CN110593480B - Split type cold radiation furred ceiling suspended ceiling - Google Patents

Abstract

The invention provides a split type cold radiation suspended ceiling, which comprises a hoisting assembly, a cold radiation unit and a decoration panel, wherein the hoisting assembly is arranged on the ceiling; the cold radiation unit is hoisted below the hoisting assembly and comprises a cold radiation heat conduction layer, a cold source and a heat preservation layer; the cold radiation heat conduction layer is provided with a cold source installation groove extending along the axial direction, the cold source is installed in the cold source installation groove and is in heat conduction connection with the cold radiation heat conduction layer, the back sealing cover of the cold source is provided with an insulating layer, and the cold radiation unit is hoisted below the hoisting assembly through the cold radiation heat conduction layer; the decoration panel is hoisted under the hoisting assembly and can be covered under the cold radiation unit in a separable way, and the back surface of the decoration panel is in heat conduction connection with the radiation surface of the cold radiation unit. The invention separately hoists the cold radiation unit and the decoration panel, thereby facilitating the operation.

Description

Split type cold radiation furred ceiling suspended ceiling

Technical Field

The invention relates to the technical field of building materials and indoor heating and cooling, in particular to a split type cold radiation suspended ceiling.

Background

Cold radiation technology has been proposed abroad and introduced into China for many years, and its working principle is the physical heat radiation principle. The temperature of the surface of the suspended ceiling and the room temperature generate obvious temperature difference, so that a heat radiation phenomenon is formed between the suspended ceiling and the indoor space, and the aim of indoor heating or cooling is fulfilled.

The prior art cold radiation suspended ceiling is basically an improvement on each suspended ceiling on the basis of a common suspended ceiling. Each ceiling is independently provided with a cold source, a heat insulation layer and other structures, and then is installed block by block like a common suspended ceiling. However, current suspended ceiling designs have gradually transitioned to large ceiling designs, i.e., rather than using small tiles for ceiling stitching, large tiles are employed to present a flatter, more integrated suspended ceiling structure.

If the large-scale panel is independently provided with structures such as a cold source and an insulating layer, the weight of the large-scale ceiling can be greatly increased, the firmness of the hoisting structure is required to be correspondingly improved, and the existing hoisting structure can not necessarily meet the requirements. The large-sized ceiling is inconvenient to install on site, and if the weight is greatly increased, the operation difficulty of site installers is greatly improved, and accidents of falling and smash injury can occur in severe cases.

It is clear that the prior art has certain drawbacks.

Disclosure of Invention

The invention aims to solve the technical problem of providing a split type cold radiation suspended ceiling, which is convenient to operate by separately hoisting a cold radiation unit and a decoration panel.

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

A split type cold radiation suspended ceiling comprises a hoisting component, a cold radiation unit and a decoration panel; the cold radiation unit is hoisted below the hoisting assembly and comprises a cold radiation heat conduction layer, a cold source and a heat preservation layer; the cold radiation heat conduction layer is provided with a cold source installation groove extending along the axial direction, the cold source is installed in the cold source installation groove and is in heat conduction connection with the cold radiation heat conduction layer, the back sealing cover of the cold source is provided with an insulating layer, and the cold radiation unit is hoisted below the hoisting assembly through the cold radiation heat conduction layer; the decoration panel is hoisted under the hoisting assembly and can be covered under the cold radiation unit in a separable way, and the back surface of the decoration panel is in heat conduction connection with the radiation surface of the cold radiation unit.

Further, the hoisting assembly comprises a suspender, an upper layer of hoisting bar, an upper layer of keel, a lower layer of hoisting bar, a lower layer of keel and a unit hoisting piece; the upper layer hanging bracket is hung at the bottom end of the hanging rod; the upper keels are hoisted under at least two upper hoisting codes; the lower layer hanging bracket is hung on the upper layer keel; the lower layer keels and the upper layer keels are horizontally arranged in a crossing way and are hoisted below the lower layer hanging yards; the unit hoisting piece is hoisted on the upper keel; the cold radiation unit is hoisted below the unit hoisting piece; the decoration panel is installed in the lower floor fossil fragments, and decoration panel and at least one cold radiation unit heat conduction are connected.

