

Fig. 1 is a schematic perspective view of an integrated ceiling radiation plate according to the present invention;

fig. 2 is an exploded view of the integrated ceiling radiant panel of the present invention;

fig. 3 is a schematic perspective view of the fire-proof substrate of the present invention;

fig. 4 is a schematic perspective view of an aluminum plate of the present invention;

FIG. 5 is a schematic structural view of a gypsum board of the present invention;

fig. 6 is a preferred pipe outlet method of the aluminum plate and the radiant tube of the present invention;

fig. 7 shows a preferred outlet tube pattern for a module comprising four integrated ceiling radiant panels according to the present invention;

fig. 8 is another preferred tube outlet method of the aluminum plate and radiant tube of the present invention;

fig. 9 is another preferred pipe exiting manner when four integrated ceiling radiant panels are combined into a module according to the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so that the advantages and features of the present invention can be more easily understood by those skilled in the art, and the protection scope of the present invention can be clearly and clearly defined. In the present invention, directional terms such as "up", "down", "front", "back", "left", "right", "top", "bottom", etc. refer to directions of the attached drawings only. Accordingly, the directional terms used are used for describing and understanding the present invention, and are not used for limiting the present invention.

An integrated ceiling radiation plate as shown in fig. 1 and 2 comprises a fireproof base plate 4, an aluminum plate 3, a gypsum board 1 and a radiation pipe 2.

Combine the fire prevention base plate 4 that fig. 2, 3 are shown, fire prevention base plate 4 is the fire prevention cystosepiment, has certain thickness, and fire prevention base plate 4 top surface has a plurality of strip lugs 5 that parallel, strip lug 5 is including setting up the rectangular form lug at the middle part and setting up the short strip lug at rectangular form lug both ends, and strip lug 5 edge is the arcwall face, forms many first vertical recess 10 that parallel and many first horizontal recesses 11 with first vertical recess 10 looks vertically between each strip lug, first vertical recess 10 adopts the circular arc transition with the intersection 6 of first horizontal recess 11, and intersection 6 is the quadrangle structure of pitch arc for the four sides, and first horizontal recess 11 both ends all extend outside fire prevention base plate 4, and the first vertical recess 10 that is located four angles extends outside fire prevention base plate 4. In addition, two first transverse grooves 11 are respectively provided with a concave hole 14 which is concave downwards. It should be noted that the fireproof substrate 4 itself is a flat plate structure, and the first longitudinal groove 10, the first transverse groove 11, the concave hole 14, and the like are all formed by hot press molding through an aluminum plate.

Combining the aluminum plate 3 shown in fig. 2 and 4, it is a thin sheet structure, the whole structure of the aluminum plate 3 is basically the same as the top structure of the fireproof substrate 4, the aluminum plate 3 covers the top surface of the fireproof substrate 4 and is embedded into the first longitudinal groove and the first transverse groove to form a completely coated structure, the embedded part of the aluminum plate forms the second longitudinal groove 12 and the second transverse groove 13 corresponding to the first longitudinal groove and the first longitudinal groove, both ends of the second longitudinal groove 12 and the second transverse groove 13 extend out of the aluminum plate 3, in addition, the intersection of the second longitudinal groove 12 and the second transverse groove 13 is provided with convex holes 8 which are concave downwards, the convex holes 8 are inserted into the concave holes of the fireproof substrate one by one, and the front side and the rear side of the aluminum plate 4 are respectively provided with a row of through holes 7 which run through the aluminum plate 4.

As shown in fig. 2, the radiant tube 2 is a plurality of continuous U-shaped structures (S-shaped), the radiant tube 2 is made of polyethylene tubes, the radiant tube 2 is embedded into the second longitudinal groove and the second transverse groove of the aluminum plate, and two ends of the radiant tube 2 extend out of the aluminum plate through the second longitudinal groove and/or the second transverse groove at the edges.

