CN213418347U - Heat insulation structure of stone building floor - Google Patents

Abstract

The application relates to a heat preservation structure on stone material floor, including installing the support on ground, the top level of support has been laid the stone system floor, and the support upper berth between the floor in stone system floor and house is equipped with the heated board. This application has the stone system floor and passes through heated board and ground contact for it is subaerial that indoor temperature is difficult to transmit through the stone system floor, and then makes the change curve of indoor temperature more mild, and then has less the frequency that the air conditioner started to adjust indoor temperature, has reduced the energy consumption of air conditioner, accords with the effect of the requirement of national energy-concerving and environment-protective.

Description

Heat insulation structure of stone building floor

Technical Field

The application relates to the field of decoration floor laying, in particular to a heat insulation structure of a stone building floor.

Background

Along with the gradual improvement of living conditions, the requirements of people on the living environment are higher and higher, and the house decoration industry is prosperous.

In house decoration, a floor is usually laid on a floor slab of a blank room, and the floor made of natural stone is popular with people due to natural patterns and texture, so that the floor is widely applied to the floor laying of a living room. When the floor is laid, a layer of cement is firstly laid on the ground of a house by a decorator, then the stone floor is laid on the cement in a matching way, and the floor can be laid after the cement is solidified.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: the heat conduction ability of solid is higher for indoor through stone floor and ground production heat interaction easily, and then make indoor air conditioner need consume more electric energy and be used for maintaining indoor temperature, be unfavorable for the energy-concerving and environment-protective among the daily life.

SUMMERY OF THE UTILITY MODEL

In order to solve indoor easy through stone system floor and the external heat interaction that produces and then make the problem that the air conditioner energy consumption increases and be unfavorable for energy-concerving and environment-protective, the application provides a heat insulation construction on stone material floor.

The application provides a thermal insulation structure on stone material floor adopts following technical scheme:

the utility model provides a heat preservation structure on stone material floor, is including installing the support on ground, the top level of support has been laid the stone system floor, between the floor in stone system floor and house the support upper berth is equipped with the heated board.

Through adopting above-mentioned technical scheme, the heated board is passed through on the stone system floor and ground contact for on indoor temperature is difficult for transmitting subaerial through the stone system floor, and then makes the change curve of indoor temperature more gentle, and then less the frequency that the air conditioner started to adjust indoor temperature, reduced the energy consumption of air conditioner, accord with the requirement of national energy-concerving and environment-protective.

Optionally, a heat insulation cavity is formed in the heat insulation plate.

By adopting the technical scheme, the heat insulation cavity arranged in the heat insulation board improves the heat insulation performance of the heat insulation board because the heat conductivity of air is lower than that of solid.

Optionally, a sealed heat preservation bag is embedded in the heat insulation cavity in a matching manner, and air is filled in the heat preservation bag.

Through adopting above-mentioned technical scheme, the insulated bag can block the interaction of the air in the thermal-insulated intracavity and outside air, and then has further reduced the air in the thermal-insulated intracavity and the heat exchange interaction of external world, has further improved the heat-proof quality in thermal-insulated chamber.

Optionally, a waterproof layer is coated outside the heat insulation plate.

Through adopting above-mentioned technical scheme, the waterproof layer can be so that moisture is difficult for getting into in the gas pocket of the inside of heated board, and then makes the heat conduction efficiency of heated board difficult by the influence of moisture and rise for the heat preservation function of heated board is difficult for reducing.

Optionally, the insulation board is not in contact with the ground.

Through adopting above-mentioned technical scheme, carry out the heat interaction through the air between heated board and the ground for the change curve of the temperature of heated board itself is more level and smooth.

Optionally, the side wall of the insulation board contacting the wall surface is paved with a sealing plate, and the sealing plate can seal the insulation board and the ground.

Through adopting above-mentioned technical scheme, the heated board passes through to form behind the sealed between closing plate and the ground, and the heat exchange is difficult for producing with indoor air in the clearance between heated board and the ground to the air, has further reduced indoor temperature's range of variation.

Optionally, when the stone floor is the level, the level is provided with the mounting bar on the downside of one of them lateral wall, the mounting bar is followed its place the length direction setting of the lateral wall on stone floor, the stone floor with the upside of another lateral wall that the mounting bar is relative is improved level and is provided with spacing, spacing is followed its place the length direction setting of the lateral wall on stone floor, just the mounting bar with spacing can splice each other, and thickness sum between them with the thickness of stone floor equals, the mounting bar is worn to be equipped with construction bolt, works as the stone floor is laid when on the support, construction bolt's one end is passed the mounting bar with support threaded connection.

Through adopting above-mentioned technical scheme, staff's accessible spacing and the cooperation between the mounting bar install the stone floor on the support through construction bolt with splicing each other.

Optionally, mounting grooves are formed in the mounting bar in one-to-one correspondence with the mounting bolts, and bolt caps of the mounting bolts can be embedded in the mounting grooves in a matching manner.

Through adopting above-mentioned technical scheme, the nut of construction bolt inlays to establish and hides back in the mounting groove for both laminate more when the spacing is cooperating with the mounting bar.

