CN213682730U - Pipeline detachable concrete floor for radiation - Google Patents

Abstract

The utility model relates to an air conditioner field for an air conditioner end device particularly, relates to a removable concrete floor of pipeline for radiation. The radiation pipeline detachable concrete floor comprises a floor body, a radiation coil and a locking piece; the bottom of the floor slab body is provided with a pipeline groove which is used for installing the radiation coil; the locking member is switchable between a locked state and an open state, the locking member being capable of locking the radiant coil within the pipe channel when locked; when the locking member is opened, the radiant coil can be removed from the ducting trough. The utility model provides a radiation pipeline detachable concrete floor, which can finish the detachment and maintenance of the radiation coil pipe without damaging the main structure; in addition, the radiant coil occupies a smaller building floor height or does not occupy the building floor height at all; meanwhile, the radiant coil has the advantages of strong radiant energy, small thermal inertia and high heat exchange efficiency.

Description

Pipeline detachable concrete floor for radiation

Technical Field

The utility model relates to an air conditioner field for an air conditioner end device particularly, relates to a removable concrete floor of pipeline for radiation.

Background

Building energy consumption is the main form of energy consumption, and building energy conservation forms a great worldwide trend and is a basic trend of modern technology development. Meanwhile, it is becoming more and more important and urgent to improve the indoor environmental quality, improve the comfort level, and reduce the environmental pollution.

The independent temperature and humidity control system adopts two independent systems to respectively control and regulate the indoor temperature and humidity, thereby avoiding energy waste and air quality reduction caused by temperature and humidity combined treatment in a conventional system.

The ceiling radiation system is the most ideal end form in the independent temperature and humidity control system, and the principle is that the cold and hot medium transfers energy to the radiation surface through the radiation coil pipe, and the radiation surface directly exchanges heat with the indoor environment in a convection and radiation (mainly radiation) mode, so that the transfer process of the energy from the cold and hot source to the indoor environment of the terminal user is greatly simplified, and the irreversible loss is reduced. The refrigerant is water, and compared with air, the water can improve the energy transmission density and save the space occupied by the transmission channel. The radiation heating only needs low-temperature hot water at 30-35 ℃ in winter, and the radiation refrigeration only needs high-temperature cold water at 16-20 ℃ in summer, so that the perfect combination of high comfort and low energy consumption is realized.

The existing applied ceiling radiation system is divided into a dry method technology and a wet method technology, wherein the dry method technology needs to arrange a plastering layer or a ceiling board below a concrete floor slab, and a radiation coil is laid in the plastering layer or the ceiling board, so that the radiation coil occupies a larger building floor height; the radiation coil pipe of the wet method technology is laid between an upper reinforcing steel bar and a lower reinforcing steel bar of a concrete floor slab and needs to be buried in cement on a construction site, the method cannot realize the disassembly and maintenance of the radiation coil pipe on the premise of not damaging a main body structure, and the radiation capability is poor, the thermal inertia is large, and the heat exchange efficiency is low.

In summary, how to overcome the above-mentioned defects of the existing ceiling radiation system is a technical problem to be solved urgently by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a removable concrete floor of pipeline for radiation to alleviate the ceiling radiation system among the prior art existence occupy the building story height or can't realize the technical problem that radiation coil's dismantlement was maintained at the later stage.

The utility model provides a removable concrete floor of pipeline for radiation, including floor body, radiation coil pipe and locking piece.

The bottom of the floor slab body is provided with a pipeline groove, and the pipeline groove is used for installing the radiation coil; said locking member being switchable between a locked condition and an open condition, said locking member being capable of locking said radiant coil within said channel when locked; when the locking member is opened, the radiant coil can be removed from the channel.

Preferably, as an alternative, the locking element is mounted on the floor slab body.

Preferably, as an embodiment, the locking member is a clip.

Preferably, as an implementation mode, the floor slab body comprises an upper floor slab and a lower floor slab, the upper floor slab is a cast-in-place floor slab, and the lower floor slab is a prefabricated floor slab.

