CN215802912U - Assembled multipurpose heating module and heating system - Google Patents

Abstract

The utility model provides a fabricated multipurpose heating module and a heating system. The heating module comprises a heat insulation layer, and a heating body groove for embedding a heating body is formed in the upper surface of the heat insulation layer. The reflective layer covers an upper surface of the thermal insulating layer and is bonded to the thermal insulating layer. The surface of the heating body groove is covered by the reflecting layer. The side surface of the heat insulation layer is provided with a clamping structure for forming clamping connection with a clamping structure with a complementary shape of an adjacent heating module. According to the utility model, the adjacent heating modules can form clamping connection, so that the installation is convenient; the reflecting layer is combined with the heat insulation layer, and the reflecting layer and the heat insulation layer are not easy to separate; the heat insulation layer and the reflecting layer can be assembled simultaneously in one-step assembly in site construction, and separate construction is not needed, so that the construction difficulty is simplified; moreover, the reflecting layer covers the whole upper surface of the heat insulation layer, particularly the heat insulation layer for isolating the heating body and the heating body groove, so that heat radiation generated by the heating body can be effectively reflected to the upper space, and the heat insulation effect and the heating efficiency are improved.

Description

Assembled multipurpose heating module and heating system

Technical Field

The utility model relates to the technical field of floor heating, in particular to an assembled multipurpose heating module and a heating system assembled by the same.

Background

Floor heating is a very popular heating model. According to the hot water pipe or the heating cable, the system can be divided into a water floor heating system and an electric floor heating system. In the aspect of construction, according to whether concrete backfill is needed or not, dry construction site heating and wet construction floor heating can be separated. Regardless of the heating body and the construction method, a heat insulation layer is usually laid on a flat ground, and then the heating body is laid on the heat insulation layer. The structure and the performance of the heat-insulating layer have great influence on the heating, heat insulation, moisture prevention, construction and other aspects of the floor heating system.

In the prior art, a solution for forming a heat insulation layer by splicing heating modules is provided, however, a gap at a splicing part is usually large, heat is easy to spread, the heat insulation effect is weakened, and uneven heating is caused; moreover, a reflecting layer needs to be additionally paved, so that the construction complexity is increased, and the reflecting layer and the heat insulation layer are separated from each other, so that the separation is easy to occur; applying the heating body directly on the flat surface of the insulation layer also takes up room height.

Therefore, in practice, a heating module for building a floor heating system, which has the advantages of good heat insulation effect, convenience in construction and installation and small occupied height and space, is urgently needed to be provided.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide an assembled multipurpose heating module to at least solve the problems of uneven heating, inconvenient installation, easy delamination and the like in the prior art.

To achieve the above object, in a first aspect of the present invention, there is provided a warming module including: the upper surface of the heat insulation layer is provided with a heating body groove for embedding a heating body; and a reflective layer covering the upper surface of the thermal insulation layer and combined with the thermal insulation layer; wherein the surface of the heating body groove is covered by the reflecting layer; the side surface of the heat insulation layer is provided with a clamping structure for forming clamping connection with a clamping structure with a complementary shape of an adjacent heating module.

According to the scheme, the adjacent heating modules can form clamping connection, so that the installation is convenient; the reflecting layer is combined with the heat insulation layer, and the reflecting layer and the heat insulation layer are not easy to separate; the heat insulation layer and the reflecting layer can be assembled at the same time by assembling the heating module in one step in site construction, and separate construction is not needed, so that the construction difficulty is simplified; moreover, the reflecting layer covers the whole upper surface of the heat insulation layer, particularly the heat insulation layer for isolating the heating body and the heating body groove, so that heat radiation generated by the heating body can be effectively reflected to the upper space, and the heat insulation effect and the heating efficiency are improved.

Optionally, the insulation layer has a rectangular profile, with snap-in structures provided on all four side surfaces thereof.

Optionally, the first side surface of the heat insulation layer is provided with a first clamping portion with an upward protruding triangular cross section, and a first clamping groove with a downward protruding triangular cross section is formed between the first clamping portion and the first side surface of the heat insulation layer; the second clamping groove is formed between the second clamping part and the second side surface of the heat insulation layer; the first clamping part and the second clamping groove are complementary in shape, and the second clamping part and the first clamping groove are complementary in shape.