Further, the top of cold radiation heat conduction layer is equipped with the hoist and mount ear along axial extension, the bottom of unit hoist and mount spare is equipped with and hoist and mount ear complex hoist and mount claw, hoist and mount claw hook locates on the hoist and mount ear and makes cold radiation unit hoist and mount under the upper fossil fragments.

Furthermore, the two sides of the cold radiation heat conduction layer are respectively provided with a connecting slot and a connecting flange which are matched with each other; the adjacent cold radiation units are inserted into the connecting slots through the connecting flanges, so that the two cold radiation units are mutually fixed.

Further, the cold source of the cold radiation unit is a heat conduction pipe, and a heat conduction medium is filled in the heat conduction pipe.

Further, the heat conducting pipes of the adjacent cold radiation units are connected through connecting pipelines, and the connecting pipelines are U-shaped, so that the heat conducting pipes are connected into a multi-bend coil pipe.

Further, the cold sources of the adjacent cold radiation units are connected through connecting pipelines, and each connecting pipeline comprises an inlet main pipe, an outlet main pipe and a branch pipe; the inlet main pipe extends along the arrangement direction of the heat conduction pipes and is arranged at one end of the cold radiation unit, and the inlet main pipe is connected with each heat conduction pipe through a branch pipe; the outlet main pipe extends along the arrangement direction of the heat conduction pipes and is arranged at the other end of the cold radiation unit, and the outlet main pipe is communicated with each heat conduction pipe through the branch pipes.

Further, the back of decoration panel is fixed to be laminated and is had a point boss, and the surface of point boss evenly is equipped with to the convex bump in decoration panel back, and every bump is fixed and heat conduction connection with the back laminating of decoration panel, and the back of point boss is connected with the radiation surface heat conduction of cold radiation unit.

Further, the radiating surface of the cold radiating unit is provided with heat-conducting silica gel in a laminating mode.

Further, the radiating fins are arranged on the surface of the radiating surface of the cold radiating unit in a protruding mode.

The split type cold radiation suspended ceiling provided by the invention has the following advantages:

The cold radiation unit and the decoration panel are separately hoisted, the cold radiation unit is hoisted firstly and then covered by the decoration panel, so that the cooling function is realized, the operation convenience is improved, and the advantage is particularly remarkable for the current popular large-scale ceilings;

the cold radiation unit and the decoration panel are respectively hoisted through the hoisting assembly, and the hoisting stress of the cold radiation unit and the decoration panel is not concentrated together, so that the stress is more dispersed, and the safety is higher;

The back of a decoration panel can be correspondingly provided with a plurality of cold radiation units according to the requirement, thereby facilitating the standardized production of the cold radiation units.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of the whole structure of a split type cold radiation suspended ceiling provided by the invention.

Fig. 2 is a schematic diagram showing an exploded structure of the cold radiation unit and the unit hanging member.

Fig. 3 is a schematic view of a combined structure of a decoration panel and a spot protruding plate.

Fig. 4 is a schematic diagram of an assembled structure of the connecting pipeline.

Fig. 5 is a schematic diagram of an assembly structure of an inlet main pipe and an outlet main pipe.

Reference numerals illustrate:

1. hoisting assembly 2, cold radiation unit

3. Decorative panel 4, boom

5. Upper layer hanging bracket 6 and upper layer keel

7. Lower layer hanging bracket 8 and lower layer keel

9. Unit sling 10, cold radiation heat conducting layer

11. Cold source 12 and heat insulating layer

13. Lifting lug 14 and lifting claw

15. Connection slot 16, connection flange

17. Radiating fin 18, spot convex plate

19. Connecting pipeline 20 and inlet main pipe

21. Outlet main pipe 22, branch pipe

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention and the accompanying drawings. It should be noted that the described embodiments are only some embodiments of the present invention, and 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.

Examples

Referring to fig. 1 to 3, an embodiment of the present invention provides a split type cold radiation suspended ceiling, which includes a hoisting assembly 1, a cold radiation unit 2 and a decoration panel 3; the cold radiation unit 2 is hoisted below the hoisting assembly 1, wherein the cold radiation unit 2 comprises a cold radiation heat conduction layer 10, a cold source 11 and a heat preservation layer 12; the cold radiation heat conduction layer 10 is provided with a cold source installation groove extending along the axial direction, the cold source 11 is installed in the cold source installation groove and is in heat conduction connection with the cold radiation heat conduction layer 10, a heat preservation layer 12 is arranged on a back sealing cover of the cold source 11, and the cold radiation unit 2 is hoisted under the hoisting assembly 1 through the cold radiation heat conduction layer 10; the decoration panel 3 is hoisted under the hoisting assembly 1 and is detachably covered under the cold radiation unit 2, and the back surface of the decoration panel 3 is in heat conduction connection with the radiation surface of the cold radiation unit 2.

