CN217057671U - Overhead dry-method floor heating module - Google Patents

Abstract

The utility model discloses an overhead dry method floor heating module, the structural layer upper surface is provided with a plurality of first eyelidretractors, first eyelidretractor top is equipped with the floor heating module layer board, the floor heating module layer board upper surface is provided with a plurality of second eyelidretractors, second eyelidretractor top is provided with the decoration base plate, decoration base plate upper surface is provided with the finish coat; be equipped with water pipe and electric pipe around the first eyelidretractor, be provided with ground heating coil, heated board, thermal radiation membrane around the second eyelidretractor. The device is fast to install, the floor heating module, the support and the like can be fast installed, and dry construction is adopted for fixing the support, installing the module, coiling the pipe, decorating the base plate and leveling during installation; the heat dissipation rate is high, the fiber reinforced calcium silicate board subjected to anti-seepage treatment is a decorative base layer board, the heat conductivity reaches more than 85%, the energy consumption is low, and the foot feel is comfortable; easy to maintain, along with the live time is long, the intraductal incrustation scale that has deposited of heating, can pull down the water pipe and wash or change, have the advantage of quick detach fast-assembling than other underfloor heating systems.

Description

Overhead dry-method floor heating module

Technical Field

The utility model relates to a fitment module technical field, concretely relates to module warms up built on stilts dry method.

Background

The overhead dry-method floor heating module is further developed on the basis of an assembled overhead ground, the key point of the assembly is high integration and adaptability, and a heating pipe, a thermal radiation film and a heat-insulation extruded sheet are added in a module structure of the assembled overhead ground, so that the floor heating ground with high ground heat dissipation rate can be realized, and a composite floor heating module is formed.

SUMMERY OF THE UTILITY MODEL

Therefore, the utility model provides an overhead dry method floor heating module to solve the above-mentioned problem among the prior art.

In order to achieve the above object, the present invention provides the following technical solutions:

according to the utility model discloses a first aspect, an overhead dry floor heating module, including structural layer, first eyelidretractor, water pipe, floor heating module layer board, floor heating pipe, second eyelidretractor and finish coat; the upper surface of the structural layer is provided with a plurality of first supporters, the top ends of the first supporters are provided with the floor heating module supporting plate, the upper surface of the floor heating module supporting plate is provided with a plurality of second supporters, and the top ends of the second supporters are provided with the finish coat; the water pipe is arranged around the first support, and the ground heating pipe is arranged around the second support.

Further, the decorative base plate is arranged between the top end of the second support and the decorative layer.

Further, the finishing layer is any one of a floor, a floor tile and a carpet.

Further, still include the spool, be provided with around the first eyelidretractor the spool.

Furthermore, the floor heating module comprises a heat insulation plate, the floor heating module supporting plate is arranged between the decorative base plate and the heat insulation plate, and the floor heating pipe is installed in a groove formed in the upper surface of the heat insulation plate.

Further, still include the heat radiation membrane, the upper surface of heated board is laid the heat radiation membrane.

Furthermore, the floor heating system also comprises a water separator, and the plurality of floor heating pipes are connected with the water separator.

Furthermore, the floor heating module supporting plate is of an integrated structure formed by cutting a fiber-reinforced calcium silicate plate subjected to anti-permeation treatment, and the decorative base plate is of an integrated structure formed by cutting a fiber-reinforced calcium silicate plate subjected to anti-permeation treatment.

Furthermore, the specification of ground heating module layer board is 800mm 1200mm 10mm, and the specification of decorating the base plate is 800mm 1200mm 20 mm.

Further, when the finishing layer is a floor tile, the floor tile is customized, the customized thickness is not less than 20mm, and the specification of the floor tile is any one of 300mm x 300mm, 600mm x 600mm, 600mm x 1200mm, 450mm x 900mm, 800mm x 800mm, 900mm x 900mm and 900mm x 1800 mm.

The utility model has the advantages of as follows: the device is fast to install, the floor heating module, the support and the like can be fast installed, and the support is fixed, the module is installed, the coil pipe, the decorative base plate and the leveling are completed in one go by adopting dry construction during installation; the heat dissipation rate is high, the fiber reinforced calcium silicate board subjected to anti-seepage treatment is a decorative base layer board, the heat conductivity reaches more than 85%, the energy consumption is low, and the foot feel is comfortable; easy to maintain, along with the live time is long, the incrustation scale has been depositd in the heating pipe, can pull down the water pipe and wash or change, has the advantage of quick detach fast-assembling than other underfloor heating systems.

