CN107062485B

CN107062485B - Radiation plate mounting structure and mounting method thereof

Info

Publication number: CN107062485B
Application number: CN201710319717.6A
Authority: CN
Inventors: 沙群淮; 王有志
Original assignee: Berlind Kunshan Environmental Equipment Co ltd
Current assignee: Berlind Kunshan Environmental Equipment Co ltd
Priority date: 2017-05-09
Filing date: 2017-05-09
Publication date: 2023-08-25
Anticipated expiration: 2037-05-09
Also published as: CN107062485A

Abstract

The invention discloses a radiation plate mounting structure and a mounting method thereof.A plurality of limiting pieces are movably arranged on two sides of the upper surface of a radiation plate, each limiting piece has an unfolding state and a folding state, and when the limiting piece is in the folding state, the width of the radiation plate is smaller than the width between two auxiliary keels positioned on the left side and the right side of the radiation plate; when the limiting pieces are in an unfolding state, the limiting pieces are blocked above the auxiliary keels positioned on the left side and the right side of the radiation plate; the radiation plate mounting structure also comprises a plurality of transverse pressurizing spring plates which are arranged on the upper surface of the radiation plate and apply elasticity downwards, the lower surface of the radiation plate is flush with the lower surface of the auxiliary keel or lower than the lower surface of the auxiliary keel, and the radiation plate mounting structure and the mounting method thereof can simplify the radiation plate mounting process and have better radiation effect.

Description

Radiation plate mounting structure and mounting method thereof

Technical Field

The invention relates to the field of heat dissipation equipment at the tail end of an air conditioning system, in particular to an indoor suspended ceiling heating system.

Background

In the prior art, the radiation plates are classified according to the installation mode, and can be roughly classified into a suspended ceiling radiation plate, a wall hanging radiation plate, a wall-in radiation plate, a floor radiation plate and the like. The ceiling radiation plate is fixedly installed through a ceiling device or is hung on an indoor ceiling/ceiling through flexible connecting pieces such as chains.

In the indoor installation process, the suspended ceiling radiation plate needs to be hung or fixed on a ceiling or the ceiling, and the radiation plate is inconvenient to install due to the fact that the weight and occupied space of the radiation plate are too large, and the detachable suspended ceiling radiation plate is needed to be installed rapidly and conveniently, so that the radiation effect is not affected.

Disclosure of Invention

In order to solve the technical problems, the invention aims to provide a suspended ceiling radiation plate mounting structure which simplifies the mounting process and has better radiation effect.

In order to achieve the purpose of the invention, the invention adopts the following technical scheme:

the utility model provides a radiation plate mounting structure, includes the furred ceiling fossil fragments that are fixed on indoor ceiling and fixes the radiation plate on the furred ceiling fossil fragments, the furred ceiling fossil fragments include main joist and auxiliary joist, the both sides of radiation plate upper surface activity be provided with a plurality of locating parts, the locating part have expansion and folding state, when the locating part be in folding state, the width of radiation plate be less than the width between two auxiliary joists that are located the radiation plate left and right sides; when the limiting pieces are in an unfolding state, a plurality of limiting pieces are blocked above the auxiliary keels positioned on the left side and the right side of the radiation plate; the radiation plate mounting structure also comprises a plurality of transverse pressurizing spring plates which are arranged on the upper surface of the radiation plate and apply elasticity downwards, and the lower surface of the radiation plate is flush with or lower than the lower surface of the auxiliary keel.

In the above technical solution, preferably, the lateral pressurizing spring plate includes a pressurizing portion and hook portions located at left and right ends of the lateral pressurizing spring plate, the hook portions at the two ends of the lateral pressurizing spring plate are respectively hooked on the auxiliary keels located at left and right sides of the radiation plate, and the pressurizing portion abuts against the upper surface of the radiation plate.

In the above technical solution, preferably, the lateral pressing spring has an elastically deformed state and an original state, and when the lateral pressing spring is in the original state, the lower surface of the hook portion is higher than the lower surface of the pressing portion.

In the above technical solution, preferably, the plurality of limiting members are rotatably connected to the upper surface of the radiation plate.

In the above technical scheme, preferably, the radiation plate comprises a heat insulation plate with a pipe groove on the lower surface, a metal heat conduction layer covering the lower surface of the heat insulation plate, and an oxygen blocking plastic pipe fixed in the pipe groove and internally filled with high/low temperature flowing medium, wherein the metal heat conduction layer is in heat conduction contact with the oxygen blocking plastic pipe, and the metal heat conduction layer forms a heat conduction plane for heat conduction contact with the gypsum board.