Unlike conventional suspended ceiling or cold radiation ceiling, the present invention integrates the cold radiation unit 2 for the cold radiation function into one functional part, separated from the decorative panel 3, and separately hangs the load. The lifting device is used for being beneficial to dispersing the lifting load, so that the ceiling is not overweight, and the stress is more scientific. And the construction is facilitated, and constructors do not need to lift a cold radiation ceiling with larger weight to a high place for installation construction. This advantage is particularly pronounced in large ceilings of large area, which are currently in widespread use.

For the concrete hoisting structure, preferably, the hoisting assembly 1 comprises a boom 4, an upper layer hoisting bar 5, an upper layer keel 6, a lower layer hoisting bar 7, a lower layer keel 8 and a unit hoisting piece 9; the upper layer hanging bracket 5 is hung at the bottom end of the hanging rod 4; the upper keels 6 are hoisted under at least two upper hoisting codes 5; the lower layer hanging bracket 7 is hung on the upper layer keel 6; the lower keel 8 and the upper keel 6 are horizontally arranged in a crossing way and are hoisted under the lower hoisting code 7; the unit hoisting piece 9 is hoisted on the upper keel 6; the cold radiation unit 2 is hoisted below the unit hoisting piece 9; the decoration panel 3 is mounted on the lower keel 8, and the decoration panel 3 is in heat conduction connection with the at least one cold radiation unit 2.

More specifically, the top of the cold radiation heat conduction layer 10 is preferably provided with a lifting lug 13 extending along the axial direction, the bottom of the unit lifting piece 9 is provided with a lifting claw 14 matched with the lifting lug 13, and the lifting claw 14 is hooked on the lifting lug 13 to enable the cold radiation unit 2 to be lifted below the upper keel 6.

The hoist assembly 1 refers to prior art keel systems and essentially takes over most of the structure of the keel system. The cold radiation units 2 and the upper keels 6 independently form a hoisting structure, so that the load of all the cold radiation units 2 is dispersed on the upper keels 6, and the burden of the decoration panel 3 is reduced. During installation, the cold radiation unit 2 assembled in the factory in advance is hoisted, and then the bottom is covered with the decoration panel 3. In the hoisting structure, the cold radiation heat conduction layer 10 corresponds to the skeleton of the cold radiation unit 2, and is not only a main structure bearing hoisting load, but also a mounting base material of the cold source 11, the heat insulation layer 12 and the like. Meanwhile, the structure has the advantage of high integration level, and the cold radiation unit 2 is a highly integrated cold radiation functional component when leaving a factory, so that the standardized mass production is easy. One decoration panel 3 can correspond to a plurality of cold radiation units 2, and the construction method and structure are the same no matter what size the decoration panel 3 adopts.

As shown in detail in fig. 1 and 2, the cold radiation units 2 are preferably compactly combined with each other. The two sides of the cold radiation heat conduction layer 10 are respectively provided with a connecting slot 15 and a connecting flange 16 which are matched with each other; adjacent cold radiation units 2 are inserted into the connecting slots 15 through the connecting flanges 16, so that the two cold radiation units 2 are mutually fixed. The structure is similar to a jigsaw puzzle, and adjacent cold radiation units 2 can be mutually assembled to form a more compact whole. With this structure, the number of unit hanging pieces 9 can be reduced as appropriate, and it is unnecessary to equip each cold radiation unit 2 with a unit hanging piece 9, thereby saving the use of parts.

Preferably, the cold source 11 of the cold radiation unit 2 is a heat-conducting pipe, and a heat-conducting medium is introduced into the heat-conducting pipe. This is in the form of a cold source 11 of a conventional cold radiation ceiling which is widely used at present, nor does it exclude the use of an electrically cooled cold source 11.