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 description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a sectional view of an overhead dry floor heating module provided by some embodiments of the present invention.

Fig. 2 is a sectional view of an overhead dry floor heating module provided by other embodiments of the present invention.

In the figure: 1. structural layer, 2, water pipe, 3, first eyelidretractor, 4, warm up the module layer board, 5, ground heating coil, 6, decorate the basal plate, 7, finish coat, 8, spool, 9, thermal radiation membrane, 10, second eyelidretractor, 11, heated board.

Detailed Description

The present invention is described in detail with reference to the specific embodiments, and other advantages and effects of the present invention will be apparent to those skilled in the art from the disclosure herein. 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.

As shown in fig. 1 or fig. 2, in an embodiment of the first aspect of the present invention, the overhead dry-method floor heating module includes a structural layer 1, a first supporter 3, a water pipe 2, a floor heating module supporting plate 4, a floor heating pipe 5, a second supporter 10, and a finish layer 7; the upper surface of the structural layer 1 is provided with a plurality of first supporters 3, the top ends of the first supporters 3 are provided with floor heating module supporting plates 4, the upper surface of the floor heating module supporting plate 4 is provided with a plurality of second supporters 10, and the top ends of the second supporters 10 are provided with the finish coat layer 7; the water pipe 2 is arranged around the first supporter 3, and the ground heating pipe 5 is arranged around the second supporter 10.

In the above embodiment, it should be noted that the ground ABS plastic support is a support member, a support surface with a uniform elevation is formed by adjusting the height of the support, and the impermeable calcium silicate board and other base layer boards are mounted on the first support 3 to form the floor heating module supporting board 4.

In the embodiment, two schemes of fig. 1 or fig. 2 are included, in which fig. 1 illustrates a scheme of arranging a decorative base layer board 6 between a second supporter 10 and a finishing layer 7, and fig. 2 illustrates a scheme of directly arranging the finishing layer 7 on the top of the second supporter 10, namely, thickening a floor tile (i.e., a customized floor tile).

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, a decorative base layer board 6 is further included, and the decorative base layer board 6 is disposed between the top end of the second supporter 10 and the finishing layer 7.

In the above alternative embodiment, it should be noted that the base layer plate 6 formed by the impermeable-treated calcium silicate board or the like is mounted on the second support 10.

Alternatively, as shown in fig. 1 or 2, in some embodiments, the finishing layer 7 is any one of a floor, a floor tile, and a carpet.

In the alternative embodiment described above, it should be noted that the finishing layer 7 may also be other finishing structures than those described above.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, the support further includes a conduit 8, and the conduit 8 is disposed around the first supporter 3.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, the floor heating module further includes a heat insulation board 11, the heat insulation board 11 is disposed between the floor heating module supporting board 4 and the decorative base plate 6, and the floor heating pipe 5 is installed in a groove formed in the upper surface of the heat insulation board 11.

In the above optional embodiment, it should be noted that the insulation board 11 is a flame retardant polyphenyl insulation board, for example, the specification of the flame retardant polyphenyl insulation board is 800mm by 1200mm by 30 mm.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, the heat insulation board further includes a heat radiation film 9, and the heat radiation film 9 is laid on the upper surface of the heat insulation board 11.

In the above alternative embodiment, it should be noted that the heat radiation film 9 is also disposed in the groove provided on the upper surface of the heat insulating plate 11.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, a water separator is further included, and the plurality of floor heating pipes 5 are all connected to the water separator.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, the floor heating module supporting plate 4 is an integrated structure formed by cutting a fiber-reinforced calcium silicate plate subjected to anti-permeation treatment.

Optionally, as shown in fig. 1 or fig. 2, in some embodiments, the size of the floor heating module support plate 4 is 800mm by 1200mm by 10 mm.

In the above alternative embodiment, it should be noted that when the overhead height is greater than or equal to 40mm, the specification of the fiber reinforced calcium silicate plate subjected to the anti-permeation treatment is 800mm × 1200mm × 10mm, and the plate can be customized according to the design requirements in the factory.

