CN215907282U - Assembled multifunctional dry floor heating system - Google Patents

Abstract

The utility model relates to a multi-functional dry-type underfloor heating system of assembled, it warms up the module field with relating to, and it includes heat transfer layer and a plurality of pipe of inlaying, be equipped with the tube seat that is used for holding a plurality of pipes that inlay on the heat transfer layer, inlay the pipe and inlay and establish in the tube seat, still include fossil fragments, be equipped with on fossil fragments and be used for holding inlaying of heat transfer layer and establish the groove, the heat transfer layer inlays to be established and establishes in the groove, be equipped with the subassembly of making level that is used for making level to fossil fragments on the fossil fragments. This application has heat preservation, dampproofing, fire prevention, shock attenuation and syllable-dividing multi-functional effect to ground.

Description

Assembled multifunctional dry floor heating system

Technical Field

The application relates to the field of floor heating, in particular to an assembled multifunctional dry floor heating system.

Background

The dry floor heating is a thin floor heating which is laid by adopting a prefabricated groove heat-insulating module in a dry method and does not need cement backfilling. The dry floor heating uses the metal uniform heating layer as a ground radiator, so that the low-temperature heating medium uniformly heats the ground, and heat is supplied to the indoor space in a radiation and convection mode, thereby achieving the purpose of rapid and comfortable heating.

Chinese patent with publication number CN201407728Y discloses a far infrared dry-type floor heating module, which comprises a heat preservation layer and a heat transfer layer, wherein the heat transfer layer is positioned above the heat preservation layer, a pipe groove is arranged on the heat transfer layer, a far infrared heating layer is arranged on the surface of the heat transfer layer or between the heat transfer layer and the heat preservation layer, and the pipe groove is an inward concave U-shaped groove.

In the related art, before a dry floor heating module is installed, the installation ground is firstly leveled, and the installation ground is leveled by adopting a wet cement leveling mode generally at present.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: and the wet cement leveling is utilized, so that the construction personnel is required to pour concrete again on the installation ground, and the time and the labor are wasted.

SUMMERY OF THE UTILITY MODEL

In order to improve the problem that it is hard consuming time to pour concrete again to the ground, this application provides a multi-functional dry-type underfloor heating system of assembled.

The application provides a multi-functional dry-type underfloor heating system of assembled adopts following technical scheme:

the utility model provides a multi-functional dry-type underfloor heating system of assembled, includes heat transfer layer and a plurality of pipe that inlays, be equipped with the tube seat that is used for holding a plurality of pipes that inlay on the heat transfer layer, inlay the pipe and inlay and establish at the tube seat, still include fossil fragments, be equipped with on the fossil fragments and be used for holding the inlaying of heat transfer layer and establish the groove, the heat transfer layer inlays to be established and establishes in inlaying and establishing the inslot, be equipped with the subassembly of making level that is used for making level to fossil fragments on the fossil fragments.

By adopting the technical scheme, the heat transfer layer is embedded in the embedding groove, and the embedded pipe is embedded in the pipe groove, so that the embedded pipe is installed; the keel is leveled by the leveling assembly, so that the construction efficiency of the floor heating by personnel is improved, and time and labor are saved.

Optionally, the leveling assembly includes a spiral ring and a leveling bolt, the keel is provided with a plurality of threaded holes, an outer annular wall of the spiral ring is provided with an external thread, an inner annular wall of the spiral ring is provided with an internal thread, the internal thread of the spiral ring and the external thread of the spiral ring have opposite rotation directions, the spiral ring is in threaded connection with the threaded holes, the leveling bolt is in threaded connection with the inner annular wall of the spiral ring, a screw head of the leveling bolt extends out of a side wall of the keel, which faces the ground, and abuts against the ground, and a groove used for being matched with the screwdriver is formed in a side wall of the leveling bolt, which is far away from the screw head.