Preferably, as an implementation mode, the floor slab body is a prefabricated floor slab, or the floor slab body is a cast-in-place floor slab.

Preferably, as an implementable mode, the radiant coil is a zigzag coil or an S-shaped coil.

Preferably, as an implementation mode, a gap between the radiant coil and the pipeline groove is filled with a filler.

Preferably, as an embodiment, the radiant coil is sunk in the conduit groove.

Preferably, as an implementation mode, the pipe detachable concrete floor for radiation further comprises a surface layer, and the surface layer covers the lower part of the floor body and the radiation coil pipe.

Preferably, as an embodiment, the facing layer comprises a gypsum layer and/or a decorative protective layer.

The utility model provides a removable concrete floor of pipeline for radiation's beneficial effect is:

the utility model provides a radiation pipeline detachable concrete floor, which mainly comprises a floor body, a radiation coil pipe and a locking piece, wherein the bottom of the floor body is provided with a pipeline groove, and the radiation coil pipe can be placed in the pipeline groove; above-mentioned locking piece has locking and opens two kinds of states, and the locking piece can switch between locking state and open mode, can lock the radiation coil pipe in pipeline ditch when the locking piece locks, can lose the locking effect to the radiation coil pipe when the locking piece is opened, and at this moment, the radiation coil pipe can be followed in the pipeline ditch and taken out.

When the radiant coil leaks water or has other problems and needs to be disassembled for maintenance, the locking piece in the locking state is switched to the opening state; then, taking the radiation coil out of the pipeline groove to replace the radiation coil or maintain the radiation coil; then, reinstalling the repaired radiant coil or a new radiant coil into the pipeline groove; finally, will be in the locking piece of open mode and switch into the locking state, so, the utility model provides a radiation is with removable concrete floor of pipeline, alright on the basis of not destroying major structure, accomplished radiation coil's dismantlement and maintained.

In addition, because the radiation coil can be installed in the pipeline groove on the floor slab body, the radiation coil occupies a smaller building floor height or does not occupy the building floor height at all; because the pipeline slot is arranged at the bottom of the floor slab body, the radiation coil arranged in the pipeline slot has stronger radiation capability, small thermal inertia and higher heat exchange efficiency.

It should be noted that, the utility model provides a removable concrete floor of pipeline for radiation not only can be used to the refrigeration, can also be used to winter radiation heating, and occupation space is less, and engineering cost is lower.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a cross-sectional view of a longitudinal sectional structure of a detachable concrete floor slab with a pipeline for radiation according to an embodiment of the present invention;

fig. 2 is a cross-sectional view of another longitudinal sectional structure of a detachable concrete floor slab with pipelines for radiation according to an embodiment of the present invention;

fig. 3 is a front view of a floor body in a radiation pipe detachable concrete floor provided in an embodiment of the present invention;

fig. 4 is a front view of another floor body in the pipe detachable concrete floor for radiation provided by the embodiment of the utility model.

Icon:

100-floor slab body; 110-upper floor slab; 120-lower floor slab; 130-reinforcing steel bars; 140-a pipe channel;

200-radiant coils;

300-surface layer.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The present invention will be described in further detail below with reference to specific embodiments and with reference to the attached drawings.

Referring to fig. 1 to 4, the present embodiment provides a radiation pipe detachable concrete floor, which mainly comprises a floor body 100, a radiation coil pipe 200 and a locking element, wherein a pipe groove 140 is formed at the bottom of the floor body 100, and the radiation coil pipe 200 can be placed in the pipe groove 140; the locking member has two states of locking and opening, and the locking member can be switched between the locking state and the opening state, and when the locking member is locked, the radiation coil 200 can be locked in the pipe groove 140, and when the locking member is opened, the locking effect on the radiation coil 200 can be lost, and at the moment, the radiation coil 200 can be taken out from the pipe groove 140.