Referring to fig. 2 and 5, the gypsum board 1 is a flat plate structure and covers the top surface of the aluminum plate 3, and the top surface of the gypsum board 1 is provided with laser marking grooves 9 corresponding to the shapes of the radiant tubes.

As shown in fig. 6, in a pipe discharging manner, the inlet ends and the outlet ends of the radiant tubes 2 extend out from the left side (or the right side) of the aluminum plate 3, four integrated ceiling radiant panels are spliced into a module, and the radiant tubes extend out from the left side and the right side, as shown in fig. 7; as another pipe outlet method shown in fig. 8, the inlet ends and the outlet ends of the radiant tubes 2 both extend out from the two sides below (or above) the aluminum plate 3, the four integrated ceiling radiant panels are spliced into a module, and the radiant tubes extend out from the upper, lower and middle parts, as shown in fig. 9; due to the special matching structures of the second longitudinal groove and the second transverse groove, various pipe outlet modes can be combined according to actual installation conditions, and convenience is provided for installation.

After the fireproof substrate 4, the aluminum plate 3, the radiant tube 2 and the gypsum board 1 are assembled, an integral rectangular structure is formed, cold water or hot water is introduced into the radiant tube 2 during use, cold or heat is conducted to the surface of the gypsum board 1 through the tube wall of the radiant tube 2, and then radiation convection is carried out between the gypsum board 1 and the indoor temperature, so that the purpose of cooling or heating is achieved.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (10)

1. An integral type furred ceiling radiation board which characterized in that: including fire prevention base plate, aluminum plate, gypsum board and radiant tube, fire prevention base plate top surface evenly distributed have many parallel first vertical recess and many and first vertical recess looks vertically first horizontal recess, first vertical recess and the circular arc transition of first horizontal recess intersection, the aluminum plate lid closes in fire prevention base plate top surface and imbeds first vertical recess and first horizontal recess, and the embedding position forms with first vertical recess, the corresponding second vertical recess of first vertical recess, the horizontal recess of second, and is located the vertical recess of second and/or the horizontal recess of second in aluminum plate four corners and extends to outside aluminum plate, the radiant tube is the continuous U type structure of a plurality of looks, in radiant tube embedding second vertical recess and the horizontal recess of second, and the radiant tube both ends stretch out outside aluminum plate, the gypsum board lid closes at the aluminum plate top surface.

2. The integrated ceiling radiant panel of claim 1, wherein: the top surface of the fireproof substrate is provided with a plurality of parallel strip-shaped convex blocks, the edges of the strip-shaped convex blocks are arc-shaped surfaces, and a first longitudinal groove and a first transverse groove are formed among the strip-shaped convex blocks.

3. The integrated ceiling radiant panel of claim 2, wherein: the strip-shaped convex blocks comprise strip-shaped convex blocks arranged in the middle and short strip-shaped convex blocks arranged at two ends of the strip-shaped convex blocks.

4. The integrated ceiling radiant panel of claim 1, wherein: the aluminum plate is embedded into the fireproof substrate in a hot-pressing mode.

5. The integrated ceiling radiant panel of claim 1, wherein: and a convex hole which is concave downwards is formed at the intersection of the second longitudinal groove and the second transverse groove.

6. The integrated ceiling radiant panel of claim 1, wherein: and a row of through holes penetrating through the aluminum plate are respectively formed in two sides of the aluminum plate.

7. The integrated ceiling radiant panel of claim 1, wherein: the gypsum board top surface is equipped with the laser marking groove corresponding with radiant tube shape.

8. The integrated ceiling radiant panel of claim 1, wherein: and two ends of the radiant tube extend out of the aluminum plate from the left side or the right side.

9. The integrated ceiling radiant panel of claim 1, wherein: and two ends of the radiant tube extend out of the aluminum plate from the front side or the rear side.

10. The integrated ceiling radiant panel of claim 8 or 9, wherein: the integrated ceiling radiation plate is combined into a module through four blocks.

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