CN202031290U

CN202031290U - Dry type paved geothermal floor

Info

Publication number: CN202031290U
Application number: CN2011200659769U
Authority: CN
Inventors: 李增清; 李渊
Original assignee: Individual
Current assignee: Individual
Priority date: 2011-03-14
Filing date: 2011-03-14
Publication date: 2011-11-09
Anticipated expiration: 2021-03-14

Abstract

The utility model relates to a dry type paved geothermal floor, which belongs to the technical field of building decorating materials and comprises a substrate. A decorating surface layer is arranged on the upper surface of the substrate, two sides of the substrate are respectively provided with a lock catch matched with the adjacent substrate, a groove concave upwards is formed on the lower surface of the substrate and comprises two side portions and an upper bottom arranged between the two side portions, a heat conducting medium layer is attached to the surface of the groove and at least covers the upper bottom of the groove, a heat insulation die block contacting with the ground is arranged under the substrate, a boss protruding upwards is formed on the upper surface of the heat insulation die block, the shape of the boss is matched with that of the groove arranged on the lower surface of the substrate, and a heating unit contacting with the heat conducting medium layer in a heat conduction manner is arranged between the heat insulation die block and the heat conducting medium layer. Accordingly, the surface of the floor can be heated uniformly, heat conduction path is shorter, heat efficiency is higher and integral paving thickness is smaller.

Description

The dry type heating floor of mating formation

Technical field

The utility model relates to a kind of dry type heating floor of mating formation, and belongs to technical field of building and decoration materials.

Background technology

In the prior art, the heat-conducting medium of heating floor or heater element all are arranged with the floor branch, or lay on the ground or be installed in inside such as other members between ground and the floor such as base plate.For example, Chinese patent literature discloses a kind of composite floor for heating [application number: CN 200510040599.2], solution be that existing heating floor coefficient of thermal conductivity is low, distortion is big, the easy problem of be full of cracks in surface.It comprises dash board, inferior dash board, central layer, base plate, is provided with horizontal thermal trough in the central layer, and vertical thermal trough is set in the base plate, and the laterally vertical mutually and perforation of thermal trough and vertical thermal trough laterally is filled with heat-conducting medium in thermal trough and the vertical thermal trough.In the technique scheme, heat-conducting medium needs elder generation with heat transferred base plate and central layer, then passes to time dash board and dash board again by base plate and central layer, its heat conduction path is long, heat conduction efficiency is lower, and the manufacturing process more complicated, and heat is difficult to be passed to rapidly floor surface.

Summary of the invention

The utility model purpose is to provide a kind of floor surface to be heated evenly everywhere, heat conduction path is shorter, the thermal efficiency is higher, the less dry type of the whole pavement thickness heating floor of mating formation, solved floor surface that prior art the exists inequality of being heated everywhere, problems such as heat conduction path is longer, and the thermal efficiency is lower.

Above-mentioned technical purpose of the present utility model mainly solves by the following technical programs: it comprises substrate, upper surface of base plate is provided with decorative surface layer, the both sides of substrate are respectively equipped with the snap close that can cooperate with adjacent substrate, described base lower surface is formed with the groove to fovea superior, described groove comprises both sides and the upper bottom portion between both sides, described groove surfaces is pasted with the heat-conducting medium layer, described heat-conducting medium layer covers the upper bottom portion of groove at least, described substrate below is provided with the heat insulation module that contacts with ground, the upper surface of described heat insulation module forms the boss of epirelief, the shape of described boss and the groove of base lower surface match, and are provided with the heater that contacts with the conduction of heat of heat-conducting medium layer between described heat insulation module and the heat-conducting medium layer.The utility model is provided with the groove of fovea superior in order to the heat-conducting medium layer to be set at base lower surface, thereby can effectively shorten the distance between the decorative surface layer of heat-conducting medium layer and upper surface of base plate, dwindle heat conduction path, improved the firing rate of floor surface, and simultaneously can reduce heat and conduct downwards, improved the thermal efficiency; On the other hand, the boss of heat insulation module can be engaged in the groove of base lower surface, even overlap in short transverse between heat insulation module and the substrate, thereby can effectively reduce the whole pavement thickness of the utility model heating floor.

As preferably, the degree of depth of described groove is 1/3 to 2/3 of a substrate thickness, thereby groove upper bottom portion to the distance of upper surface of base plate is controlled at 1/3 to 2/3 of substrate thickness, effectively shortens the heat-conducting medium layer to the conduction of heat distance between the substrate surface decorative surface layer.

