CN207569971U - A kind of graphene heat dissipation floor - Google Patents

Abstract

The utility model is related to a kind of graphene heat dissipation floors, include base material, nano-carbon film heating layer and upper strata panel from the bottom to top, metal heat-conducting layer is additionally provided among the nano-carbon film heating layer and upper strata panel, the upper strata panel through-thickness is provided with multiple heat dissipation blind holes.Metal heat-conducting layer in heating layer and upper strata panel is set, even heat can be disperseed, and the conduction of another heat is more smoothly, the setting heat dissipation blind hole on the panel of upper strata on the basis of the thickness for not reducing upper strata panel, improves radiating efficiency.

Description

A kind of graphene heat dissipation floor

Technical field

The utility model is related to a kind of floor, more particularly to a kind of graphene heat dissipation floor.

Background technology

In recent years, the mode of northern heating had very much, and the application of floor heating is also increasingly extensive, and the laying of floor heating generally requires Composite heating floor, upper strata panel is traditionally arranged to be wooden plank, and in heat transfer process, the heat between solid and air passes The biggest obstacle that effect is heat dissipation is passed, due to the laying of upper strata panel, heating floor is caused to have, and heat conduction efficiency is not high, heat dissipation Effect is undesirable, the shortcomings of for heat lag.Therefore in order to solve this problem, people spread frequently with relatively thin upper strata panel If to improve the heat-conducting effect on floor, but it is relatively thin floor bad mechanical strength that this, which brings the problem of new, resistance to compression, it is wear-resistant, The effect of heat resistanceheat resistant is poor, so as to reduce the bulk life time of heating floor.

Utility model content

In order to solve the above-mentioned technical problem, the utility model provides a kind of graphene heat dissipation floor, and technical solution is：

A kind of graphene heat dissipation floor, from the bottom to top including base material, nano-carbon film heating layer and upper strata panel, the nanometer Metal heat-conducting layer is additionally provided among carbon film heating layer and upper strata panel, the upper strata panel through-thickness is provided with multiple dissipate Hot blind hole.

Metal heat-conducting layer in heating layer and upper strata panel is set, even heat can be disperseed, and the conduction of another heat More smoothly, the setting heat dissipation blind hole on the panel of upper strata on the basis of the thickness for not reducing upper strata panel, improves heat dissipation effect Rate.

Preferably, it is additionally provided with far-infrared reflection film layer among the base material and the nano-carbon film heating layer.

Further, the graphene heat dissipation floor further includes multiple heat dissipation plug-in units, and the heat dissipation plug-in unit is movably arranged on On the metal heat-conducting layer, and it is inserted into heat dissipation blind hole.

Further, the heat dissipation plug-in unit includes heat conducting disk and the groups of fins being set in the heat conducting disk, the gold Belong to heat-conducting layer upper surface and be provided with fluting, the heat conducting disk is movably installed in the fluting.

The setting heat dissipation plug-in unit on metal heat-conducting layer, and be inserted into blind hole, the heat of metal heat-conducting layer is further prolonged It reaches in blind hole, further improves heat dissipation effect.

Further, the heat dissipation blind hole madial wall top is provided with spring, under the elastic force of spring, improves heat dissipation plug-in unit Contact tightness degree between metal heat-conducting layer, further improves heat dissipation effect.

Further, through-thickness is provided with multiple through-holes on the metal heat-conducting layer between the fluting, further Improve heat dissipation effect.

Further, the heat dissipation blind hole includes cylindrical first hole portion and above the cylindrical first hole portion The second hole portion of cone, the height in the cylindrical first hole portion is less than the half of the upper strata plate thickness, the heat dissipation The total height of blind hole is less than 3/4ths of the upper strata plate thickness, while heat dissipation effect is not influenced, improves face layer The mechanical strength of plate.

Further, the groups of fins is formed for the cooling fin of multiple parallel longitudinal settings, improves heat dissipation area, into One step improves heat dissipation effect.

Further, the heat dissipation channel for connecting the adjacent heat dissipation blind hole is provided among the upper strata panel, it is described The cross-sectional diameter of heat dissipation channel is less than the cross-sectional diameter of the heat dissipation blind hole, sets heat dissipation channel, will be between heat dissipation blind hole Heat transmitted mutually, heat circulates in heat dissipation channel, further improves heat dissipation effect.

Graphene heat dissipation floor provided by the utility model, it is ensured that floor mechanical strength is higher, and radiates simultaneously Effect is good, and another even heat distribution can make heat quickly be transferred to entire upper strata panel, when reducing heat supply in a short time It is long, heating efficiency is improved, the effect of so as to reach reduction energy consumption, improve floor service life.

Description of the drawings

The elevational schematic on 1 graphene of Fig. 1 embodiments heat dissipation floor；

The partial vertical sectional schematic diagram on 2 graphene of Fig. 2 embodiments heat dissipation floor；

The partial vertical sectional schematic diagram on 3 graphene of Fig. 3 embodiments heat dissipation floor.

Figure of description is that structure diagram, thickness length etc. does not do practical structures restriction effect, and attached drawing it Between without scaling relationship.

