CN217537710U - Overhead wood floor heat preservation system - Google Patents
Overhead wood floor heat preservation system Download PDFInfo
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- CN217537710U CN217537710U CN202220885901.3U CN202220885901U CN217537710U CN 217537710 U CN217537710 U CN 217537710U CN 202220885901 U CN202220885901 U CN 202220885901U CN 217537710 U CN217537710 U CN 217537710U
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- wood floor
- magnesium board
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Abstract
The utility model belongs to the technical field of floor building technique and specifically relates to a built on stilts formula timber apron heat preservation system is related to, including the timber apron, laid heated board and the overhead bottom plate that has the heat preservation effect between timber apron and the floor, the overhead bottom plate is laid at the floor top, and the heated board is laid at the overhead bottom plate top, and the timber apron is laid at the heated board top. This application has the effect of accelerating the construction progress, still has the effect that improves indoor heat preservation, can also reduce staff's labour and material cost simultaneously.
Description
Technical Field
The application relates to the technical field of floor construction, in particular to an overhead wood floor heat preservation system.
Background
As a common floor, the wood floor is widely applied to house decoration, has high wear resistance and high strength, and can meet the support requirements of people walking on the ground of a house.
The traditional building floor surface heat preservation construction mostly adopts wet process operation, lays the heated board on the floor surface, then cast-in-place reinforcing bar pea gravel concrete on the heated board, at last lays the timber apron, and the work progress is loaded down with trivial details, and the period is long, and engineering quality is difficult to guarantee, and labour and material cost are higher.
SUMMERY OF THE UTILITY MODEL
In order to accelerate the construction progress, reduce construction cost, improve the heat preservation effect on building ground, this application provides an overhead timber apron heat preservation system.
The application provides a pair of overhead timber apron heat preservation system adopts following technical scheme:
the utility model provides an overhead formula timber apron heat preservation system, includes the timber apron, heated board and the overhead bottom plate that has the heat preservation effect have been laid between timber apron and the floor, the overhead bottom plate is laid in the floor top, the heated board is laid in the overhead bottom plate top, the timber apron is laid in the heated board top.
Through adopting above-mentioned technical scheme, when carrying out the construction, the staff lays overhead bottom plate and heated board on the floor in proper order, and overhead bottom plate and heated board all have the heat preservation effect, lay the top of heated board with the timber apron again at last, and the staff need not cast-in-place reinforcing bar pea gravel concrete in the work progress, and produced intensity of labour is lower, can accelerate the construction progress.
Preferably, the overhead bottom plate is a glass magnesium plate, and the insulation plate is an XPS extruded sheet.
By adopting the technical scheme, the heat conductivity coefficient of the magnesium oxide board and the XPS extruded sheet is lower, and the extruded sheet has better heat insulation property, so that indoor heat is not easy to dissipate, and the indoor heat insulation effect is improved.
Preferably, the thickness ratio of the glass magnesium board to the XPS extruded sheet is 1: (0.5-0.8).
Through adopting above-mentioned technical scheme, glass magnesium board and XPS extruded sheet thickness ratio have better heat preservation effect and dampproofing effect when this within range.
Preferably, the thickness ratio of the glass magnesium board to the wood floor is 1: (0.8-1.2).
By adopting the technical scheme, when the thickness ratio of the glass magnesium board to the wood floor is in the range, the glass magnesium board can bear the pressure of the wood floor, and meanwhile, the glass magnesium board has better heat insulation performance.
Preferably, the floor slab is provided with a supporting component for supporting the glass magnesium board, and a heat-insulating cavity for paving the electromechanical pipeline is formed between the glass magnesium board and the floor slab.
By adopting the technical scheme, the heat-preservation cavity forms a space for installing the electromechanical pipeline so as to realize pipeline separation, and the heat-preservation cavity forms an air heat-insulation space, so that the heat-preservation effect of the whole indoor space is improved.
Preferably, the supporting component comprises a supporting base, a supporting screw rod, an adjusting nut and a supporting plate, the supporting base is abutted to the top surface of the floor slab, the supporting screw rod is detachably mounted on the top of the supporting base, the adjusting nut is in threaded connection with the supporting screw rod, the supporting plate is fixed on the adjusting nut, and the glass magnesium board is abutted to the top surface of the supporting plate.
Through adopting above-mentioned technical scheme, when the glass magnesium board received the load, the backup pad made the difficult production of glass magnesium board cracked, and the staff can adjust the relative position of adjusting nut and supporting screw according to electromechanical pipeline's difference when carrying out the construction, is convenient for adjust the space size of heat preservation cavity, and the operation flexibility is high.
Preferably, a tapping screw penetrates through the top surface of the glass magnesium board, and the tapping screw is in threaded connection with the support plate.
Through adopting above-mentioned technical scheme, self-tapping screw wears to locate glass magnesium board and backup pad simultaneously for glass magnesium board is difficult to take place relative activity with the backup pad, has improved the stability of glass magnesium board.
Preferably, a connecting nut is fixed on the supporting base, and the supporting screw is in threaded connection with the connecting nut.