By adopting the technical scheme, when the keel is leveled, the screwdriver is inserted into the groove, the leveling bolt is screwed by the screwdriver, the leveling bolt is rotated, the leveling bolt is in threaded connection with the spiral ring, the spiral ring is in threaded connection with the threaded hole, the internal thread of the spiral ring is opposite to the external thread of the spiral ring in rotation direction, and further, when the leveling bolt is rotated, the spiral ring is rotated, and meanwhile, the leveling bolt is lifted in the spiral ring, so that the adjustment of the distance between the screw head of the leveling bolt and the ground is realized, the leveling of the keel is realized, the construction efficiency is high, and the time and the labor are saved; and the keel is separated from the ground by matching the spiral ring and the leveling bolt, so that moisture on the ground is blocked, the floor is prevented from being damped and mildewed as much as possible, and the service life of the floor is prolonged.

Optionally, the subassembly of making level includes adjusting bolt and pressure-bearing bolt, be equipped with a plurality of regulation holes on the fossil fragments, evenly be equipped with a plurality of countersunk grooves on the lateral wall that fossil fragments kept away from ground, countersunk groove and regulation hole are linked together, adjusting bolt rotates to be connected in the regulation hole, adjusting bolt's spiral shell head sets up at the countersunk groove, adjusting bolt has seted up the mounting groove on keeping away from the lateral wall of spiral shell head, be equipped with the screw thread on the cell wall of mounting groove, pressure-bearing bolt keeps away from the one end of pressure-bearing bolt spiral shell head and the cell wall threaded connection of mounting groove, pressure-bearing bolt's spiral shell head stretch out fossil fragments towards the lateral wall on ground and with ground butt, pressure-bearing bolt is last and be equipped with the spout along self axis direction, be equipped with the slider that is used for sliding in the spout on the pore wall of regulation hole.

By adopting the technical scheme, when the keel is leveled, the adjusting bolt is in threaded connection with the pressure-bearing bolt, the adjusting bolt is screwed, so that the adjusting bolt and the pressure-bearing bolt rotate relatively, the pressure-bearing bolt slides along the direction of the chute, the distance from the side wall of the screw head of the pressure-bearing bolt facing the ground to the side wall of the keel facing the ground is adjusted, the keel is leveled, the construction efficiency is high, and time and labor are saved; the adjusting bolts and the bearing bolts are matched to separate the keel from the ground, so that moisture on the ground can be blocked, the floor is prevented from being damped and mildewed as much as possible, and the service life of the floor is prolonged.

Optionally, a convex plate is fixedly connected to the side wall of the adjusting bolt, and a concave groove for rotating the convex plate is formed in the adjusting hole.

Through adopting above-mentioned technical scheme, utilize flange and sunken groove to cooperate and realized the rotation between adjusting bolt and the regulation hole and be connected.

Optionally, a heat conducting assembly is arranged between the heat transfer layer and the embedded pipe.

Through adopting above-mentioned technical scheme, utilize heat conduction assembly to conduct the heat of inlaying the pipe, increased heat conductivity and heat conduction area, improved heat conduction efficiency.

Optionally, the heat conduction assembly comprises a first aluminum plate, the first aluminum plate is arranged on the heat transfer layer, a first clamping groove used for being matched with the embedded pipe is formed in the first aluminum plate, and the embedded pipe is embedded in the first clamping groove.

Through adopting above-mentioned technical scheme, utilize first aluminum plate increase heat conductivity, reduce the thermal loss of embedded pipe, be favorable to the thermal high-efficient utilization of embedded pipe, save the heating expense.

Optionally, the heat conduction assembly comprises a second aluminum plate and infrared emission cloth, the second aluminum plate is arranged on the heat transfer layer, the infrared emission cloth is arranged on the side wall, away from the heat transfer layer, of the second aluminum plate, a second clamping groove used for being matched with the embedded pipe is formed in the second aluminum plate, and a placing groove used for being matched with the second clamping groove is formed in the infrared emission cloth.

By adopting the technical scheme, the heat conductivity is increased by utilizing the second aluminum plate, the heat loss of the embedded pipe is reduced, the efficient utilization of the heat of the embedded pipe is facilitated, and the heating cost is saved; by utilizing the infrared emission cloth, the radiation area is increased, the ground is favorably heated uniformly, and the comfort level of a user is improved.