Alternatively, as shown in fig. 1 or 2, in some embodiments, the decorative substrate sheet 6 is a unitary structure cut from a fiber-reinforced calcium silicate sheet that has been subjected to an infiltration-resistant treatment.

Alternatively, as shown in fig. 1 or 2, in some embodiments, the decorative base sheet 6 has a gauge of 800mm by 1200mm by 20 mm.

In the above alternative embodiment, it should be noted that the decorative base sheet 6 may be factory customized according to design requirements.

Optionally, as shown in fig. 2, in some embodiments, when the finishing layer 7 is a floor tile, the floor tile is customized to have a thickness of 20mm or more, and the specification of the floor tile is any one of 300mm by 300mm, 600mm by 600mm, 600mm by 1200mm, 450mm by 900mm, 800mm by 800mm, 900mm by 900mm, and 900mm by 1800 mm.

In the alternative embodiment described above, it should be noted that the custom tiles 7 can be factory cut according to design requirements.

The floor heating module mainly comprises a supporter, a flame-retardant polyphenyl insulation board, a thermal radiation film, a water separator, a floor heating pipe, a decorative layer, a decorative base plate or thickened floor tiles, a floor heating module supporting board, special structural adhesive, silane modified nail-free adhesive and the like.

Application scope of the present application: the integrated heating part can be applied to all dry floor heating buildings taking water heating as a heat source.

Integrated floor heating technology preparation and operation conditions:

1. familiarizing the construction drawing and the site, and making technical, environmental and safe trades;

2. a ground control line is placed according to a design drawing, and the position is accurate;

3. concealed acceptance inspection such as installation of pipelines in the overhead layer is required to be completed;

4. finishing the polishing work by wet operation of the suspended ceiling, finishing the construction of the partition keel or the partition wall and checking and accepting to be qualified;

5. before the floor is installed, the base layer is cleaned, dried and dusted.

6. The construction environment temperature during gluing is not lower than 5 ℃;

preparing materials of the integrated floor heating system:

1. the floor heating module supporting plate: when the overhead height is more than or equal to 40mm, the fiber reinforced calcium silicate board subjected to anti-seepage treatment has the specification of 800 mm-1200 mm-10 mm, and can be processed and customized in factories according to design requirements.

2. Overhead decoration of the base layer plate: the fiber reinforced calcium silicate plate which meets the design load requirement and is subjected to anti-seepage treatment has the standard specification of 800 mm-1200 mm-20 mm and is cut according to the design requirement and processed in a factory. If the customized floor tile is used as the veneer layer, the decorative base layer plate can be eliminated, and the customized floor tile can be paved on the top end of the second support.

3. Special structural adhesive and silane modified nail-free adhesive.

4. And selecting the corresponding type of overhead supporter according to the overhead height.

5. The floor heating module according to the design requirement: the fire-retardant polyphenyl board keeps warm, the ground heating coil, the heat radiation membrane, water collection and distribution ware.

Preparing tools for construction of the integrated floor heating system: infrared level gauge, level bar, high-power dust collector, glue gun, rubber hammer, cutting saw, tapper, etc.

The construction standard of the integrated floor heating system construction process is as follows:

1. the construction process comprises the following steps: checking codes according to a picture, arranging in advance, cleaning the ground, snapping lines, installing a first support, leveling the first support, installing a module supporting plate, two layers of snapping lines, installing a second support, installing a heat insulation plate/pipe laying, leveling the second support, performing a pressing test, installing a decorative base plate or customizing floor tiles to pave, performing a secondary pressing test, installing a veneer layer and protecting finished products.

2. Construction steps and standards:

(1) and rechecking the specifications of the materials on site according to the design customized specifications, checking whether the materials are damaged or not, and performing pre-arrangement on site.

(2) Cleaning a room: A. before construction, a 2M guiding rule is used for checking the ground flatness, and the too sharp local bulge is leveled by combining chiseling and grinding; B. before construction, a high-power dust collector is used for cleaning dust and removing oil stains on the ground of a construction interface so as to avoid influencing the firmness of the mounting and bonding of the support.