According to the scheme, the triangular clamping part and the clamping groove are easy to form firm clamping connection, and the field assembly construction is convenient; moreover, the clamping part and the clamping groove can form a basically seamless assembly part, so that the heat dissipation, moisture permeation and sound transmission through the gap can be effectively reduced, and the heat preservation effect, the moisture-proof effect and the sound insulation effect can be improved.

Optionally, the heating body groove is a tubular groove with an open upper side, and the reflective layer covers an inner surface of the tubular groove.

Optionally, the thermal insulation layer is a polyurethane plate, and the reflective layer is an aluminum foil. It is known in the art that polyurethane boards have excellent heat insulating, moisture preventing, flame retarding, sound insulating, etc. effects, and are used as heat insulating layers, so that the heating module can achieve excellent heat insulating, moisture preventing, flame retarding, sound insulating, etc. effects, i.e., achieve versatility.

Optionally, the size of the warming module is 600 × 600mm, 800 × 800mm or 1200 × 1200 mm. These dimensions match those of commercially available tile or wood flooring, thereby facilitating design and construction.

Optionally, the width of the heating body groove is in the range of 10-150 mm. The shape and size of the heating body groove may be appropriately selected according to the shape and size of the heating body.

In a second aspect of the present invention, there is provided a heating system comprising: a plurality of thermal modules, each thermal module comprising: the upper surface of the heat insulation layer is provided with a heating body groove for embedding a heating body; and a reflective layer covering the upper surface of the thermal insulation layer and combined with the thermal insulation layer; wherein the surface of the heating body groove is covered by the reflecting layer; the side surface of the heat insulation layer is provided with a clamping structure for forming clamping connection with a clamping structure with a complementary shape of an adjacent heating module; the heating body is embedded into the heating body groove of the heating module, so that part of the reflecting layer is positioned between the heating body and the heat insulation layer; the heat conduction layer is arranged above the heating module and the heating body; and a decorative layer disposed over the heat conductive layer.

Optionally, the heating body is a water pipe or a heating cable. Therefore, the heating system can be a hydrothermal heating system or an electric heating system.

Optionally, the decorative layer is a tile or a wood floor.

Drawings

FIG. 1 illustrates a cross-sectional schematic view of a modular multipurpose heating module according to the present invention;

fig. 2 shows a schematic partial cross-sectional view of a heating system built using the heating module of fig. 1;

fig. 3 shows a schematic top view of a heating system built up with a plurality of heating modules of fig. 1.

Reference numerals: 11 a warming module; 1, a heat insulation layer; 2 a reflective layer; 3 heating body groove; 4 a first engaging portion; 5 a first clamping groove; 6 a second engaging portion; 7 a second engaging groove; 8, heating body; 9 a heat conducting layer; 10 a decorative layer; 21 a top layer portion; 22 heating body slot portions.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

The utility model provides a fabricated multipurpose heating module 11 which is used for being spliced with each other to form a heating system, such as a floor heating system. The heating module 11 is plate-shaped as a whole. Fig. 1 shows a schematic cross-sectional view of a warming module 11 according to the utility model. As shown, the warming module 11 includes an insulating layer 1 and a reflective layer 2. The upper surface of the heat insulation layer 1 is provided with a heating body groove 3 for embedding a heating body 8. The reflective layer 2 is disposed on the upper surface of the heat insulating layer 1 and is firmly bonded thereto. The reflective layer 2 has a top layer portion 21 covering the top surface of the heat insulating layer 1, and also has a heating body groove portion 22 covering the upper surface of the heating body groove 3. The top layer portion 21 and the heating body groove portion 22 are connected to each other. The reflective layer 2 thus completely covers the entire upper surface of the insulating layer 1. Therefore, the reflective layer 2 can reflect heat radiation from the heating body upward, and heat loss due to penetration through the heat insulating layer 1 can be reduced.

The heat insulation layer 1 can be made of a material having characteristics of heat insulation, sound insulation, moisture resistance, light weight and the like. For example, the heat insulation layer 1 may be made of inorganic modified polyurethane material or other high-performance heat insulation material. The reflective layer 2 may be made of a material having a property of reflecting heat radiation, such as aluminum foil.