Optionally, a soaking protection plate for covering the plurality of embedded pipes is fixedly arranged on the keel, the soaking protection plate is abutted to the side wall of the keel far away from the ground, and the soaking protection plate is a glass magnesium plate.

By adopting the technical scheme, the soaking protection plate is used for absorbing and releasing the heat of the embedded pipe, so that the heat is released more uniformly, the glass magnesium plate has good fireproof and heat-insulating properties, can absorb a large amount of heat energy in the process of burning in fire, delays the rise of the ambient temperature, has low density, lightens the building load, and is beneficial to structural earthquake resistance; the magnesium oxide board also has good sound insulation performance, and is beneficial to keeping the environment quiet.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the leveling assembly is utilized to separate the keel from the ground by a certain distance, so that the moisture on the ground can be blocked, the floor is prevented from being damped and mildewed as much as possible, and the service life of the floor is prolonged;

2. utilize heat conduction assembly to carry out the conduction to the heat of inlaying the pipe, the increase heat conductivity, increase heat conduction area is favorable to ground to be heated evenly, has improved the comfort level.

Drawings

Fig. 1 is a schematic view of the overall structure of the assembled multifunctional dry floor heating system in embodiment 1 of the present application.

Fig. 2 is a schematic sectional view taken along the plane a-a in fig. 1.

Fig. 3 is an enlarged view taken along a in fig. 2.

Fig. 4 is a schematic view of the overall structure of the assembled multifunctional dry floor heating system in embodiment 2 of the present application.

Fig. 5 is a schematic sectional view taken along the plane B-B in fig. 4.

Fig. 6 is an enlarged view taken along B in fig. 5.

Fig. 7 is a schematic view of the overall structure of the assembled multifunctional dry floor heating system in embodiment 3 of the present application.

Fig. 8 is a schematic sectional view taken along the plane C-C in fig. 7.

Fig. 9 is an enlarged view taken along line C in fig. 8.

Fig. 10 is a schematic view of the overall structure of the assembled multifunctional dry floor heating system in embodiment 4 of the present application.

Description of reference numerals: 1. a heat transfer layer; 2. embedding a pipe; 3. a pipe groove; 4. a keel; 5. a leveling assembly; 51. a spiro ring; 52. leveling the bolt; 53. adjusting the bolt; 54. a pressure-bearing bolt; 6. a threaded hole; 7. a groove; 8. an adjustment hole; 9. a countersunk groove; 10. mounting grooves; 11. a chute; 12. a slider; 13. a convex plate; 14. a recessed groove; 15. a heat conducting component; 151. a first aluminum plate; 152. a second aluminum plate; 153. infrared emission cloth; 16. a first card slot; 17. a second card slot; 18. a placing groove; 19. and (5) soaking the protection plate.

Detailed Description

The present application is described in further detail below with reference to figures 1-10.

The embodiment of the application discloses multi-functional dry-type underfloor heating system of assembled.

Example 1

Referring to fig. 1 and 2, the assembled multifunctional dry floor heating system comprises a heat transfer layer 1, a plurality of embedded pipes 2 and keels 4; the heat transfer layer 1 is provided with a plurality of pipe grooves 3, the embedded pipes 2 are embedded in the pipe grooves 3, and the pipe walls of the embedded pipes 2 are attached to the pipe walls of the pipe grooves 3, so that the embedded pipes 2 are installed; the keel 4 is provided with an embedding groove which is a through groove, and the heat transfer layer 1 is embedded in the embedding groove, so that the installation of the keel 4 and the heat transfer layer 1 is realized; be equipped with on fossil fragments 4 and be used for the subassembly 5 of making level to fossil fragments 4, utilize the subassembly 5 of making level to make level to fossil fragments 4, improved the efficiency of construction that personnel ground warms up, labour saving and time saving.