Through adopting above-mentioned technical scheme, coupling nut makes support screw rod and support base realize demountable installation, when coupling nut or when taking place to damage when supporting the base, is convenient for change, has reduced the maintenance cost.
Preferably, the support plate is welded to the adjustment nut.
Through adopting above-mentioned technical scheme, improved backup pad and adjusting nut's joint strength, improved the backup pad to the supporting effect of glass magnesium board.
In summary, the present application includes at least one of the following beneficial technical effects:
1. during construction, workers sequentially lay an overhead bottom plate and an insulation board on a floor slab, the overhead bottom plate and the insulation board both have insulation effects, and finally lay a wood floor on the top of the insulation board, and the whole process adopts dry-method assembly type construction, so that the cast-in-place of reinforced fine stone concrete is not needed in the construction process, the labor intensity is low, the construction progress can be accelerated, and the construction period can be shortened; meanwhile, the assembly rate of the building can be improved by adopting dry assembly type construction;
2. the glass magnesium board and the XPS extruded sheet have low heat conductivity coefficient and good heat insulation, so that indoor heat is not easy to dissipate, and the indoor heat insulation effect is improved;
3. make glass magnesium board and floor form the heat preservation cavity between the room through supporting component, the heat preservation cavity forms the space of installation electromechanical pipeline to realize the pipeline separation, simultaneously, the heat preservation cavity forms the thermal-insulated space of air, has improved indoor holistic heat preservation effect.
Drawings
Fig. 1 is a sectional view showing the overall structure of the present embodiment;
fig. 2 is a sectional view showing the structure of the support member according to the present embodiment.
Reference numerals are as follows: 1. a wood floor; 2. a heat-insulating board; 21. XPS extruded sheets; 3. an overhead floor; 31. a glass magnesium board; 4. a support assembly; 41. a support base; 42. a support screw; 43. adjusting the nut; 44. a support plate; 5. a heat preservation cavity; 6. a connecting nut; 7. a self-tapping screw.
Detailed Description
The present application is described in further detail below with reference to figures 1-2.
The embodiment of the application discloses an overhead wood floor heat preservation system.
Referring to fig. 1, an overhead type timber apron heat preservation system, including laying in timber apron 1 at floor top, heated board 2 and the overhead bottom plate 3 that have the heat preservation effect are laid to timber apron 1's bottom, and in this embodiment, overhead bottom plate 3 is a plurality of glass magnesium boards 31 of concatenation mutually, and heated board 2 is a plurality of XPS extruded sheet 21 of concatenation mutually.
The plurality of spliced XPS extruded sheets 21 are laid at the bottom of the wood floor 1, and the glass magnesium board 31 is laid at the bottom of the XPS extruded sheet 21. The top of the floor is provided with a supporting component 4 for supporting the glass magnesium board 31, and the supporting component 4 enables a heat-insulating cavity 5 for installing an electromechanical pipeline to be formed between the glass magnesium board 31 and the floor. The heat insulation cavity 5 forms an air heat insulation layer, so that indoor heat is not easy to dissipate, and the heat insulation effect of the whole indoor environment and the comfort of the indoor environment are improved.
The heat conductivity coefficient of the glass magnesium board 31 is about 0.216 w/cm.k, the heat conductivity coefficient of the XPS extruded sheet 21 is about 0.033 w/cm.k, and both the glass magnesium board 31 and the XPS extruded sheet 21 have good heat preservation and insulation effects, so that the indoor heat preservation effect is improved. The glass magnesium board 31 and the XPS extruded sheet 21 also have good moisture resistance, so that the wood floor 1 is not easy to be corroded by water vapor, and the service life of the wood floor 1 is prolonged.
Because the heat resistance of the glass magnesium board 31 is higher than that of the XPS extruded board 21, the glass magnesium board 31 is laid at the bottom of the XPS extruded board 21, so that the XPS extruded board 21 is not easy to generate thermal deformation, and the service life of the XPS extruded board 21 is prolonged. The thickness ratio of the glass magnesium board 31 to the XPS extruded sheet 21 is 1: (0.5-0.8), and in the range of the ratio, the glass magnesium board 31 and the XPS extruded sheet 21 can generate better heat preservation effect and moisture-proof effect after being spliced. The thickness ratio of the glass magnesium board 31 to the wood floor 1 is 1: (0.8-1.2), in the range of the ratio, the glass magnesium board 31 plays a role in heat preservation, and meanwhile, the glass magnesium board 31 can play a good role in supporting the wood floor 1 and the XPS extruded sheet 21, so that the XPS extruded sheet 21 is not easy to break.
Referring to fig. 2, the supporting assembly 4 includes a supporting base 41, a supporting screw 42, an adjusting nut 43 and a supporting plate 44, the supporting base 41 is in a truncated cone shape or a square platform shape with a trapezoidal cross section, and the side with the larger cross section of the supporting base 41 abuts against the floor, so that the center of gravity of the supporting base 41 is as close to the floor as possible, and the supporting base 41 is not easy to move after being placed on the floor.
