CN213599461U - Assembled dry-type ground heating and composite heat preservation module thereof - Google Patents

Abstract

The utility model discloses an assembled dry-type floor heating and compound incubation module thereof, compound incubation module includes: the bottom of the support cushion block is used for connecting the ground; the heat insulation body with the upper surface flush with the upper surface of the supporting cushion block is positioned on one side of the supporting cushion block or positioned between the pair of supporting cushion blocks and is connected with the supporting cushion block or the pair of supporting cushion blocks into a whole; a heat-conductive reflective film arranged above the supporting cushion block and the heat insulation body; wherein, the heat preservation body and the heat-conducting reflecting film are connected together through a clamping structure or an adhesive. The utility model discloses a compound incubation module collection lip block, heat-insulating body, heat conduction reflection membrane in an organic whole, can prefabricate in the mill, the roughness is good, and intensity is high, directly mat formation can when the on-the-spot installation of building site is under construction, and the size cuts swiftly, and it is very convenient to install and use.

Description

Assembled dry-type ground heating and composite heat preservation module thereof

Technical Field

The utility model relates to a technical field warms up with the dry-type, in particular to assembled dry-type warms up and compound incubation module thereof.

Background

In recent years, floor heating systems are popular, and are divided into a water floor heating system and an electric floor heating system, and the water floor heating system is divided into a dry floor heating system and a wet floor heating system; the wet floor heating system usually adopts concrete backfill to bury a heating body, a heat insulation plate and a heat conduction reflection film, the concrete has high strength after being hardened, and a ceramic tile floor tile or a wood floor is laid on the concrete; dry floor heating refers to a novel dry construction scheme without concrete backfill.

At present, in the market, dry floor heating products are assembled by using materials such as independent heat insulators, heat-conducting reflecting films and the like on a construction site, all scattered materials need to be cut respectively when the size of the products is adjusted, the installation efficiency is very low, and the flatness is very poor after the products are constructed. In addition, the prior art directly lays the ceramic tile or the floor tile on the heat preservation body, and under the effect of long-term trampling or heavy object pressure, the ground can be caused to collapse and damage, and the maintenance or replacement cost is increased.

Disclosure of Invention

The utility model aims at solving the above problem, a warm up and compound incubation module thereof of assembled dry-type is provided, compound incubation module collection lip block, heat-insulating body, heat conduction reflection membrane in an organic whole, can prefabricate in the mill, and the roughness is good, and intensity is high, directly mat formation can when the construction site installation, and the size cuts swiftly, and it is very convenient to install and use.

In order to realize the above object of the utility model, the utility model provides a compound incubation module of usefulness is warmed up to assembled dry-type, include: the bottom of the support cushion block is used for connecting the ground; the heat insulation body with the upper surface flush with the upper surface of the supporting cushion block is positioned on one side of the supporting cushion block or positioned between the pair of supporting cushion blocks and is connected with the supporting cushion block or the pair of supporting cushion blocks into a whole; a heat-conductive reflective film arranged above the supporting cushion block and the heat insulation body; wherein, the heat preservation body and the heat-conducting reflecting film are connected together through a clamping structure or an adhesive.

Wherein, the joint structure includes: at least one groove disposed on an upper surface of the insulation; and the protrusion part is arranged on the heat-conducting reflecting film and is used for being inserted into the groove.

Preferably, the groove is an arc-shaped groove, and the protruding part is an arc-shaped protruding part.

Or, the groove is a wedge-shaped groove, and the protrusion is a wedge-shaped protrusion.

Or the groove is an omega-shaped groove, and the protruding part is an omega-shaped protruding part matched with the omega-shaped groove.

Furthermore, an open slot for installing a floor heating water pipe is formed in the upper surface of the protruding portion.

Preferably, the open slot is arc-shaped or wedge-shaped.

Furthermore, the heat preservation structure also comprises an inserting structure used for connecting the heat preservation body and the supporting cushion block into a whole.