Referring to fig. 3, the leveling assembly 5 includes a spiral ring 51 and a leveling bolt 52, a plurality of threaded holes 6 are uniformly formed in the keel 4, external threads are formed on the outer annular wall of the spiral ring 51, external threads on the outer annular wall of the spiral ring 51 are in threaded connection with the threaded holes 6, internal threads are formed on the inner annular wall of the spiral ring 51, one end of the leveling bolt 52, away from the screw head, is in threaded connection with the internal threads of the spiral ring 51, the external threads of the spiral ring 51 are opposite to the internal threads of the spiral ring 51 in the rotating direction, the screw head of the leveling bolt 52 extends out of the side wall, facing the ground, of the keel 4 and abuts against the ground, one end of the leveling bolt 52, away from the screw head, does not extend out of the side wall, away from the keel 4, away from the side wall of the leveling bolt 52, and is provided with a groove 7 matched with a screwdriver, and in this embodiment, the groove 7 is a hexagonal groove.

When the keel 4 is leveled, the end of the screwdriver is inserted into the groove 7, the screwdriver is screwed, the leveling bolt 52 is driven by the screwdriver to rotate, the external thread of the spiral ring 51 is in threaded connection with the threaded hole 6, the leveling bolt 52 is in threaded connection with the internal thread of the spiral ring 51, the screwing directions of the internal thread of the spiral ring 51 and the external thread of the spiral ring 51 are opposite, further, when the leveling bolt 52 rotates, the spiral ring 51 and the leveling bolt 52 synchronously rotate, at the moment, the leveling bolt 52 and the spiral ring 51 relatively rotate, so that the distance from the side wall of the screw head of the leveling bolt 52 facing the ground to the side wall of the keel 4 facing the ground is adjusted, and the leveling of the keel 4 is realized; by adopting the leveling mode, the construction efficiency is high, time and labor are saved, and the construction cost is low; and the screw ring 51 is matched with the leveling bolt 52 so as to isolate the keel 4 from the ground, thereby preventing the moisture on the ground from corroding the floor, leading the floor to be moistened and mildewed and being beneficial to prolonging the service life of the floor.

Referring to fig. 3, a heat conducting assembly 15 is arranged between the heat transfer layer 1 and the embedded pipe 2, the heat conducting assembly 15 comprises a first aluminum plate 151, a first clamping groove 16 with a U-shaped longitudinal section is arranged on the first aluminum plate 151, the first clamping groove 16 is used for being matched with the embedded pipe 2, the embedded pipe 2 is arranged in the first clamping groove 16, and the pipe wall of the embedded pipe 2 is attached to the groove wall of the first clamping groove 16; first aluminum plate 151 is laminated with the lateral wall that heat transfer layer 1 kept away from ground towards the lateral wall on ground mutually, the lateral wall that ground and the perisporium looks butt of pipe 2 are kept away from to first aluminum plate 151, utilize first aluminum plate 151 to conduct the heat of pipe 2, first aluminum plate 151 has good heat conductivity, utilize first aluminum plate 151 to conduct the heat of pipe 2 to the heat transfer layer 1 fast, the heat conduction efficiency to heat transfer layer 1 has been improved, through setting up first aluminum plate 151, be favorable to the thermal high-efficient utilization of pipe 2, reduce the thermal loss of pipe 2.

Referring to fig. 3, a soaking protection plate 19 is arranged on the keel 4, the soaking protection plate 19 is used for completely covering the keel 4 and the embedded pipes 2, the side wall of the soaking protection plate 19 close to the ground is abutted to the side wall of the keel 4 far away from the ground, the soaking protection plate 19 is fixedly connected with the keel 4 through bolts, and the soaking protection plate 19 is a glass magnesium plate.

The soaking protection plate 19 is used for absorbing the heat of the embedded pipe 2 and driving the whole soaking protection plate 19 to heat, so that the heat is more uniformly released, and the heating efficiency and the heating effect of the floor heating are improved; the glass magnesium board has certain elasticity and comfortable foot feel, has good fireproof and heat-insulating properties, and can absorb a large amount of heat energy in the process of burning in case of fire, so that the temperature of the surrounding environment is delayed to rise; the glass magnesium board has low density, thereby reducing the building load and being beneficial to the structural earthquake resistance; the magnesium oxide board also has good sound insulation performance, and is beneficial to keeping the environment quiet.