When the radiant coil 200 leaks water or has other problems and needs to be disassembled for maintenance, the locking piece in the locking state is switched to be in the opening state; then, the radiant coil 200 is taken out of the pipe groove 140 to replace the radiant coil 200 or repair the radiant coil 200; then, reinstalling the repaired radiant coil 200 or a new radiant coil 200 into the pipe groove 140; finally, will be in the locking piece of open mode and switch into the locking state, so, the radiation that this embodiment provided is with removable concrete floor of pipeline, alright on the basis of not destroying major structure, accomplished radiation coil 200's dismantlement maintenance.

In addition, since the radiant coil 200 can be installed in the pipe groove 140 of the floor body 100, the radiant coil 200 occupies a small building floor height or does not occupy the building floor height at all; because the pipe groove 140 is formed at the bottom of the floor slab body 100, the radiation coil 200 installed in the pipe groove 140 has a strong radiation capability, a small thermal inertia, and a high heat exchange efficiency.

It should be noted that, the utility model provides a removable concrete floor of pipeline for radiation not only can be used to the refrigeration, can also be used to winter radiation heating, and occupation space is less, and engineering cost is lower.

Preferably, the locking member is installed on the floor body 100 so that the locking member is always connected to the floor body 100, and when the radiant coil 200 is disassembled, the locking member does not need to be separately placed, thus eliminating the trouble of storing the locking member and preventing the locking member from being lost due to improper storage.

As an implementable mode, can set up the locking piece and floor body 100 into integrated into one piece structure, not only can improve the stability of being connected between locking piece and the floor body 100, removed the loaded down with trivial details work that the later stage installation brought moreover from.

As another alternative, the locking member may be installed on the floor slab body after the floor slab body is formed.

A clip may be used as the locking member.

Specifically, the clip has a fixing portion, a movable portion and a connecting portion, wherein the fixing portion is fixedly connected with the floor slab body 100, so that the clip is connected with the floor slab body 100; the both ends of movable part are hinged end and link respectively, and the both ends of fixed part also are hinged end and link respectively, and the hinged end of movable part and the hinged end of fixed part are articulated each other, and the link of movable part passes through connecting portion with the link of fixed part can dismantle and be connected.

When the radiation coil 200 needs to be taken out, the connecting part can be operated to separate the connecting end of the movable part from the connecting end of the fixed part, and then the clamp is opened to take out the radiation coil 200 in the clamp; when the radiant coil 200 needs to be locked, the clamp is closed, and then the connection part is operated, so that the connection end of the movable part and the connection end of the fixed part are connected together, and the radiant coil 200 is locked in the pipe groove 140 by using the clamp, which is very convenient to operate.

Clips are very common locking elements that are either customizable or available directly from the market, which is less expensive than customization when less demand is needed.

The floor body in the pipe detachable concrete floor for radiation that this embodiment provided can adopt following three kinds of concrete structure.

First, referring to fig. 1, the floor slab body 100 is composed of an upper floor slab 110 and a lower floor slab 120, wherein the upper floor slab is a cast-in-place floor slab, and the lower floor slab 120 is a prefabricated floor slab. The lower floor 120 is fabricated in a factory (the fabricated lower floor includes the steel bar 130), then the lower floor 120 is directly transported to the site for installation, then the steel bar 130 is laid on the upper side of the lower floor 120, and finally the upper floor 110 is directly cast in the site.

It should be noted that the floor slab body 100 having the above-described specific structure is applicable to a prefabricated building.

Secondly, the whole floor slab body 100 is set as a prefabricated floor slab, the whole floor slab body 100 can be manufactured in a factory, and then the floor slab body 100 is directly transported to a site for installation, so that the assembly performance is stronger.

Thirdly, referring to fig. 2, the whole floor body 100 is a cast-in-place floor. During installation, two layers of reinforcing steel bars 130 are directly laid on site, and then the reproducing site is integrally cast to form the floor slab body 100.

Specifically, a zigzag coil or an S-shaped coil may be used as the above-described radiation coil 200.

It should be noted that, no matter which way the radiation coil 200 is arranged, the utilization rate of the floor slab body 100 can be improved, so that the heat exchange area of the radiation coil 200 is increased, and further, the heat exchange efficiency is improved.

It is preferred that adjacent sections of radiant coil 200 be equally spaced to provide more uniform heat distribution.