Wherein, grafting structure includes: a side groove which is arranged on the side end surface of the supporting cushion block and is used for connecting the heat preservation body; and a side projection which is arranged on the side end surface of the heat preservation body for connecting the support cushion block and projects outwards.

Or, the plug structure includes: a side protrusion which is opened on the side end surface of the supporting cushion block for connecting the heat preservation body and protrudes outwards; and the side groove is arranged on the side end face of the heat preservation body for connecting the supporting cushion block.

Furthermore, the utility model provides an assembled dry-type floor heating, it includes a plurality of compound incubation modules as above.

Compared with the prior art, the utility model discloses an assembled dry-type floor heating and compound incubation module thereof has following advantage:

1. the utility model discloses an assembled dry-type floor heating and compound incubation module, collect lip block, heat-insulating body, heat conduction reflection membrane in an organic whole, can prefabricate in the mill, the roughness is good, intensity is high, directly when the construction site installation directly subaerial mat formation can, the size cuts swiftly, and it is very convenient to install and use.

2. The utility model discloses an assembled dry-type floor heating and compound incubation module, the bolster can be to the component of installing above this module like decoration panels such as ceramic tile or timber apron to the supporting role, tramples or can not sink under the heavy object pressure, improves the intensity and the life of module.

The embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Drawings

Fig. 1 is a schematic structural view of a first structure of the composite heat-insulating module for assembled dry floor heating of the utility model;

fig. 2 is a schematic structural view of a second structure of the composite heat-insulating module for the assembled dry floor heating of the utility model;

fig. 3 is a schematic structural view of a third structure of the composite heat-insulating module for the assembled dry floor heating of the utility model;

fig. 4 is an exploded view of a fourth construction of the composite thermal module for an assembled dry floor heating of the present invention;

fig. 5 is an exploded view of a first assembled dry floor heating structure of the present invention;

fig. 6 is an exploded view of the second structure of the assembled dry floor heating of the present invention.

Detailed Description

The utility model provides an assembled dry-type floor heating, it includes a plurality of compound incubation modules, and compound incubation module includes: the bottom of the support cushion block is used for connecting the ground; the heat insulation body with the upper surface flush with the upper surface of the supporting cushion block is positioned on one side of the supporting cushion block or positioned between the pair of supporting cushion blocks and is connected with the supporting cushion block or the pair of supporting cushion blocks into a whole; a heat-conductive reflective film arranged above the supporting cushion block and the heat insulation body; wherein, the heat preservation body is connected with the heat-conducting reflecting film through a clamping structure or an adhesive.

The assembled dry floor heating and composite heat insulation module of the utility model integrates the supporting cushion block, the heat insulation body and the heat conduction reflection film, can be prefabricated in a factory, has good flatness and high strength, can be directly paved on the ground when being installed and constructed on a construction site, has quick size cutting and is very convenient to install and use; in addition, the supporting cushion block can be used for supporting members arranged above the module, such as decorative panels of ceramic tiles or wood floors, and the like, and can not collapse under the pressure of trampling or heavy objects, so that the strength and the service life of the module expanded floor heating are improved.

Below, it is right the utility model discloses the structure of assembled dry-type floor heating and compound incubation module carries out detailed description.

Example 1

Fig. 1 is a schematic structural view of the composite heat preservation module for prefabricated dry floor heating according to the present embodiment (when the heat conductive reflective film C is not connected to the heat preservation body). As can be seen from fig. 1, the composite thermal insulation module of the present embodiment includes: a supporting cushion block A, a heat insulation body B and a heat-conducting reflecting film C. Wherein, the lip pad A is the cuboid bodily form, and heat-insulating body B also is the cuboid bodily form, and length is unanimous with lip pad A's length, settles in lip pad A one side and is connected as an organic whole through the mode that bonds with lip pad A, and during the preparation, the thickness of heat-insulating body B can be equivalent with lip pad A's thickness for after both connect as an organic whole, the upper surface parallel and level of heat-insulating body B and lip pad A's upper surface. And the heat-conducting reflecting film C is arranged above the supporting cushion block A and the heat preservation body B, the width of the supporting cushion block A and the heat preservation body B after being connected into a whole is consistent with that of the heat-conducting reflecting film C, and the heat-conducting reflecting film C is connected with the heat preservation body B through a clamping structure or an adhesive.