The implementation principle of the embodiment 1 is as follows: when the dry floor heating is installed, firstly, the keel 4 is erected on the ground needing to be paved on the dry floor heating, the leveling bolt 52 is screwed, the leveling bolt 52 and the spiral ring 51 rotate relatively, and the distance from the side wall of the spiral head of the leveling bolt 52 facing the ground to the side wall of the keel 4 facing the ground is changed due to the fact that the external thread of the spiral ring 51 and the internal thread of the spiral ring 51 rotate in opposite directions, so that the leveling of the keel 4 is achieved, the construction efficiency is high, and time and labor are saved.

Then inlay heat transfer layer 1 and establish the inslot in inlaying, place first aluminum plate 151 on the lateral wall that heat transfer layer 1 kept away from ground again, when first draw-in groove 16 on first aluminum plate 151 and pipe groove 3 on the heat transfer layer 1 cooperate, inlay pipe 2 and establish in first draw-in groove 16 of first aluminum plate 151, place soaking protection board 19 on the lateral wall that fossil fragments 4 kept away from ground at last, it is fixed with fossil fragments 4 to utilize the bolt with soaking protection board 19, it is fixed to utilize soaking protection board 19 and heat transfer layer 1 to realize the centre gripping of inlaying pipe 2, lay ceramic tile or timber apron on the lateral wall that soaking protection board 19 kept away from ground at last, the mating formation to dry-type ground heating has been realized.

Example 2

The present embodiment is different from embodiment 1 in that the structure of the heat conductive member 15 is different.

Referring to fig. 4, 5 and 6, the heat conducting assembly 15 includes a second aluminum plate 152 and an infrared emitting cloth 153, the second aluminum plate 152 is provided with a plurality of second clamping grooves 17, the second clamping grooves 17 are used for being matched with the embedded pipe 2, and the infrared emitting cloth 153 is provided with a placing groove 18 for being matched with the embedded pipe 2; when the heat transfer pipe is installed, the second aluminum plate 152 is firstly placed on the heat transfer layer 1, so that the second clamping groove 17 is matched with the pipe groove 3, the infrared emitting cloth 153 is then placed on the heat transfer layer 1, so that the placing groove 18 is matched with the second clamping groove 17, and finally the embedded pipe 2 is placed in the second clamping groove 17.

The implementation principle of the embodiment 2 is as follows: second aluminum plate 152 has good heat conductivity, utilizes second aluminum plate 152 to increase heat transfer layer 1's heat conductivity, utilizes infrared emission cloth 153, has further increased heat transfer layer 1's heat radiating area for ground is heated evenly, reduces the thermal loss of embedded pipe 2, is favorable to the high-efficient utilization to the heat of embedded pipe 2, makes the speed of accelerating the intensification and saved the expense of heating.

Example 3

This embodiment differs from embodiment 1 in the construction of the leveling assembly 5.

Referring to fig. 7, 8 and 9, the leveling assembly 5 includes an adjusting bolt 53 and a pressure-bearing bolt 54, the keel 4 is uniformly provided with a plurality of adjusting holes 8, the side wall of the keel 4 far from the ground is provided with a plurality of countersunk grooves 9, the countersunk grooves 9 are communicated with the adjusting holes 8, one end of the adjusting bolt 53 far from the screw head of the adjusting bolt 53 is fixedly connected with an annular convex plate 13, the adjusting hole 8 is provided with a concave groove 14 for accommodating the convex plate 13, the adjusting bolt 53 is rotatably connected in the adjusting hole 8 by matching the convex plate 13 with the concave groove 14, the screw head of the adjusting bolt 53 is arranged in the countersunk groove 9, the side wall of the adjusting bolt 53 far from the screw head of the adjusting bolt 53 is provided with an installation groove 10, the groove wall of the installation groove 10 is provided with threads, one end of the pressure-bearing bolt 54 far from the screw head of the pressure-bearing bolt 54 is in threaded connection with the installation groove 10, the screw head of the pressure-bearing bolt 54 extends out of the side wall of the keel 4 facing the ground and is abutted to the ground, the peripheral wall of the pressure-bearing bolt 54 is provided with a sliding groove 11 along the axial direction, and the wall of the adjusting hole 8 close to the ground is provided with a sliding block 12 matched with the sliding groove 11.