Since there are a plurality of cold radiation units 2, the connection problem of the heat conductive pipe is inevitably involved. Referring to fig. 4, for a specific connection form of the heat pipes, as one preferable scheme, the heat pipes of the adjacent cold radiation units 2 are connected through a connection pipeline 19, and the connection pipeline 19 is in a U shape, so that the heat pipes are connected into a multi-bend coil.

The pipeline structure is similar to the traditional metal coil pipe, the flow is smaller, and the efficiency is more moderate. The medium liquid flows from the inlet to the outlet, and the outlet of the heat conducting pipe between the adjacent cold radiation units 2 is connected with the inlet.

Referring to fig. 5, or another preferred structure may be adopted, the cold sources 11 of adjacent cold radiation units 2 are connected through a connecting pipeline 19, and the connecting pipeline 19 includes an inlet main pipe 20, an outlet main pipe 21 and a branch pipe 22; the inlet main pipe 20 extends along the arrangement direction of the heat conduction pipes and is provided at one end of the cold radiation unit 2, and the inlet main pipe 20 is connected with each heat conduction pipe through a branch pipe 22; the outlet main pipe 21 extends along the arrangement direction of the heat transfer pipes and is provided at the other end of the cold radiation unit 2, and the outlet main pipe 21 is communicated with each of the heat transfer pipes through a branch pipe 22.

The scheme adopts a straight-line pipeline structure, medium liquid is input through an inlet main pipe 20, and meanwhile, the medium liquid is distributed in each branch pipe 22 to flow into each channel, and finally, the medium liquid is converged and output through an outlet main pipe 21. The pipeline structure has large flow and very rapid heat transfer response.

Referring to fig. 3 in detail, preferably, a protruding point plate 18 is fixedly attached to the back surface of the decorative panel 3, protruding points protruding toward the back surface of the decorative panel 3 are uniformly arranged on the surface of the protruding point plate 18, each protruding point is fixedly attached to and in heat-conducting connection with the back surface of the decorative panel 3, and the back surface of the protruding point plate 18 is in heat-conducting connection with the radiation surface of the cold radiation unit 2.

The protruding points 18 are formed by processing the metal plate material in a pressing manner, and the evenly distributed point contact between the protruding points and the decorative panel 3 is beneficial to more evenly distributing the cold radiation heat transfer effect, and meanwhile, the cooling effect is not too direct to cause easy condensation on the surface of the decorative panel 3. At the same time, the spot-convex plate 18 has a certain thickness and a certain deformation adaptability, so that the assembly tolerance between the back surface of the decoration panel 3 and the cold radiation unit 2 can be compensated in the installation height when the decoration panel 3 is installed in construction. In addition, the other function of the spot protruding plate 18 is to strengthen, so long as the bottom is adhered to the back surface of the decorative panel 3 by the adhesive, the decorative panel 3 can be strengthened, the strength is improved, and the decorative panel is not easy to bend. This effect is of great advantage in large ceiling applications.

Preferably, a heat conductive silica gel (not shown) is adhered to the surface of the radiation surface of the cold radiation unit 2. The heat-conducting silica gel has higher heat-conducting property and can be also used for heat conduction between the cold radiation unit 2 and the decoration panel 3. And the heat conduction silica gel also has certain thickness and deformation adaptability, so that the assembly tolerance between the back surface of the decoration panel 3 and the cold radiation unit 2 is compensated in the installation height when the decoration panel 3 is installed in a construction manner.

Or preferably, the radiation surface of the cold radiation unit 2 is convexly provided with radiation fins 17. The radiation fins 17 are advantageous in increasing the area of the radiation surface of the cold radiation unit 2, thereby enhancing the radiation effect.

The above structural schemes of the convex plate 18, the heat-conducting silica gel and the radiation fins 17 can be alternatively implemented, or can be implemented by combining a plurality of features to cooperate.

According to the split type cold radiation suspended ceiling provided by the invention, the cold radiation unit 2 and the decoration panel 3 are separately hoisted, the cold radiation unit 2 is hoisted firstly and then covered by the decoration panel 3, so that the cooling function is realized, the convenience of operation is improved, and the split type cold radiation suspended ceiling is especially suitable for the current popular large-scale ceiling structure. The cold radiation unit 2 and the decoration panel 3 are respectively hoisted through the hoisting assembly 1, and the hoisting stress of the cold radiation unit and the decoration panel can not be concentrated together, so the stress is more scientific, and the safety is higher. The back of one decoration panel 3 can be correspondingly provided with a plurality of cold radiation units 2 according to the requirement, thereby facilitating the standardized production of the cold radiation units 2.