(3) Line snapping: A. the accuracy of the 1.2m horizontal line in the room was reviewed. According to the requirement of the designed elevation, the elevation of the ground finish surface, the elevation of the second support and the elevation of the first support are measured out downwards in sequence by a horizontal line of 1.2m, the point positions are drawn on the wall, and the module is flicked to finish the surface line; B. according to design requirements, module specifications and the support spacing standard of less than or equal to 400, warps and wefts are popped on the ground, and the warps and the wefts need to return 200mm on the adjacent wall surface to be used as the second support position line snapping marks.

(4) The first support device is installed: A. firstly, cleaning up dust on the ground of a base layer at the position of a support, putting the support, placing a level ruler (bubble calibration) on the support, observing the flatness of the ground and determining whether a special gasket is needed to be used for adjustment, and if the adjustment is not needed, directly using silane modified nail-free glue for bonding. If necessary, the level is calibrated by using a special gasket according to the height difference displayed by the bubble of the level. Coating silane modified nail-free glue on the bottom surface of a support, pressing the support with a palm, slightly rotating to ensure that the nail-free glue overflows from a hole at the bottom of the support, and if an inclined gasket is arranged at the bottom, ensuring that the gasket does not rotate along with the support; B. after all the supporters are sequentially installed, a person is required to attend the site, and the person cannot enter the site within 24 hours of drying the silane modified nail-free glue.

(5) Leveling a first support: A. the silane modified nail-free glue is initially solidified, after certain strength is achieved, the supporters are rotated one by one to be adjusted to the required height according to the requirement of the ground overhead height, and if the supporters are provided with the lock catches, the lock catches are locked after the height of the supporters is adjusted. The adjusting ranges of the supporters of different models are different, whether the adjusting stroke exceeds the adjusting range of the model or not needs to be noticed in the adjusting process, and if the adjusting stroke exceeds the adjusting range of the model, the supporter of a higher model needs to be replaced; B. after the height of the support is adjusted, if floor heating or construction with other methods is available, floor heating or other constructors are arranged to enter the site for construction, and the support cannot be touched in the construction process.

(6) Installing a module supporting plate: A. before installation, carefully checking whether the plate is damaged, and if the plate is damaged, eliminating the plate or turning the plate into a cutting edge for use; B. before installation, whether the support is damaged and has errors due to height caused by other construction projects during solidification is checked again, and if the errors occur, timely supplement and adjustment are needed; C. the paving sequence is from inside to outside, when the plate is paved, silane modified nail-free glue is used for spreading glue on the plane of the support, the glue applying thickness is 3mm-5mm, the calcium silicate plate is placed on the support, and the calcium silicate plate is compacted after the distance between the calcium silicate plate and the partition walls on the four sides and the height of the calcium silicate plate are adjusted without errors before the nail-free glue is solidified. Before adjacent calcium silicate boards are laid, glue is applied to the center positions of the side faces of the four sides of each board for a circle by using special structural glue, the diameter of the glue is 5mm (the glue can be adjusted according to the width of a brick joint), the glue is applied to places where the glue is applied absolutely, each board is bonded one by one, a gap of 2 mm-3 mm is reserved between the boards, and fine adjustment is completed before the adhesive is solidified; D. after the bonded structural adhesive is condensed, inspectors wear soft-bottom shoes with strong foot feeling, walk along a room with the aid of the gravity of heels of single feet, ensure that each calcium silicate plate can step on, check whether loosening and warping phenomena exist, remove unqualified plates in time if the phenomena exist, and bond the support again after adjustment.

(7) Two layers of snapping lines: and when the module supporting plate is installed, after the adhesive is basically solidified, cleaning the structural adhesive extruded from the plate joint by using an art designer knife, and snapping lines at the position of the second support on the module supporting plate. And performing line snapping according to the return mark on the line snapping line at the position of the first support, so that the position of the second support is overlapped with the position of the first support.

(8) Installing a second support: and mounting the second support according to the support mounting position determined by the elastic line, wherein the mounting position is overlapped with the first support, and the mounting method is consistent.