Preferably, a filler may be filled in the gap between the radiant coil 200 and the pipe groove 140, so that the radiant coil 200 and the pipe groove 140 are in close contact with each other through the filler, the heat of the radiant coil 200 can be uniformly transferred to the floor slab body, and the heat distribution is more uniform.

Further, the radiant coil 200 is sunk in the duct groove 140, that is, after the radiant coil 200 is installed in the duct groove 140, each part of the radiant coil 200 is located in the duct groove 140 and does not protrude out of the opening of the duct groove 140, so that the radiant coil 200 does not occupy an excessive building height.

Of course, the structure that the radiant coil protrudes from a part of the groove of the pipeline is also within the protection scope of the present invention.

Referring to fig. 1 and 2, the radiation pipe detachable concrete floor provided in this embodiment is further provided with a surface layer 300, and the surface layer 300 covers the floor body 100 and the radiation coil pipe 200, so that the pipe grooves 140 and the radiation coil pipe 200 are not exposed to the outside, the appearance is good, and a good visual effect can be obtained.

With the facing 300, if it is desired to remove the radiant coil 200, the facing 300 can be scraped and then the locking member can be opened without damaging the main structure of the floor slab body.

Specifically, the surface layer 300 may be provided as a gypsum layer; alternatively, the surface layer 300 may be a decorative protective layer; alternatively, the surface layer 300 may be provided with a gypsum layer and a decorative protective layer at the same time, and in such a structure, the decorative protective layer may be provided below the gypsum layer.

Certainly, the radiation that does not have the surface course is with removable concrete floor of pipeline is also in the scope of the utility model discloses the protection.

To sum up, the utility model discloses a pipeline detachable concrete floor for radiation, it has overcome a plurality of technical defects of traditional ceiling radiation system. The radiation pipeline detachable concrete floor provided by the embodiment can finish the detachment and maintenance of the radiation coil pipe 200 on the basis of not damaging the main body structure; in addition, the radiant coils 200 occupy less or no building floor height; meanwhile, the radiant coil 200 has strong radiant energy, small thermal inertia and high heat exchange efficiency.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A radiation pipeline detachable concrete floor is characterized by comprising a floor body (100), a radiation coil pipe (200) and a locking piece;

a pipeline groove (140) is formed in the bottom of the floor slab body (100), and the pipeline groove (140) is used for installing the radiant coil (200); said lock being switchable between a locked state and an open state, said lock when locked being capable of locking said radiant coil (200) within said pipe channel (140); when the lock is open, the radiant coil (200) can be removed from the conduit channel (140).

2. The concrete floor slab with detachable radiant piping according to claim 1, characterized in that said locking member is installed on said floor slab body (100).

3. The pipe detachable concrete floor for radiation according to claim 1, wherein said locking member is a clip.

4. The concrete floor slab with detachable radiation pipes of claim 1, wherein the floor slab body (100) comprises an upper floor slab (110) and a lower floor slab (120), the upper floor slab (110) is a cast-in-place floor slab, and the lower floor slab (120) is a precast floor slab.

5. The concrete floor slab with detachable radiation pipes according to claim 1, wherein the floor slab body is a prefabricated floor slab, or the floor slab body (100) is a cast-in-place floor slab.

6. The pipe detachable concrete floor for radiation according to claim 1, wherein the radiation coil pipe (200) is a zigzag coil pipe or an S-shaped coil pipe.

7. The pipe detachable concrete floor for radiation according to claim 1, wherein a gap between the radiation coil pipe (200) and the pipe groove (140) is filled with a filler.

8. The pipe detachable concrete floor for radiation according to claim 1, wherein said radiation coil pipe (200) is sunk in said pipe groove (140).

9. A radiant ducted demountable concrete floor according to any one of claims 1-8, wherein said floor body further comprises a face layer (300), said face layer (300) covering under said floor body (100) and said radiant coil (200).

10. The pipe detachable concrete floor for radiation according to claim 9, characterized in that said surface layer (300) comprises a gypsum layer and/or a decorative protective layer.

Images