The four side surfaces of the heat insulation layer 1, namely the front surface, the rear surface, the left surface and the right surface, are respectively provided with a clamping structure for forming basically seamless and firm clamping connection between the adjacent heating modules 11. Fig. 1 shows the engagement structure on the left and right sides of the heat insulating layer 1. On the first side/right side of the insulation layer 1, a first engaging portion 4 protrudes from the insulation layer 1, and a first engaging groove 5 is formed between the first engaging portion 4 and the side surface of the insulation layer 1. On the second side/left side of the insulation layer 1, a second engaging portion 6 protrudes from the insulation layer 1, and a second engaging groove 7 is formed between the second engaging portion 6 and the side surface of the insulation layer 1. In particular, the first engagement portion 4 and the second engagement groove 7 and the second engagement portion 6 and the second engagement groove 5 are complementary in shape, whereby the engagement structures of adjacent heating modules 11 can be complementarily engaged with each other, thereby achieving easy, reliable and gap-free assembly.

In the embodiment shown in fig. 1, the first engaging portion 4 has an upwardly convex triangular cross section, the first engaging groove 5 has a downwardly convex triangular cross section, the second engaging portion 6 has a downwardly convex triangular cross section, and the second engaging groove 7 has an upwardly convex triangular cross section. A triangular cross-section is a preferred embodiment and other shapes, such as rectangular, trapezoidal, circular snap and snap groove shapes, can be used in the heating module of the utility model as well.

The size specification of the heating module 11 may be 600 × 600mm, 800 × 800mm, 1200 × 1200mm to fit with the size of the commercially available tile or wood floor, and may be arbitrarily cut to facilitate on-site construction.

The heat insulation layer 1 and the reflecting layer 2 in the heating module 11 are combined in advance through manufacturing, and the heat insulation layer 1 and the reflecting layer 2 do not need to be separately constructed on site. Specifically, in the link of moulding plastics, the material of insulating layer 1 and reflection stratum 2 is applyed in proper order in the die cavity for reflection stratum 2 is located the upper surface of insulating layer 1, and the two uses the mould with the profile phase-match of heating body 8 to carry out pressure working to the material in the die cavity, makes the heating body groove 3 that forms adaptation heating body 8 profile, makes reflection stratum 2 cover a plurality of detached heating body grooves 3 in succession moreover. The specific shape and dimensions of the heating body tank 3 can be set according to the actual shape and dimensions of the heating body 8 used, and can be, for example, a continuous round tubular shape, as shown in fig. 1; for example, the width of the heating body groove 3 may be 10 to 150 mm; furthermore, the heating body groove 8 may be formed by a plurality of small bosses separated from each other, forming a heating module in the form of a so-called "weiqi board".

The heating module 11 of the utility model can have heating body grooves 3 of various shapes, thus adapt to the heating bodies 8 of various shapes and sizes and different construction modes thereof, and does not depart from the main conception of the utility model, namely, the reflecting layer 2 is paved and combined on the upper surface of the heat insulation layer 1 with the heating body grooves 3 in advance, so that the reflecting layer 2 can be firmly combined with the heat insulation layer 1, two steps of construction on site are saved, and the construction is simplified; moreover, the reflecting layer 2 continuously covers the top surface of the heat insulation layer 1 and the upper surface of the heating body groove 3, when the heating body 8 in the heating body groove 3 starts to work, the heat generated by the heating body is upwards reflected by the reflecting layer 2, and the heating body cannot excessively penetrate through the heat insulation layer 1 to be downwards transmitted, so that the upper and lower heat insulation is improved, and the heating efficiency is improved.

Fig. 2 shows a schematic partial cross-sectional view of an exemplary heating system formed using the heating module 11 shown in fig. 1. A heating body 8 is embedded in the heating body groove 3 of fig. 1. The heating body 8 may be a hot water pipe, for example, for implementing a hydrothermal floor heating system, or may be a heating cable, for example, for implementing an electrothermal floor heating system. The heating body 8 is completely embedded in the heating body groove 3, and the upper surface of the heating body 8 is lower than the upper surface of the heating module 11, which facilitates the implementation of dry construction, i.e., construction without concrete backfill, because the heating body 8 does not protrude upward, which does not interfere with the laying of the upper layer material. And a heat conduction layer 9 and a decoration layer 10 are sequentially laid on the upper side of the heating module 11 embedded with the heating body 8, so that the construction of a heating system is completed. Heat conductive layer 9 may be made of a heat conductive, wear resistant, resilient material to assist in the mounting of upper decorative layer 10. The heat conducting layer 9 can be made of mica plate, graphene modified plastic heat conducting material or other heat conducting materials. Decorative layer 10 may be a ceramic tile or a wood floor.