In the above technical scheme, preferably, the radiation plate comprises a plurality of heat insulation plates, and the heat insulation plates are in seamless lap joint.

In the above technical scheme, preferably, an upper pressing strip and a lower pressing strip are fixed at the joint of two adjacent heat insulation boards, the metal heat conduction layer and the oxygen-blocking plastic pipe are clamped and fixed between the upper pressing strip and the lower pressing strip, and the upper pressing strip and the lower pressing strip are fixed through a fastener.

The mounting method of the radiation plate mounting structure comprises the following steps: the method comprises the following steps:

1) Mounting a main keel and an auxiliary keel;

2) Placing the radiation plate between the auxiliary keels positioned on the left side and the right side of the radiation plate, expanding a plurality of limiting pieces, and hanging the radiation plate on the auxiliary keels;

3) The two hook parts of the transverse pressurizing elastic sheet are hooked on the auxiliary keel;

4) And a gypsum board is arranged under the radiation board in a covering way.

Compared with the prior art, the invention has the following beneficial effects: the left end and the right end of the upper surface of the radiation plate are movably provided with limiting pieces, the limiting pieces are in unfolding and folding states, and when the limiting pieces are in the folding states, the width of the radiation plate is smaller than the width between two auxiliary keels positioned on the left side and the right side of the radiation plate; when the limiting pieces are in an unfolding state, the limiting pieces are blocked above the auxiliary keels positioned on the left side and the right side of the radiation plate, so that the radiation plate can be conveniently and rapidly installed or separated from the space between the two auxiliary keels, the installation or the disassembly is more convenient and simple, and the efficiency is improved; be provided with horizontal pressurization shell fragment on the upper surface of radiant panel, when the false keel holds in the palm and lifts the radiant panel, the hook portion at both ends is hooked the false keel about the horizontal pressurization shell fragment, and the pressurization portion in the middle of the horizontal pressurization shell fragment supports tight radiant panel upper surface, guarantees the radiant panel and firmly installs for the lower surface of radiant panel flushes or is less than the lower surface of false keel with the lower surface of false keel, and the whole appearance of radiant panel is more pleasing to the eye.

Drawings

FIG. 1 is a schematic perspective view of a ceiling radiant panel of the present invention;

FIG. 2 is a schematic bottom view of a ceiling radiant panel of the present invention;

FIG. 3 is a partially exploded perspective view of the ceiling radiant panel of the present invention;

FIG. 4 is a schematic view of a cut-away A-A of a ceiling radiant panel of the present invention.

Wherein: 1. a ceiling keel; 11. a keel suspender; 12. a main keel; 121. a keel slide fastener; 13. a secondary keel; 2. a radiation plate; 21. a thermal insulation board; 211. a tube groove; 2111. a straight line segment; 2112. a circular arc section; 2113. a protrusion; 22. a metal heat conducting layer; 23. an oxygen-blocking plastic tube; 231. a water inlet end; 232. a water outlet end; 24. a transverse pressurizing spring plate; 241. a pressurizing section; 242. a hook portion; 25. an upper pressing bar; 251. a limiting piece; 26. and (5) a lower pressing bar.

Detailed Description

In order to describe the technical content, constructional features, achieved objects and effects of the invention in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

The ceiling heating/refrigerating system comprises an outdoor heating/refrigerating machine and a plurality of combined ceilings installed indoors, wherein each combined ceiling comprises a plurality of radiating plates 2 installed on indoor ceiling keels 1 and gypsum boards covered below the plurality of radiating plates 2, each radiating plate 2 comprises a heat-insulating plate 21 with a pipe groove 211 formed in the lower surface, a metal heat-conducting layer 22 covered on the lower surface of the heat-insulating plate 21, an oxygen-blocking plastic pipe 23 fixed in the pipe groove 211 and internally communicated with high/low temperature flowing media, and the metal heat-conducting layer 22 is partially positioned in the pipe groove 211 and is in heat-conducting contact with the oxygen-blocking plastic pipe 23, and the metal heat-conducting layer 22 forms a heat-conducting plane for heat-conducting contact with the gypsum boards.

As shown in fig. 1, 3 and 4, the suspended ceiling joist 1 is fixedly installed on an indoor ceiling/ceiling of a building, and the suspended ceiling joist 1 comprises a joist suspender 11, a main joist 12 fixed at the lower end of the joist suspender 11, and two auxiliary joists 13 fixed on the main joist 12 and mutually perpendicular to the main joist 12; the main keels 12 are movably provided with keel sliders 121, the auxiliary keels 13 are fixedly arranged on the keel sliders 121 and can slide along the axial direction of the main keels 12 through the keel sliders 121, so that the interval between two adjacent auxiliary keels 13 is adjusted; a radiation plate 2 is arranged between the two auxiliary keels 13.