The connecting nut 6 is embedded at the end with the smaller section area of the supporting base 41, and the supporting screw rod 42 is connected with the connecting nut 6 in a threaded mode. When the supporting base 41 or the supporting screw 42 is damaged, the supporting base 41 or the supporting screw 42 is convenient to replace, and the maintenance cost can be saved. The adjusting nut 43 is screwed to the supporting screw 42, the supporting plate 44 is a metal member with high structural strength, the supporting plate 44 is welded to the adjusting nut 43, and the supporting plate 44 abuts against the bottom surface of the adjacent glass magnesium board 31, so that the top surfaces of the adjacent glass magnesium boards 31 are kept flush. When a worker performs construction work, after the glass magnesium panel 31 is laid on the support plate 44, the tapping screw 7 is inserted into the top surface of the glass magnesium panel 31, and the tapping screw 7 is screwed into the support plate 44, so that the glass magnesium panel 31 and the support plate 44 are fixedly connected.
When the staff is carrying out construction operation, through adjusting nut 43 at supporting screw 42 mounted position, can adjust the interval between backup pad 44 and the floor for glass magnesium board 31 keeps moderate interval with electromechanical pipeline, and it is convenient to adjust, can improve the efficiency of construction. Meanwhile, the cost generated by the whole system is low, and the cost can be saved.
The implementation principle of the overhead wood floor heat-insulation system in the embodiment of the application is as follows: during the construction process, a worker places a plurality of support bases 41 on a floor slab, connects support studs to the support bases 41 in a threaded manner, adjusts the mounting positions of adjusting nuts 43 on support screws 42 so that the top surfaces of a plurality of support plates 44 are kept parallel and level, lays a plurality of glass magnesium boards 31 on the tops of the support plates 44, lays an XPS extruded sheet 21 on the top surface of the glass magnesium boards 31, and finally lays a wood floor 1 on the top of the XPS extruded sheet 21, so that the cast-in-place steel bar and fine stone concrete is not needed during the construction process, the labor intensity is low, and the construction progress can be accelerated; the glass magnesium board 31 and the XPS extruded sheet 21 have low heat conductivity coefficient, so that indoor heat is not easy to lose; the glass magnesium board 31 and the XPS extruded sheet 21 also have good moisture resistance, so that the wood floor 1 is not easy to be corroded by water vapor, and the service life of the wood floor 1 can be prolonged.
The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.
Claims (9)
1. An overhead wood floor heat preservation system comprises a wood floor (1), and is characterized in that: the floor is characterized in that a heat insulation plate (2) with a heat insulation effect and an overhead bottom plate (3) are laid between the wood floor (1) and the floor slab, the overhead bottom plate (3) is laid at the top of the floor slab, the heat insulation plate (2) is laid at the top of the overhead bottom plate (3), and the wood floor (1) is laid at the top of the heat insulation plate (2).
2. The overhead wood floor insulation system according to claim 1, wherein: built on stilts bottom plate (3) are glass magnesium board (31), heated board (2) are XPS extruded sheet (21).
3. The overhead wood flooring insulation system according to claim 2, wherein: the thickness ratio of the glass magnesium board (31) to the XPS extruded sheet (21) is 1: (0.5-0.8).
4. The overhead wood flooring insulation system according to claim 2, wherein: the thickness ratio of the glass magnesium board (31) to the wood floor (1) is 1: (0.8-1.2).
5. The overhead wood floor insulation system according to claim 2, wherein: the floor is provided with a supporting component (4) for supporting the glass magnesium board (31), and a heat-insulating cavity (5) for laying an electromechanical pipeline is formed between the glass magnesium board (31) and the floor.
6. The overhead wood floor insulation system according to claim 5, wherein: support assembly (4) are including supporting base (41), support screw (42), adjusting nut (43) and backup pad (44), support base (41) butt in the floor top surface, support screw (42) demountable installation in support base (41) top, adjusting nut (43) threaded connection in support screw (42), backup pad (44) are fixed in adjusting nut (43), glass magnesium board (31) butt in backup pad (44) top surface.
7. The overhead wood floor insulation system according to claim 6, wherein: and a self-tapping screw (7) penetrates through the top surface of the glass magnesium board (31), and the self-tapping screw (7) is in threaded connection with the supporting plate (44).
8. The overhead wood floor insulation system according to claim 6, wherein: a connecting nut (6) is fixed on the supporting base (41), and the supporting screw rod (42) is in threaded connection with the connecting nut (6).
9. The overhead wood floor insulation system according to claim 6, wherein: the support plate (44) is welded to the adjustment nut (43).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202220885901.3U CN217537710U (en) | 2022-04-16 | 2022-04-16 | Overhead wood floor heat preservation system |
Applications Claiming Priority (1)
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CN202220885901.3U CN217537710U (en) | 2022-04-16 | 2022-04-16 | Overhead wood floor heat preservation system |
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CN217537710U true CN217537710U (en) | 2022-10-04 |
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CN202220885901.3U Active CN217537710U (en) | 2022-04-16 | 2022-04-16 | Overhead wood floor heat preservation system |
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- 2022-04-16 CN CN202220885901.3U patent/CN217537710U/en active Active
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