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

1. the stone floor is contacted with the ground through the heat insulation plate, so that the indoor temperature is not easy to be transferred to the ground through the stone floor, the change curve of the indoor temperature is smooth, the frequency of starting the air conditioner to adjust the indoor temperature is reduced, the energy consumption of the air conditioner is reduced, and the national energy-saving and environment-friendly requirements are met;

2. some temperature on the stone system floor need just can continue to transmit away from the heated board through the transmission of insulated bag, has further improved the heat exchange degree of difficulty on stone system floor and ground, has strengthened the heat preservation effect of heated board.

Drawings

Fig. 1 is a schematic perspective view of the present application.

Fig. 2 is a schematic cross-sectional view of the insulation board and the structure thereon of the present application.

Description of reference numerals: 1. a support; 11. a stone floor; 111. mounting a bar; 112. a limiting strip; 113. installing a bolt; 114. mounting grooves; 2. a thermal insulation board; 21. a thermally insulating cavity; 22. a heat-preservation bag; 23. a waterproof layer; 3. and (7) sealing the plate.

Detailed Description

The present application is described in further detail below with reference to figures 1-2.

The embodiment of the application discloses insulation construction on stone material floor, refer to fig. 1 and 2, including support 1, support 1 passes through the bolted connection subaerial. A stone floor 11 is horizontally laid on the top of the bracket 1,

the stone floor 11 is provided with a mounting bar 111 integrally on the lower side of one side wall along the length direction of the side wall, and a limiting bar 112 integrally provided on the upper side of the other side wall of the stone floor 11 opposite to the mounting bar 111 along the length direction of the side wall. The mounting strip 111 and the limiting strip 112 can be spliced with each other, and the sum of the thicknesses of the mounting strip and the limiting strip is equal to the thickness of the stone floor 11.

Two mounting bolts 113 are arranged on the mounting bar 111 in a penetrating way, and when the stone floor 11 is laid on the bracket 1, one end of the mounting bolt 113 penetrates through the mounting bar 111 to be connected with the bracket 1 in a threaded way. Two mounting grooves 114 are further formed in the mounting bar 111, and the cap of the mounting bolt 113 can be correspondingly fitted and embedded in the mounting grooves 114.

The insulation board 2 is laid on the support 1 between the stone floor 11 and the floor of the house. The insulation board 2 is coated with a waterproof layer 23, and the waterproof layer 23 is formed by spraying waterproof paint. A heat insulation cavity 21 is formed in the heat insulation plate 2, a heat insulation bag 22 is embedded in the heat insulation cavity 21 in a matching mode, and the heat insulation bag 22 is in a sealed state and is filled with air.

Waterproof layer 23 on the upper surface of heated board 2 laminates with stone floor 11 mutually, is provided with the clearance between the lower surface of heated board 2 and the ground, and with the room wall laminating heated board 2 with equal fixed mounting have closing plate 3 on the lateral wall of wall contact, closing plate 3 is used for forming sealedly between the contact lateral wall of wall and heated board 2.

The application principle of the insulation construction of stone material floor board of the embodiment of this application is: when the heat on the stone floor 11 is transferred, the heat is transferred to the floor after sequentially passing through the upper layer of the heat insulation board 2, the air in the heat insulation bag 22, the lower layer of the heat insulation board 2 and the air in the gap between the heat insulation board 2 and the bottom plate.

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 heat preservation structure on stone material floor, its characterized in that: including installing support (1) on ground, stone system floor (11) have been laid to the top level of support (1), between stone system floor (11) and the floor in house support (1) upper berth is equipped with heated board (2).

2. The insulation structure of stone floor according to claim 1, wherein: and a heat insulation cavity (21) is formed in the heat insulation plate (2).

3. The heat insulation structure of stone floor as claimed in claim 2, wherein: the heat insulation cavity (21) is internally embedded with a sealed heat insulation bag (22), and the heat insulation bag (22) is filled with air.

4. The insulation structure of stone floor according to claim 3, wherein: the heat insulation plate (2) is coated with a waterproof layer (23).

5. The insulation structure of stone floor according to claim 4, wherein: the heat insulation plate (2) is not in contact with the ground.

6. The insulation structure of stone floor according to claim 5, wherein: the side wall of the heat insulation board (2) contacting with the wall surface is paved with a sealing plate (3), and the sealing plate (3) can seal the heat insulation board (2) and the ground.

7. The insulation structure of stone floor according to claim 1, wherein: when the stone floor (11) is horizontal, the lower side of one side wall is horizontally provided with an installation strip (111), the mounting bar (111) is arranged along the length direction of the side wall of the stone floor (11) where the mounting bar is arranged, a limiting strip (112) is horizontally arranged on the upper side of the other side wall of the stone floor (11) opposite to the mounting strip (111), the limiting strips (112) are arranged along the length direction of the side wall of the stone floor (11) where the limiting strips are arranged, the mounting strip (111) and the limiting strip (112) can be spliced with each other, the sum of the thicknesses of the mounting strip and the limiting strip is equal to the thickness of the stone floor (11), a mounting bolt (113) penetrates through the mounting strip (111), when the stone floor (11) is laid on the support (1), one end of the mounting bolt (113) penetrates through the mounting strip (111) to be in threaded connection with the support (1).

8. The insulation structure of stone floor according to claim 7, wherein: mounting grooves (114) are formed in the mounting strip (111) in one-to-one correspondence with the mounting bolts (113), and bolt caps of the mounting bolts (113) can be embedded in the mounting grooves (114) in a matching mode.

Images