Fig. 3 shows a schematic top view of an exemplary heating system formed using the heating module 11 shown in fig. 1. The heating system is assembled by a plurality of heating modules 11 (four heating modules 11 are shown in fig. 3) being snap-fitted to each other, in particular by means of complementary snap-fit portions and snap-fit grooves on the adjoining side surfaces of adjacent heating modules 11 shown in fig. 1. Therefore, the plurality of heating modules 11 can form seamless connection parts, especially, the assembly of the clamping parts and the clamping grooves forms nonlinear joints, and compared with the joints in a vertical straight through mode, the joints can block heat, moisture, noise and the like from spreading downwards along the joints, thereby further improving heat insulation, improving heating efficiency and improving moisture-proof and sound-proof effects. The mutual assembly of the clamping part and the clamping groove is simple and convenient, and the subsequent construction is also convenient. The alignment of the heating body slots 3 of adjacent heating modules 11 with each other enables the continuous laying of the heating bodies 8 across a plurality of heating modules 11, as shown in fig. 3.

The heating module is assembled, so that the on-site assembly and splicing can be realized; also has multiple purposes, namely, multiple purposes such as heat insulation, heat radiation reflection, sound insulation, moisture resistance and the like.

The heating module and the heating system can be a floor heating module and a floor heating system, and can also be other heating modules and heating systems used in other occasions.

Exemplary embodiments of the present invention have been described in detail herein with reference to the preferred embodiments, however, it will be understood by those skilled in the art that various changes and modifications may be made to the specific embodiments described above and various combinations of the various features and structures presented in the present invention without departing from the spirit of the utility model, the scope of which is defined by the appended claims.

Claims (10)

1. A modular multipurpose thermal module comprising:

the upper surface of the heat insulation layer is provided with a heating body groove for embedding a heating body; and

a reflective layer covering the upper surface of the heat insulating layer and combined with the heat insulating layer;

wherein the surface of the heating body groove is covered by the reflecting layer;

the side surface of the heat insulation layer is provided with a clamping structure for forming clamping connection with a clamping structure with a complementary shape of an adjacent heating module.

2. The modular multipurpose heating module according to claim 1,

the heat insulation layer has a rectangular outline, and clamping structures are arranged on four side surfaces of the heat insulation layer.

3. The fabricated multipurpose heating module according to claim 1 or 2,

the first side surface of the heat insulation layer is provided with a first clamping part with an upward protruding triangular cross section, and a first clamping groove with a downward protruding triangular cross section is formed between the first clamping part and the first side surface of the heat insulation layer;

the second clamping groove is formed between the second clamping part and the second side surface of the heat insulation layer;

the first clamping part and the second clamping groove are complementary in shape, and the second clamping part and the first clamping groove are complementary in shape.

4. The modular multipurpose heating module according to claim 1,

the heating body groove is a tubular groove with an open upper side, and the reflecting layer covers the inner surface of the tubular groove.

5. The modular multipurpose heating module according to claim 1,

the heat insulation layer is a polyurethane plate, and the reflecting layer is an aluminum foil.

6. The modular multipurpose heating module according to claim 1,

the size of the heating module is 600mm multiplied by 600mm, 800mm multiplied by 800mm or 1200mm multiplied by 1200 mm.

7. The modular multipurpose heating module according to claim 1,

the width of the heating body groove is within the range of 10-150 mm.

8. A heating system, comprising:

a plurality of the fabricated multipurpose heating modules of any one of claims 1 to 7,

the heating body is embedded into the heating body groove of the heating module, so that the partial reflecting layer is positioned between the heating body and the heat insulation layer;

the heat conduction layer is arranged above the heating module and the heating body; and

and the decorative layer is arranged above the heat conduction layer.

9. The warming system according to claim 8,

the heating body is a water pipe or a heating cable.

10. The warming system according to claim 8,

the decorative layer is a ceramic tile or a wood floor.

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