The implementation principle of the embodiment 3 is as follows: when the keel 4 is leveled, the adjusting bolt 53 is screwed, the adjusting bolt 53 is in threaded connection with the pressure-bearing bolt 54, the adjusting bolt 53 and the pressure-bearing bolt 54 rotate relatively, the adjusting bolt 53 is in threaded connection with the pressure-bearing bolt 54, the pressure-bearing bolt 54 moves upwards or downwards along the axis direction of the pressure-bearing bolt 54 under the matching of the sliding chute 11 and the sliding block 12, at the moment, the screw head of the pressure-bearing bolt 54 drives the keel 4 to change the distance between the keel 4 and the ground, so that the keel 4 is leveled, the floor heating is leveled, the construction efficiency is high, and time and labor are saved; the bearing bolt 54 supports the keel 4 to be separated from the ground, so that the moisture on the ground can be blocked, the floor can be prevented from mildewing due to moisture as much as possible, and the service life of the floor is prolonged.

Example 4

The difference between the embodiment and the embodiment 1 is that in the embodiment 1, the keels 4 and the heat transfer layer 1 are distributed left and right to form left and right overhead floor heating; in this embodiment, the keels 4 and the heat transfer layer 1 are vertically distributed to be vertically overhead ground heating.

Referring to fig. 10, soaking protection board 19 sets up on fossil fragments 4 keep away from the lateral wall on ground, heat transfer layer 1 sets up on soaking protection board 19 keeps away from the lateral wall of fossil fragments 4, soaking protection board 19 is the glass magnesium board, be equipped with a plurality of tube slots 3 on heat transfer layer 1, inlay pipe 2 and inlay and establish in tube slot 3, the pipe wall of inlaying pipe 2 and the inboard wall laminating of tube slot 3, the installation to inlaying pipe 2 has been realized, be equipped with first aluminum plate 151 between inlaying pipe 2 and the heat transfer layer 1, be equipped with the first draw-in groove 16 that the longitudinal section is "U" type on the first aluminum plate 151, first draw-in groove 16 is used for cooperateing with inlaying pipe 2, the lateral wall that first aluminum plate 151 faced ground and heat transfer layer 1 keep away from ground is laminated mutually, the lateral wall looks butt of first aluminum plate 151 keeping away from ground and the perisporium looks butt of inlaying pipe 2, the ceramic tile or directly lay on the lateral wall that heat transfer layer 1 kept away from ground, the pavement to upper and lower empty type dry-type floor heating has been realized.

The implementation principle of the embodiment 4 is as follows: when installing dry-type ground heating, erect fossil fragments 4 subaerial that dry-type ground heating need mat formation at first, utilize the subassembly 5 of making level to make level fossil fragments 4, then directly lay heat transfer layer 1 on the lateral wall that fossil fragments 4 kept away from ground, utilize the bolt with heat transfer layer 1 and fossil fragments 4 fixed connection, place first aluminum plate 151 on the lateral wall that heat transfer layer 1 kept away from ground again, when first draw-in groove 16 on first aluminum plate 151 and the pipe socket 3 on the heat transfer layer 1 cooperate, inlay pipe 2 in first draw-in groove 16, at last, directly lay floor or ceramic tile on the lateral wall that ground was kept away from on heat transfer layer 1, realized mat formation to overhead type dry-type ground heating from top to bottom.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a multi-functional dry-type underfloor heating system of assembled, includes heat transfer layer (1) and a plurality of pipe (2) of inlaying, be equipped with pipe box (3) that are used for holding a plurality of pipe (2) of inlaying on heat transfer layer (1), inlay pipe (2) and inlay and establish in pipe box (3), its characterized in that: still include fossil fragments (4), be equipped with on fossil fragments (4) and be used for holding the groove of establishing of inlaying of heat transfer layer (1), heat transfer layer (1) inlays to be established and inlays to establish in the groove, be equipped with on fossil fragments (4) and be used for leveling subassembly (5) of making level to fossil fragments (4).