Wherein, when this embodiment adopted the joint structure, the joint structure can adopt following structure, include: a plurality of grooves B-1 are arranged on the upper surface of the heat insulator B at intervals along the width direction of the heat insulator B, each groove B-1 extends along the length direction of the heat insulator, and the extending length is consistent with the length of the heat insulator B; the plurality of convex parts C-1 are arranged on the heat conductive reflecting film C at intervals along the width direction of the heat conductive reflecting film C, and each convex part C-1 extends along the length direction of the heat conductive reflecting film C and the length of the convex part C-1 is consistent with the length of the heat conductive reflecting film C. When in design, the positions of the plurality of convex parts C-1 on the heat-conducting reflecting film C correspond to the positions of the plurality of grooves B-1 on the heat preservation body B one by one, so that the convex parts C-1 can be inserted into the corresponding grooves B-1.

The groove B-1 of the present embodiment is an omega-shaped groove (as shown in FIG. 1), and correspondingly, the protrusion C-1 is an omega-shaped protrusion having a shape corresponding to the shape of the groove B-1. it should be noted that the size of the protrusion C-1 is slightly smaller than that of the groove B-1, so that the protrusion C-1 can be correspondingly inserted into the groove B-1.

Further, in this embodiment, an open slot is further formed in the upper surface of the protruding portion C-1, so that the heating element 7 (the heating element 7 is shown in fig. 5 and fig. 6, that is, the floor heating radiating pipe) is disposed in the open slot, and the open slot may be in an Ω shape (see fig. 1) or a wedge shape (not shown in the figure).

During manufacturing, the supporting cushion block A can be made of one of wood plates, cement plates, calcium silicate plates, metal blocks and the like, the heat insulation body B can be made of one of extruded sheets, polystyrene plates, polyurethane plates and other heat insulation materials, and the heat-conducting reflective film C is a film body made of an aluminum plate, a copper plate and other metal materials easy to conduct heat. When the heat-conductive reflective film C is processed, the corresponding portion of the plate made of metal heat-conductive materials such as aluminum plate, copper plate, etc. can be bent according to the distance between the adjacent grooves B-1 on the heat-insulating body B, so as to form the heat-conductive reflective film C with the open grooves and the protrusions required by the embodiment.

During assembly, the side end surfaces of the support cushion block A and the heat preservation body B can be bonded into a whole through an adhesive, and the upper surfaces of the support cushion block A and the heat preservation body B and the lower surface of the heat-conducting reflection film C can also be bonded into a whole through an adhesive. Further, when the module of the present embodiment is installed on the ground, the lower surfaces of the shoe a and the heat insulator B may be fixed to the ground 1 by an adhesive. The adhesive may be a prior art adhesive.

Example 2

Fig. 2 is a schematic structural view of the composite thermal module of this embodiment (when the heat-conductive reflective film C is connected to the thermal insulator). As shown in fig. 2, the composite thermal insulation module of this embodiment has substantially the same structure as that of embodiment 1, except that, compared with embodiment 1, the composite thermal insulation module of this embodiment uses one more supporting cushion block a. In the following, only the differences will be described.

As shown in fig. 2, in this embodiment, a thermal insulation body B is disposed between a pair of the chock blocks a, and both side ends of the thermal insulation body B and the corresponding side end surfaces of the pair of chock blocks a are bonded together by an adhesive, respectively, and after being connected together, the thermal insulation body B is flush with the upper surfaces of the pair of chock blocks a.

During manufacturing, the length of the heat insulator B is the same as that of the pair of the supporting cushion blocks A, and the width of the heat-conducting reflecting film C is the same as that of the heat insulator B and the total width of the pair of the supporting cushion blocks A.