As preferably, described heater structure in the form of sheets is laid between the boss of heat-conducting medium layer and heat insulation module, is equipped with thermal reflecting coating between the boss of heat insulation module and heater.Wherein, the heater of structure can close with heat-conducting medium is stacked in the form of sheets, thereby makes heat be passed to floor surface by the heat-conducting medium layer equably.

As preferably, described heat-conducting medium layer is formed with at least one heater containing cavity along the substrate longitudinal extension, described heater containing cavity protrudes downwards, and described heater is arranged in the heater containing cavity, is formed with the storage tank that is provided with for heater containing cavity outer wall on the described heat insulation module.

As preferably, have heat insulation gap between described heater containing cavity outer wall bottom and the described storage tank bottom, thereby can reduce the downward transmission of heat, reduce thermal losses, improve heat utilization efficiency.

As preferably, described heater containing cavity bottom is formed with cracking of longitudinal extension.Wherein, can be convenient to heater on the one hand cracking of heater containing cavity bottom formation longitudinal extension penetrates in the heater containing cavity; On the other hand the heater containing cavity when storage tank on the heat insulation module cooperates with the heater containing cavity from the gathering of cracking, thereby the heating physical efficiency is closely contacted with heater containing cavity inwall, play good conduction of heat.

As preferably, described heat-conducting medium layer comprises heat-conducting medium layer and following heat-conducting medium layer, the described groove surfaces that goes up heat-conducting medium layer and base lower surface attaches, described heat-conducting medium layer down is laid on the boss of heat insulation module, following heat-conducting medium layer is formed with to recessed U type groove, the soffit of described U type groove and last heat-conducting medium layer forms the heater containing cavity jointly, described heater is arranged in the heater containing cavity, is formed with on the described heat insulation module to supply the storage tank of the U type groove outer wall setting of heat-conducting medium layer down.

As preferably, have heat insulation gap between the U type groove outer wall bottom of described heat-conducting medium layer down and the described storage tank bottom, thereby can reduce the downward transmission of heat, reduce thermal losses, improve heat utilization efficiency.

As preferably, the upper bottom portion of described groove is parallel with the upper surface of substrate, is convenient to the processing and manufacturing of substrate on the one hand, can guarantee that on the other hand the upper surface of base plate decorative surface layer generates heat evenly everywhere.

Therefore, the utlity model has floor surface and be heated evenly everywhere, characteristics such as heat conduction path is shorter, and the thermal efficiency is higher, and whole pavement thickness is less.

Description of drawings

Fig. 1 is a kind of structural representation of the utility model embodiment 1;

Fig. 2 is the structural representation of the utility model embodiment 1 substrate and last heat-conducting medium layer;

Fig. 3 is a kind of structural representation of the utility model embodiment 2;

Fig. 4 is the structural representation of the utility model embodiment 2 substrates and heat-conducting medium layer;

Fig. 5 is a kind of structural representation of the utility model embodiment 3;

Fig. 6 is a kind of structural representation of the utility model embodiment 4;

Fig. 7 is a kind of structural representation of the utility model embodiment 4 substrates and heat-conducting medium layer.

The specific embodiment

Below by embodiment, and in conjunction with the accompanying drawings, the technical solution of the utility model is described in further detail.

Embodiment 1: as shown in Figure 1, the upper surface of substrate 1 is provided with decorative surface layer 2, the thin plate of decorative surface layer 2 for being attached to substrate, the both sides of substrate 1 are respectively equipped with the snap close 3 that can cooperate with adjacent substrate, as shown in Figure 2, the soffit of substrate 1 is formed with the groove 4 to fovea superior, the degree of depth of groove is 1/2 of a substrate thickness, groove 4 comprises that both sides 41 reach between both sides 41 and the upper bottom portion 42 parallel with the upper surface of substrate 1, both sides 41 are oblique following and outward-dipping from the both sides of upper bottom portion 42, the surface of groove 4 is pasted with the last heat-conducting medium layer of being made by aluminum alloy materials 5, last heat-conducting medium layer 5 covers the surface of upper bottom portion 42 and both sides 41, as shown in Figure 1, the below of substrate 1 is provided with the heat insulation module 6 that contacts with ground, the upper surface of heat insulation module 6 forms the boss 7 of epirelief, the shape of boss 7 and the groove of base lower surface 4 match, following heat-conducting medium layer 8 is laid on the boss of heat insulation module 6, following heat-conducting medium layer 8 is formed with to recessed U type groove 9, U type groove 9 forms heater containing cavity 10 jointly with the soffit of last heat-conducting medium layer 5, heater 11 is arranged in the heater containing cavity 10, be formed with on the heat insulation module 6 and supply the storage tank 12 of the U type groove 9 outer walls setting of heat-conducting medium layer down, have heat insulation gap 13 between U type groove 9 outer walls bottoms and storage tank 12 bottoms, between the boss of heat insulation module 6 and following heat-conducting medium layer 8, be equipped with thermal reflecting coating 14.