The foregoing examples illustrate only a few embodiments of the invention and are described in detail herein without thereby limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. The split type cold radiation suspended ceiling is characterized by comprising a hoisting assembly, a cold radiation unit and a decoration panel; the cold radiation unit is hoisted below the hoisting assembly and comprises a cold radiation heat conduction layer, a cold source and a heat preservation layer; the cold radiation heat conduction layer is provided with a cold source installation groove extending along the axial direction, the cold source is installed in the cold source installation groove and is in heat conduction connection with the cold radiation heat conduction layer, the back sealing cover of the cold source is provided with an insulating layer, and the cold radiation unit is hoisted below the hoisting assembly through the cold radiation heat conduction layer; the decoration panel is hoisted under the hoisting assembly and can be covered under the cold radiation unit in a separable way, and the back surface of the decoration panel is in heat conduction connection with the radiation surface of the cold radiation unit.

2. The split cold-radiation suspended ceiling of claim 1, wherein the lifting assembly comprises a boom, an upper layer lifting bar, an upper layer keel, a lower layer lifting bar, a lower layer keel, and a unit lifting member; the upper layer hanging bracket is hung at the bottom end of the hanging rod; the upper keels are hoisted under at least two upper hoisting codes; the lower layer hanging bracket is hung on the upper layer keel; the lower layer keels and the upper layer keels are horizontally arranged in a crossing way and are hoisted below the lower layer hanging yards; the unit hoisting piece is hoisted on the upper keel; the cold radiation unit is hoisted below the unit hoisting piece; the decoration panel is installed in the lower floor fossil fragments, and decoration panel and at least one cold radiation unit heat conduction are connected.

3. The split type cold radiation suspended ceiling according to claim 2, wherein the top of the cold radiation heat conduction layer is provided with a lifting lug extending along the axial direction, the bottom of the unit lifting piece is provided with a lifting claw matched with the lifting lug, and the lifting claw is hooked on the lifting lug to enable the cold radiation unit to be lifted below the upper keel.

4. A split-type cold radiation suspended ceiling according to claim 2 or 3, wherein two sides of the cold radiation heat conduction layer are respectively provided with a connecting slot and a connecting flange which are mutually matched; the adjacent cold radiation units are inserted into the connecting slots through the connecting flanges, so that the two cold radiation units are mutually fixed.

5. A split type cold radiation suspended ceiling according to claim 1, 2 or 3, wherein the cold source of the cold radiation unit is a heat conducting pipe, and a heat conducting medium is introduced into the heat conducting pipe.

6. The split-type cold radiation suspended ceiling as set forth in claim 5, wherein the heat conducting pipes of adjacent cold radiation units are connected by connecting pipes, the connecting pipes are in a U shape, and the heat conducting pipes are connected into a multi-bend coil.

7. The split type cold radiation suspended ceiling according to claim 5, wherein cold sources of adjacent cold radiation units are connected through a connecting pipeline, and the connecting pipeline comprises an inlet main pipe, an outlet main pipe and a branch pipe; the inlet main pipe extends along the arrangement direction of the heat conduction pipes and is arranged at one end of the cold radiation unit, and the inlet main pipe is connected with each heat conduction pipe through a branch pipe; the outlet main pipe extends along the arrangement direction of the heat conduction pipes and is arranged at the other end of the cold radiation unit, and the outlet main pipe is communicated with each heat conduction pipe through the branch pipes.

8. The split type cold radiation suspended ceiling according to claim 1, 2 or 3, wherein a point convex plate is fixedly attached to the back surface of the decoration panel, convex points protruding towards the back surface of the decoration panel are uniformly arranged on the surface of the point convex plate, each convex point is fixedly attached to the back surface of the decoration panel and in heat conduction connection, and the back surface of the point convex plate is in heat conduction connection with the radiation surface of the cold radiation unit.

9. The split cold radiation suspended ceiling according to claim 1,2 or 3, wherein the radiating surface of the cold radiation unit is provided with heat conductive silica gel in a fitting manner.

10. A split cold radiation suspended ceiling as claimed in claim 1, 2 or 3, wherein the radiating surface of the cold radiation unit is provided with radiating fins in a protruding manner.