The radiation plate 2 comprises a heat insulation plate 21, a metal heat conduction layer 22 and an oxygen-blocking plastic pipe 23; the heat-insulating plate 21 is made of EPP material, EPP is an abbreviation (expanded polypropylene), is a abbreviation of novel foam plastic, has the advantages of light specific gravity, shock resistance, compression resistance, high deformation recovery rate, resistance to various chemical solvents, insulation, heat resistance and the like, and the heat-insulating plate 21 made of the material can keep heat continuously, so that the heat-radiating effect of the radiation plate is enhanced; the radiation plate 2 is formed by splicing a plurality of heat preservation plates 21, an upper pressing strip 25 and a lower pressing strip 26 are fixed at the joint of two adjacent heat preservation plates 21, and the upper pressing strip and the lower pressing strip are fixedly connected through fasteners such as bolts.

The two ends of the upper pressing strip 25 are hinged with the limiting piece 251, the limiting piece 251 can rotate 90 degrees around the hinge points of the two ends of the upper pressing strip 25, so that the limiting piece 251 has an unfolding state and a folding state, and when the limiting piece 251 is in the folding state, the width of the radiation plate 2 is smaller than the width between the two auxiliary keels 13 positioned at the left side and the right side of the radiation plate 2; when the limiting pieces 251 are in the unfolded state, the plurality of limiting pieces 251 are blocked above the auxiliary keels 13 positioned at the left side and the right side of the radiation plate 2; thereby mounting or detaching the radiation plate 2 from between the two subsidiary keels 13; the upper surface of the radiation plate 2 is abutted with a transverse pressurizing spring piece 24.

The lateral pressing spring piece 24 has an elastic deformation state and an original state, the lateral pressing spring piece 24 comprises a pressing portion 241 and hook portions 242 positioned at the left end and the right end of the lateral pressing spring piece 24, when the lateral pressing spring piece 24 is in the original state, the lower surface of the hook portion 242 is higher than the lower surface of the pressing portion 241; when the lateral pressing spring piece 24 is in an elastic deformation state, the hook parts 242 at the two ends of the lateral pressing spring piece 24 are respectively hooked on the auxiliary keels 13 positioned at the left side and the right side of the radiation plate 2, the pressing parts 241 are abutted against the upper surface of the radiation plate 2 and exert downward elastic force on the upper surface of the radiation plate 2; the lower surface of the radiant panel 2 is flush with the lower surface of the cross runner 13 or below the lower surface of the cross runner 13.

As shown in fig. 2 and 4, the heat insulation board 21 is provided with a pipe groove 211, the groove bottom width of the pipe groove 211 is larger than the groove opening width, the pipe groove 211 comprises a plurality of straight-line sections 2111 which are parallel to each other and arc sections 2112 which are respectively connected with the straight-line sections 2111, and the straight-line sections 2111 and the arc sections 2112 are connected end to form a continuous disc-shaped pipe groove 211; the straight line segments 2111 are positioned at the middle position of the radiation plate 2, the circular arc segments 2112 are positioned at two ends of the radiation plate 2, the distance between two adjacent straight line segments 2111 of the pipe groove 211 is 1 to 1.5 times of the pipe diameter of the oxygen-blocking plastic pipe, and protrusions 2113 extending towards the center of the pipe groove along the plane of the cross section of the pipe groove are arranged at two sides of the inner wall of the pipe groove 211.

In order to enhance the heat radiation effect of the radiation plate, the lower surface of the heat insulation plate 21 is covered with a metal heat conduction layer 22 made of a thin metal sheet, the metal heat conduction layer 22 partially penetrates into the pipe groove 211 and clings to the inner wall of the pipe groove 211, and the lower surface of the radiation plate 2, which is positioned outside the metal heat conduction layer 22, is covered with a layer of gypsum board which is in heat conduction contact with the metal heat conduction layer 22, and the thickness of the gypsum board is 9.5mm.

For convenience in processing and installation, the oxygen-blocking plastic pipe 23 is made of soft plastic, and when the oxygen-blocking plastic pipe 23 is extruded into the pipe groove 211, the oxygen-blocking plastic pipe 23 comprises a water inlet end 231 and a water outlet end 232, and the water inlet end 231 and the water outlet end 232 simultaneously extend out from one side of the radiation plate 2, and a high/low temperature fluidity medium such as cold/hot water or the like is introduced into the oxygen-blocking plastic pipe 23.