(9) Installing a heat insulation board/pipe laying: A. and the second support is installed, and after the nail-free glue is basically solidified, the heat-insulation board is paved on the module supporting plate. When in pavement, the heat insulation board is used on the heat insulation board according to the position of the support

The hole digger is provided with a hole, and the back of the hole digger is sleeved with the support on the module supporting plate. After the heat preservation plates are paved, whether the space around the room meets the design requirements is checked; B. and laying ground heating pipes according to the trend of the design drawing, wherein the reserved quantity of the ground heating pipes connected to the water distributing and collecting device is sufficient. And marking the area and the water supply and return water of each path of ground heating pipe so as to be connected with a water collector. The pipe diameter of the floor heating pipe meets the design requirement, the floor heating pipe is laid by passing through the second support when the pipe distribution position is designed, and the allowable deviation of the distance is +/-10 mm; C. when the ground heating pipe is laid, the ground heating pipe is embedded into the groove of the heat insulation plate according to the principle of the sequence of gradually laying the ground heating pipe to the water collecting and distributing device from inside to outside. Each main pipe passes from under the overhead layer through other areas to the location of the water collector. The pipeline connected into the water collecting and distributing device is protected by penetrating a corrugated pipe, the type, specification and nominal pressure of the ground heating water collecting and distributing device meet the design requirements, and the distance between the center of the water collecting and distributing device and the ground is not less than 300 mm. And laying a thermal radiation film as required after the pipeline pavement is finished, wherein the thermal radiation film is sleeved on the heat insulation plate after being provided with a hole in accordance with the heat insulation plate when being laid at the position with the support, and the plane of the support is exposed.

(10) Leveling a second support: and leveling the support after the finished product of the floor heating is protected, wherein the method is consistent with the first support leveling construction method.

(11) And (3) pressing test: after the leveling of the support is completed, the floor heating equipment is subjected to a pressing test according to the standard, and the next procedure can be performed after the floor heating equipment is qualified.

(12) Installing a decorative base layer plate or a customized floor tile:

installing a decorative base layer plate: A. before installation, carefully checking whether the plate is damaged or not, and if the plate is damaged, eliminating the plate or turning the plate into a cutting edge for use; B. before installation, whether the support is damaged and has errors caused by height due to other construction projects during solidification is checked again, and if the support is required to be supplemented and adjusted in time; C. the paving sequence is from inside to outside, when the plate is paved, silane modified nail-free glue is used for spreading glue on the plane of the support, the glue applying thickness is 3mm-5mm, the calcium silicate plate is placed on the support, and the calcium silicate plate is compacted after the distance between the calcium silicate plate and the partition walls on the four sides and the height of the calcium silicate plate are adjusted without errors before the nail-free glue is solidified. Before adjacent calcium silicate boards are laid, glue is applied to the center positions of the side faces of the four sides of each board for a circle by using special structural glue, the diameter of the glue is 5mm (the glue can be adjusted according to the width of a brick joint), the glue is applied to places where broken application is strictly forbidden, each board is bonded one by one, a gap of 2 mm-3 mm is reserved between the boards, and fine adjustment is completed before the adhesive is solidified; D. after the bonded structure glue is condensed, an inspector wears soft-sole shoes with stronger foot feeling, walks along a room with the emphasis of the heel of a single foot, ensures that each calcium silicate plate can be stepped on, checks whether the phenomena of looseness and warping exist, and if the phenomena exist, removes unqualified plates in time and bonds the supporters again after adjusting.

Secondly, customizing floor tiles for installation: A. before paving the tiles, carefully checking whether the tiles are damaged or not, and if the tiles are damaged, eliminating the tiles or turning the tiles to cut the edges. B. Before paving bricks, whether the support is damaged and has errors caused by the height of the support due to other construction projects during solidification is checked again, and if the support is required to be supplemented and adjusted in time; C. paving tiles from the middle to two sides in sequence, when paving a first blocky tile, using silane modified nail-free glue to fully fill glue on the plane of a support, wherein the glue thickness is 3-5 mm, placing the tile on the support, adjusting the distance between the tile and a partition wall on the four sides and adjusting the height of the tile before the nail-free glue is solidified, and then compacting the tile. Before adjacent ceramic tiles are laid, glue is applied to the centers of the four side faces of the tiles for a circle by using special structural glue, the diameter of the glue is 5mm (the glue can be adjusted according to the width of a tile seam), and the glue is applied to places where the glue is strictly forbidden to be applied. And placing cross-shaped clamps with corresponding models between the cross-shaped clamps and adjacent bricks, bonding each ceramic tile one by one, and finishing fine adjustment before the adhesive is solidified. D. And after the complete ceramic tile in the middle part is paved, measuring whether the residual sizes of the four sides of the partition wall are consistent with the size of the processed ceramic tile or not, and if not, re-processing and cutting the ceramic tile on site or in a factory. The cutting is accurate, a gap of 2 mm-3 mm is reserved between the ceramic tile and the partition wall, and the ceramic tile and the partition wall are bonded by structural adhesive like other brick gaps. E. After the structural adhesive of the bonded ceramic tiles is condensed, an inspector wears soft-bottom shoes with strong foot feeling, uses the heels of single feet to exert strength, walks along a room, ensures that each tile can be stepped on, checks whether the phenomena of looseness and warping exist, removes unqualified ceramic tiles in time if the phenomena exist, and bonds the support again after adjusting. F. And (5) after the ceramic tiles are bonded and inspected to be qualified, filling the seams of the ceramic tiles with a seam beautifying agent.