During laying, as shown in Figure 1, heat insulation module 6 is completed in advance on the ground, has certain interval between the adjacent heat insulation module 6, then spread reflectance coating 14 in the boss surface of heat insulation module 6, again the substrate that has fixed heat-conducting medium layer and following heat-conducting medium layer in the groove 4 is fastened on the heat insulation module 6 by groove 4, the outer wall of U type groove 9 then is engaged in the storage tank 12 of heat insulation module 6, then be mutually locked together between the adjacent substrate, in addition heater 11 be assembled in the heater containing cavity by snap close.

Embodiment 2: as shown in Figure 3, the upper surface of substrate 1 is provided with decorative surface layer 2, the thin plate of decorative surface layer 2 for being attached to substrate, the both sides of substrate 1 are respectively equipped with the snap close 3 that can cooperate with adjacent substrate, as shown in Figure 4, the soffit of substrate 1 is formed with the groove 4 to fovea superior, the degree of depth of groove is 1/2 of a substrate thickness, groove 4 comprises that both sides 41 reach between both sides 41 and the upper bottom portion 42 parallel with the upper surface of substrate 1, both sides 41 are oblique following and outward-dipping from the both sides of upper bottom portion 42, the surface of groove 4 is pasted with the heat-conducting medium layer of being made by aluminum alloy materials 15, last heat-conducting medium layer 15 covers the surface of upper bottom portion 42 and both sides 41, as shown in Figure 3, the below of substrate 1 is provided with the heat insulation module 6 that contacts with ground, the upper surface of heat insulation module 6 forms the boss 7 of epirelief, the shape of boss 7 and the groove of base lower surface 4 match, the heater 11 of structure is laid between the boss 7 of heat-conducting medium layer 15 and heat insulation module 6 in the form of sheets, is equipped with thermal reflecting coating 14 between the boss 7 of heat insulation module and heater 11.

During laying, as shown in Figure 3, heat insulation module 6 is completed in advance on the ground, has certain interval between the adjacent heat insulation module 6, then spread reflectance coating 14 in the boss surface of heat insulation module 6, heater 11 is mated formation on thermal reflecting coating 14, then the groove 4 with substrate cooperates with the boss 7 of heat insulation module 6, then is mutually locked together by snap close between the adjacent substrate again.

Embodiment 3: as shown in Figure 5, the upper surface of substrate 1 is provided with decorative surface layer 2, the thin plate of decorative surface layer 2 for being attached to substrate, the both sides of substrate 1 are respectively equipped with the snap close 3 that can cooperate with adjacent substrate, as shown in Figure 2, the soffit of substrate 1 is formed with the groove 4 to fovea superior, the degree of depth of groove is 1/2 of a substrate thickness, groove 4 comprises that both sides reach between both sides and the upper bottom portion parallel with the upper surface of substrate 1, both sides are oblique following and outward-dipping from the both sides of upper bottom portion, the surface of groove 4 is pasted with the heat-conducting medium layer of being made by aluminum alloy materials 15, heat-conducting medium layer 15 covers the surface of upper bottom portion and both sides, the below of substrate 1 is provided with the heat insulation module 6 that contacts with ground, the upper surface of heat insulation module 6 forms the boss 7 of epirelief, the shape of boss 7 and the groove of base lower surface 4 match, heat-conducting medium layer 15 is formed with a heater containing cavity 10 along substrate 1 longitudinal extension, heater containing cavity 10 protrudes downwards, heater is arranged in the heater containing cavity 10, be formed with the storage tank 12 that is provided with for heater containing cavity 10 outer walls on the heat insulation module 6, have heat insulation gap 13 between the outer wall bottom of heater containing cavity 10 and storage tank 12 bottoms.