Example 3

Fig. 3 is a schematic structural view of the composite thermal module of this embodiment (when the heat-conductive reflective film C is not connected to the thermal insulator). As can be seen from fig. 3, the composite heat-insulating module of this embodiment has substantially the same structure as that of embodiment 1, except that, in the clamping structure for connecting the heat-conductive reflective film C and the heat-insulating body B of this embodiment, the plurality of grooves B-1 provided on the heat-insulating body B include an arc-shaped groove and a wedge-shaped groove, the plurality of protrusions provided on the heat-conductive reflective film C include a wedge-shaped protrusion and an arc-shaped protrusion, and the positions of the wedge-shaped protrusion and the arc-shaped protrusion on the heat-conductive reflective film C correspond to the positions of the wedge-shaped groove and the arc-shaped groove on the heat-insulating body B, respectively.

When the heat-conducting reflecting film C, the heat insulator B and the supporting cushion block A are assembled together, the wedge-shaped convex parts and the arc-shaped convex parts on the heat-conducting reflecting film C are inserted into the wedge-shaped grooves and the arc-shaped grooves of the heat insulator B one by one.

Example 4

Fig. 4 is an exploded view of the composite thermal module of this embodiment. As shown in fig. 4, the composite thermal insulation module of this embodiment has substantially the same structure as that of embodiment 1, except that the thermal insulation body B and the spacer block a of this embodiment can be connected together by a plug structure.

As shown in fig. 4, the insertion structure of the present embodiment includes: a side groove arranged on the side end face of the supporting cushion block A for connecting the heat preservation body B; and a side protrusion which is arranged on the side end surface of the heat preservation body B for connecting the support cushion block A and protrudes outwards.

During assembly, the side protrusions of the heat insulator B are inserted into the side grooves of the spacer A to integrally connect the two.

Example 5

The structure of the composite thermal insulation module of this embodiment is substantially the same as that of embodiment 4 (not shown in the drawings), except that the plug-in structure for integrally connecting the thermal insulation body B and the supporting cushion block a of this embodiment includes: side protruding parts which are opened on the side end surfaces of the supporting cushion blocks and used for connecting the heat preservation bodies and protrude outwards; and the side groove is arranged on the side end face of the heat insulation body for connecting the support cushion block.

The manner in which the insulation B and the spacer blocks a are inserted is the same as in example 4, and will not be described again.

Example 6

The structure of the composite thermal insulation module of this embodiment is substantially the same as that of embodiment 4 or embodiment 5 (not shown in the drawings), except that in this embodiment, after the thermal insulation body B and the supporting cushion block a are connected into a whole through the plugging structure of the above embodiment, an adhesive can be coated on the plugging surfaces of the two, so that the connection between the two is more reliable.

Example 7

As shown in fig. 5, it can be seen that the assembled dry floor heating of the present embodiment includes a plurality of composite heat preservation modules (only two are shown in the figure), and the plurality of composite heat preservation modules adopt the structure of embodiment 1, that is, the composite heat preservation modules include a supporting cushion block, a heat preservation board and a heat-conductive reflection film, and further include a protection board 6 disposed above the composite heat preservation modules and a decoration panel 5 disposed above the protection board 6.

During assembly, a plurality of composite heat preservation modules are sequentially fixed on the ground 1 through adhesives to form a composite heat preservation layer, a plurality of heating bodies 7 are respectively inserted into a plurality of open grooves in the formed composite heat preservation layer, and the heating bodies 7 can adopt floor heating water pipes, heating cables, carbon fiber heating bodies and the like. After the heating element 7 is inserted into the opening groove of the heat conductive reflecting film C, the heat emitted from the heating element 7 is conducted to the protection plate 6 and the decoration panel 5 above the heat conductive reflecting film C through the heat conductive reflecting film C, and finally the heat is radiated into the whole building room.