(13) And (3) secondary pressing test: after the decoration base plate or the customized floor tiles are installed, the floor heating equipment is subjected to a pressing test again, and damage to the floor heating equipment in the construction process is found in time.

(14) Installing a decorative layer: and paving the veneer layer according to design requirements after the secondary pressing test is finished, wherein the construction method meets the requirements of the veneer process. The facing material should meet the requirements of the heating form material.

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of this invention without departing from the spirit thereof.

In the present invention, the terms "upper", "lower", "left", "right", "middle", and the like are used for clarity of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof without substantial changes in the technical content are also regarded as the scope of the present invention.

Claims (10)

1. An overhead dry-method floor heating module is characterized by comprising a structural layer (1), a first support (3), a water pipe (2), a floor heating module supporting plate (4), a floor heating pipe (5), a second support (10) and a finish coat (7); the upper surface of the structural layer (1) is provided with a plurality of first supporters (3), the top ends of the first supporters (3) are provided with the floor heating module supporting plate (4), the upper surface of the floor heating module supporting plate (4) is provided with a plurality of second supporters (10), and the top ends of the second supporters (10) are provided with the finish coat (7); the water pipe (2) is arranged around the first support (3), and the ground heating pipe (5) is arranged around the second support (10).

2. An overhead dry floor heating module as claimed in claim 1, further comprising a decorative base sheet (6), the decorative base sheet (6) being disposed between the top end of the second support (10) and the finishing layer (7).

3. An overhead dry floor heating module as claimed in claim 2, wherein the finishing layer (7) is any one of a floor, a tile and a carpet.

4. An overhead dry floor heating module as claimed in claim 3, further comprising a conduit (8), wherein the conduit (8) is arranged around the first supporter (3).

5. An overhead dry floor heating module according to claim 4, further comprising a heat insulation board (11), wherein the heat insulation board (11) is arranged between the floor heating module supporting board (4) and the decorative base board (6), and the floor heating pipe (5) is installed in a groove formed in the upper surface of the heat insulation board (11).

6. An overhead dry floor heating module as claimed in claim 5, further comprising a heat radiating film (9), the heat radiating film (9) being laid on the upper surface of the heat insulating board (11).

7. An overhead dry floor heating module as claimed in claim 6, further comprising a water separator, with which the plurality of floor heating pipes (5) are connected.

8. An overhead dry floor heating module according to claim 7, wherein the floor heating module supporting plate (4) is an integral structure formed by cutting a fiber-reinforced calcium silicate plate subjected to anti-permeation treatment, and the decoration base plate (6) is an integral structure formed by cutting a fiber-reinforced calcium silicate plate subjected to anti-permeation treatment.

9. An overhead dry floor heating module according to claim 8, characterized in that the floor heating module pallet (4) has a gauge of 800mm x 1200mm x 10mm and the decorative base sheet (6) has a gauge of 800mm x 1200mm x 20 mm.

10. An overhead dry floor heating module according to claim 9, wherein when the finishing layer (7) is a floor tile, the floor tile is custom-made with a custom thickness of 20mm or more, and the floor tile specification is any one of 300mm, 600mm, 600mm 1200mm, 450mm 900mm, 800mm, 900mm, and 900mm 1800 mm.

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