Embodiment 4: as shown in Figure 6, the upper surface of substrate 1 is provided with decorative surface layer 2, the thin plate of decorative surface layer 2 for being attached to substrate, the both sides of substrate 1 are respectively equipped with the snap close 3 that can cooperate with adjacent substrate, as shown in Figure 2, the soffit of substrate 1 is formed with the groove 4 to fovea superior, the degree of depth of groove is 1/2 of a substrate thickness, groove 4 comprises that both sides reach between both sides and the upper bottom portion parallel with the upper surface of substrate 1, both sides are oblique following and outward-dipping from the both sides of upper bottom portion, the surface of groove 4 is pasted with the heat-conducting medium layer of being made by aluminum alloy materials 15, heat-conducting medium layer 15 covers the surface of upper bottom portion and both sides, the below of substrate 1 is provided with the heat insulation module 6 that contacts with ground, the upper surface of heat insulation module 6 forms the boss 7 of epirelief, the shape of boss 7 and the groove of base lower surface 4 match, heat-conducting medium layer 15 is formed with a heater containing cavity 10 along substrate 1 longitudinal extension, heater containing cavity 10 protrudes downwards, the bottom of heater containing cavity 10 is formed with 16 (referring to the Fig. 7) that crack of longitudinal extension, and the one side of cracking that forms longitudinal extension in heater containing cavity bottom can be convenient to heater and penetrate in the heater containing cavity; On the other hand the heater containing cavity when storage tank on the heat insulation module cooperates with the heater containing cavity from the gathering of cracking, thereby the heating physical efficiency is closely contacted with heater containing cavity inwall, play good conduction of heat.Heater is arranged in the heater containing cavity 10, is formed with the storage tank 12 that is provided with for heater containing cavity 10 outer walls on the heat insulation module 6, has heat insulation gap 13 between the outer wall bottom of heater containing cavity 10 and storage tank 12 bottoms.

Claims

1. dry type heating floor of mating formation, comprise substrate, upper surface of base plate is provided with decorative surface layer, the both sides of substrate are respectively equipped with the snap close that can cooperate with adjacent substrate, it is characterized in that: described base lower surface is formed with the groove to fovea superior, described groove comprises both sides and the upper bottom portion between both sides, described groove surfaces is pasted with the heat-conducting medium layer, described heat-conducting medium layer covers the upper bottom portion of groove at least, described substrate below is provided with the heat insulation module that contacts with ground, the upper surface of described heat insulation module forms the boss of epirelief, the shape of described boss and the groove of base lower surface match, and are provided with the heater that contacts with the conduction of heat of heat-conducting medium layer between described heat insulation module and the heat-conducting medium layer.

2. the dry type according to claim 1 heating floor of mating formation, the degree of depth that it is characterized in that described groove is 1/3 to 2/3 of a substrate thickness.

3. the dry type according to claim 1 and 2 heating floor of mating formation, it is characterized in that described heater in the form of sheets structure be laid between the boss of heat-conducting medium layer and heat insulation module, between the boss of heat insulation module and heater, be equipped with thermal reflecting coating.

4. the dry type according to claim 1 and 2 heating floor of mating formation, it is characterized in that described heat-conducting medium layer is formed with at least one heater containing cavity along the substrate longitudinal extension, described heater containing cavity protrudes downwards, described heater is arranged in the heater containing cavity, is formed with the storage tank that is provided with for heater containing cavity outer wall on the described heat insulation module.

5. the dry type according to claim 4 heating floor of mating formation is characterized in that having heat insulation gap between described heater containing cavity outer wall bottom is bottom described storage tank.

6. the dry type according to claim 4 heating floor of mating formation is characterized in that described heater containing cavity bottom is formed with cracking of longitudinal extension.

7. the dry type according to claim 1 and 2 heating floor of mating formation, it is characterized in that described heat-conducting medium layer comprises heat-conducting medium layer and following heat-conducting medium layer, the described groove surfaces that goes up heat-conducting medium layer and base lower surface attaches, described heat-conducting medium layer down is laid on the boss of heat insulation module, following heat-conducting medium layer is formed with to recessed U type groove, the soffit of described U type groove and last heat-conducting medium layer forms the heater containing cavity jointly, described heater is arranged in the heater containing cavity, is formed with on the described heat insulation module to supply the storage tank of the U type groove outer wall setting of heat-conducting medium layer down.

8. the dry type according to claim 7 heating floor of mating formation, the U type groove outer wall bottom that it is characterized in that described heat-conducting medium layer down have heat insulation gap between bottom described storage tank.

9. the dry type according to claim 1 and 2 heating floor of mating formation is characterized in that the upper bottom portion of described groove is parallel with the upper surface of substrate.