2. The assembled multifunctional dry floor heating system of claim 1, wherein: the leveling assembly (5) comprises a spiral ring (51) and a leveling bolt (52), a plurality of threaded holes (6) are formed in the keel (4), external threads are formed in the outer annular wall of the spiral ring (51), internal threads are formed in the inner annular wall of the spiral ring (51), the internal threads of the spiral ring (51) and the external threads of the spiral ring (51) are opposite in rotating direction, the spiral ring (51) is in threaded connection in the threaded holes (6), the leveling bolt (52) is in threaded connection with the inner annular wall of the spiral ring (51), the screw head of the leveling bolt (52) extends out of the side wall, facing the ground, of the keel (4) and abuts against the ground, and a groove (7) matched with a screwdriver is formed in the side wall, away from the screw head, of the leveling bolt (52).

3. The assembled multifunctional dry floor heating system of claim 1, wherein: the leveling assembly (5) comprises an adjusting bolt (53) and a pressure-bearing bolt (54), a plurality of adjusting holes (8) are formed in the keel (4), a plurality of countersunk grooves (9) are uniformly formed in the side wall, away from the ground, of the keel (4), the countersunk grooves (9) are communicated with the adjusting holes (8), the adjusting bolt (53) is rotatably connected into the adjusting holes (8), the screw head of the adjusting bolt (53) is arranged in the countersunk groove (9), a mounting groove (10) is formed in the side wall, away from the screw head, of the adjusting bolt (53), threads are arranged on the groove wall of the mounting groove (10), one end, away from the screw head of the pressure-bearing bolt (54), of the pressure-bearing bolt (54) is in threaded connection with the groove wall of the mounting groove (10), the screw head of the pressure-bearing bolt (54) extends out of the side wall, towards the ground, of the keel (4) and abuts against the ground, a sliding groove (11) is formed in the pressure-bearing bolt (54) and along the axis direction of the pressure-bearing bolt, the hole wall of the adjusting hole (8) is provided with a sliding block (12) which is used for sliding in the sliding groove (11).

4. The assembled multifunctional dry floor heating system of claim 3, wherein: the side wall of the adjusting bolt (53) is fixedly connected with a convex plate (13), and a concave groove (14) for rotating the convex plate (13) is formed in the adjusting hole (8).

5. The assembled multifunctional dry floor heating system of claim 1, wherein: and a heat conduction assembly (15) is arranged between the heat transfer layer (1) and the embedded pipe (2).

6. The assembled multifunctional dry floor heating system of claim 5, wherein: heat-conducting component (15) include first aluminum plate (151), first aluminum plate (151) set up on heat transfer layer (1), be equipped with on first aluminum plate (151) be used for with inlay pipe (2) matched with first draw-in groove (16), it inlays and establishes in first draw-in groove (16) to inlay pipe (2).

7. The assembled multifunctional dry floor heating system of claim 5, wherein: heat-conducting component (15) include second aluminum plate (152) and infrared emission cloth (153), second aluminum plate (152) set up on heat transfer layer (1), infrared emission cloth (153) set up on second aluminum plate (152) keep away from the lateral wall on heat transfer layer (1), be equipped with on second aluminum plate (152) and be used for and inlay pipe (2) matched with second draw-in groove (17), be equipped with on infrared emission cloth (153) and be used for with second draw-in groove (17) matched with arrangement groove (18).

8. The assembled multifunctional dry floor heating system of claim 1, wherein: the heat-soaking device is characterized in that a heat-soaking protection plate (19) used for covering the embedded pipes (2) is fixedly arranged on the keel (4), the heat-soaking protection plate (19) is abutted to the side wall, away from the ground, of the keel (4), and the heat-soaking protection plate (19) is a glass magnesium plate.

Images