Wherein, the protection shield 6 can adopt cement board, calcium silicate board, glass magnesium board etc. and its accessible screw is connected fixedly with the lip block A of below to the heat-insulating body B, heat-generating body 7, the heat conduction reflection film C that are located its below are protected, prevent that these components from damaging, and protection shield 6 has higher intensity simultaneously, pastes the decorative cover 5 of installation and plays the supporting role to the top, prevents under the gravity action such as furniture, artificial trampling, leads to whole dry floor heating system to destroy and cave in. The protection balance plate has higher flatness, and can provide a working surface with higher flatness for the decorative surface layer bonded above the protection balance plate.

The decorative panel 5 can be ceramic tile or wood floor or other panel with decorative function, and is fixedly arranged above the protective panel 6 by sticking.

Example 8

As shown in fig. 6, it can be seen that the structure of the assembled dry floor heating of this embodiment is basically the same as that of embodiment 7, but the difference is that, in the multiple composite heat insulation modules adopted in this embodiment, the composite heat insulation modules in embodiment 1 and embodiment 2 are sequentially arranged along the ground 1. That is, one of the composite heat-insulating modules has a structure shown in fig. 1, and is a module including one of the backup pads, one of the heat-insulating boards, and one of the heat-conductive reflective films, and the other of the composite heat-insulating modules has a structure shown in fig. 2, and is a module including a pair of the backup pads, one of the heat-insulating boards, and one of the heat-conductive reflective films, and similarly, the protective board 6 is disposed above the composite heat-insulating module, and the decorative panel 5 is disposed above the protective board 6.

Example 9

The assembled dry floor heating system provided by this embodiment may adopt a structure in which the composite heat insulating modules in embodiments 1 to 6 are mutually matched to form a composite heat insulating layer, in addition to the structure of embodiments 7 and 8. The structure of the composite insulating layer is similar to that of example 7, and the description thereof is omitted.

Although the embodiments of the present invention have been described in detail, the embodiments of the present invention are not limited thereto, and those skilled in the art can modify the principles of the embodiments of the present invention, and therefore, various modifications performed according to the principles of the embodiments of the present invention should be understood as falling into the scope of the embodiments of the present invention.

Claims (10)

1. The utility model provides a compound incubation module that assembled dry-type ground heating used which characterized in that includes:

the bottom of the support cushion block is used for connecting the ground;

the heat insulation body with the upper surface flush with the upper surface of the supporting cushion block is positioned on one side of the supporting cushion block or positioned between the pair of supporting cushion blocks and is connected with the supporting cushion block or the pair of supporting cushion blocks into a whole;

a heat-conductive reflective film arranged above the supporting cushion block and the heat insulation body;

wherein, the heat preservation body and the heat-conducting reflecting film are connected together through a clamping structure or an adhesive.

2. The composite insulating module of claim 1, wherein the snap-fit structure comprises:

at least one groove disposed on an upper surface of the insulation;

and the protrusion part is arranged on the heat-conducting reflecting film and is used for being inserted into the groove.

3. The composite insulation module of claim 2, wherein the groove is an arcuate slot and the projection is an arcuate projection.

4. The composite insulation module of claim 2, wherein the groove is a wedge-shaped groove and the projection is a wedge-shaped projection.

5. The composite insulating module of claim 2, wherein the groove is an omega-shaped groove and the protrusion is an omega-shaped protrusion that mates with the omega-shaped groove.

6. The composite heat preservation module of claim 2, wherein an open groove for installing a floor heating water pipe is provided on an upper surface of the protrusion.

7. The composite insulation module of claim 1, further comprising a plug-in structure for integrally connecting the insulation body to the bolster block.

8. The composite insulation module of claim 7, wherein the plug-in structure comprises:

a side groove which is arranged on the side end surface of the supporting cushion block and is used for connecting the heat preservation body;

and a side projection which is arranged on the side end surface of the heat preservation body for connecting the support cushion block and projects outwards.

9. The composite insulation module of claim 7, wherein the plug-in structure comprises:

a side protrusion which is opened on the side end surface of the supporting cushion block for connecting the heat preservation body and protrudes outwards;

and the side groove is arranged on the side end face of the heat preservation body for connecting the supporting cushion block.

10. An assembled dry floor heating system comprising a plurality of composite thermal modules as claimed in any one of claims 1 to 9.

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