1) Mounting a main keel and an auxiliary keel;

4) And a gypsum board is arranged under the radiation board in a covering way.

The above embodiments are provided to illustrate the technical concept and features of the present invention and are intended to enable those skilled in the art to understand the content of the present invention and implement the same, and are not intended to limit the scope of the present invention. All equivalent changes or modifications made in accordance with the spirit of the present invention should be construed to be included in the scope of the present invention.

Claims

1. The utility model provides a radiation plate mounting structure, includes suspended ceiling fossil fragments (1) and fixes on suspended ceiling fossil fragments (1) radiation plate (2) on fixed indoor ceiling, suspended ceiling fossil fragments (1) include main joist (12) and auxiliary joist (13), its characterized in that: the main keel (12) is movably provided with a keel slide fastener (121), the auxiliary keel (13) is fixedly arranged on the keel slide fastener (121) and can slide along the axial direction of the main keel (12), two sides of the upper surface of the radiation plate (2) are movably provided with a plurality of limiting pieces (251), the limiting pieces (251) are rotationally connected to the upper surface of the radiation plate (2), the limiting pieces (251) are in an unfolding and folding state, and when the limiting pieces (251) are in the folding state, the width between the limiting pieces (251) on the left side and the right side of the radiation plate (2) is smaller than the width between the two auxiliary keels (13) on the left side and the right side of the radiation plate (2); when the limiting pieces (251) are in an unfolding state, a plurality of the limiting pieces (251) are blocked above the auxiliary keels (13) on the left side and the right side of the radiation plate (2); the radiation plate mounting structure also comprises a plurality of transverse pressurizing spring plates (24) which are arranged on the upper surface of the radiation plate (2) and apply elasticity downwards, and the lower surface of the radiation plate (2) is flush with the lower surface of the auxiliary keel (13) or lower than the lower surface of the auxiliary keel (13).

2. The radiation plate mounting structure according to claim 1, wherein: the transverse pressurizing spring piece (24) comprises a pressurizing part (241) and hook parts (242) positioned at the left end and the right end of the transverse pressurizing spring piece (24), the hook parts (242) at the two ends of the transverse pressurizing spring piece (24) are respectively hooked on the auxiliary keels (13) positioned at the left side and the right side of the radiation plate (2), and the pressurizing part (241) is abutted against the upper surface of the radiation plate (2).

3. The radiation plate mounting structure according to claim 2, wherein: the transverse pressing spring piece (24) has an elastic deformation state and an original state, and when the transverse pressing spring piece (24) is in the original state, the lower surface of the hook part (242) is higher than the lower surface of the pressing part (241).

4. The radiation plate mounting structure according to claim 1, wherein: the radiation plate (2) comprises a heat insulation plate (21) with a pipe groove (211) formed in the lower surface, a metal heat conduction layer (22) covering the lower surface of the heat insulation plate (21), and an oxygen blocking plastic pipe (23) fixed in the pipe groove (211) and internally communicated with high/low temperature flowing media, wherein the metal heat conduction layer (22) is in heat conduction contact with the oxygen blocking plastic pipe (23), and the metal heat conduction layer (22) forms a heat conduction plane used for heat conduction contact with the gypsum board.

5. The radiation plate mounting structure as defined in claim 4, wherein: the radiation plate (2) comprises a plurality of heat preservation plates (21), and the heat preservation plates (21) are in seamless lap joint.

6. The radiation plate mounting structure as defined in claim 5, wherein: the connecting part of two adjacent heat preservation boards (21) is fixedly provided with an upper pressing strip (25) and a lower pressing strip (26), the heat preservation boards (21), the metal heat conduction layer (22) and the oxygen-blocking plastic pipe (23) are clamped and fixed between the upper pressing strip (25) and the lower pressing strip (26), the upper pressing strip and the lower pressing strip are fixed through a fastener, and two ends of the upper pressing strip (25) are hinged and connected with the limiting piece (251).

7. The mounting method of a radiation plate mounting structure according to any one of claims 1 to 6: the method comprises the following steps:

1), installing a main keel (12) and an auxiliary keel (13);

2) Placing the radiation plate (2) between the auxiliary keels (13) positioned on the left side and the right side of the radiation plate (2), expanding a plurality of limiting pieces (251), and hanging the radiation plate (2) on the auxiliary keels (13);

3) Two hook parts (242) of the transverse pressurizing spring piece (24) are hooked on the auxiliary keel (13);

4) And a gypsum board is covered and installed below the radiation board (2).