Specific embodiment

The utility model will be further described with reference to the accompanying drawings and examples.It is right with reference to the accompanying drawings and examples The utility model is further described；In the description of the present invention, it is to be appreciated that term " on ", " under ", The orientation or position relationship of the instructions such as " interior ", " outer ", "front", "rear", "left", "right" are based on orientation shown in the drawings or position Relationship is for only for ease of description the utility model and simplifies description rather than instruction or imply that signified device or element must There must be specific orientation, with specific azimuth configuration and operation, therefore it is not intended that scope of protection of the utility model Limitation.

Embodiment 1

As shown in Figure 1, a kind of graphene heat dissipation floor, from the bottom to top including base material 1, far-infrared reflection film layer (in attached drawing Do not show), nano-carbon film heating layer 3 and upper strata panel 4, be additionally provided among the nano-carbon film heating layer 3 and upper strata panel 4 Metal heat-conducting layer 5,4 through-thickness of upper strata panel be provided with it is multiple heat dissipation blind holes 6, it is described heat dissipation blind hole 6 opening to Under.

Graphene heat dissipation floor provided by the utility model, can be rapidly achieved heating temperature, while outward after energization Radiation On Human body beneficial infrared ray in boundary's has effects that waist-leg pain, arthritis, cervical spondylosis etc. preferably to alleviate, metal heat-conducting The setting of layer, another heat are uniformly dispersed, and transmit quickly, and heat dissipation blind hole can improve the range that distributes of heat, improve radiating efficiency.

Embodiment 2

As shown in Fig. 2, the graphene heat dissipation floor that the present embodiment is provided, difference lies in further limit with embodiment 1 Fixed, 5 upper surface of metal heat-conducting layer is provided with fluting 204, and the graphene heat dissipation floor further includes multiple heat dissipation plug-in units 201, the heat dissipation plug-in unit 201 includes heat conducting disk 202 and the groups of fins 203 being set in the heat conducting disk 202, the heat conduction Disk 202 is movably installed in the fluting 204, and the groups of fins 203 is inserted into heat dissipation blind hole 6, the heat conducting disk 202 Be provided with several raised 207 on side, be provided on 204 madial walls of the fluting it is several be adapted with described raised 207 it is recessed Slot 206, it is described heat dissipation 6 madial wall top of blind hole and the groups of fins 203 among be provided with spring 205.

Heat dissipation plug-in unit is set as heat conducting disk and groups of fins, heat conducting disk is in close contact with metal heat-conducting layer, can be maximum The raising heat transfer contact area of limit, and the setting of cooling fin can improve heat dissipation area, improve heat dissipation effect, and protrusion is inserted into In groove, fixed function can be played to heat dissipation plug-in unit, the setting of spring further improves contact of the heat conducting disk with metal heat-conducting layer Tightness degree improves heat radiation function, reduces energy consumption.

Embodiment 3

As shown in figure 3, the graphene heat dissipation floor that the present embodiment is provided, difference lies in further limit with embodiment 2 Fixed, 5 through-thickness of metal heat-conducting layer between the fluting 204 is provided with multiple through-holes 303；The heat dissipation blind hole 6 includes Cylindrical first hole portion and the second hole portion of cone above the cylindrical first hole portion, the cylindrical first hole portion Height be less than 4 thickness of upper strata panel half, it is described heat dissipation blind hole 6 total height be less than 4 thickness of upper strata panel 3/4ths, the groups of fins 203 is formed for the cooling fins 301 of multiple parallel longitudinal settings, 301 height of cooling fin Successively decreased successively outward by the cooling fin at center with width, make the vertical section of entire groups of fins 203 and the heat dissipation blind hole 6 Shape is adapted；The heat dissipation channel 302 for connecting the adjacent heat dissipation blind hole 6, the heat dissipation are provided among the upper strata panel 4 The cross-sectional diameter of channel 302 is less than the cross-sectional diameter of the heat dissipation blind hole 6.

The setting of above-mentioned heat dissipation blind hole, can take into account heating floor mechanical strength and radiating efficiency, groups of fins is set For the shape being adapted with heat dissipation blind hole, radiating efficiency can be further improved, heat dissipation channel separately can carry out intercommunication, heat by heat The conduction of amount is highly efficient, and heating effect is more preferably.

Above example is only that the preferred embodiment of the utility model is described, not to the model of the utility model It encloses and is defined, under the premise of the spirit of the design of the utility model is not departed from, those of ordinary skill in the art are to the utility model The various modifications made of technical solution and improvement, the protection domain that claims of the utility model determine should all be fallen into It is interior.

Claims (9)

1. The floor 1. a kind of graphene radiates, from the bottom to top including base material (1), nano-carbon film heating layer (3) and upper strata panel (4), It is characterized in that, be additionally provided with metal heat-conducting layer (5) among the nano-carbon film heating layer (3) and upper strata panel (4), it is described on Deck panels (4) through-thickness is provided with multiple heat dissipation blind holes (6), and Open Side Down for the heat dissipation blind hole (6).
2. The floor 2. graphene as described in claim 1 radiates, which is characterized in that the graphene heat dissipation floor further includes multiple Radiate plug-in unit (201), and the heat dissipation plug-in unit (201) is movably arranged on the metal heat-conducting layer (5), and be inserted into heat dissipation blind hole (6) in.
3. The floor 3. graphene as claimed in claim 2 radiates, which is characterized in that the heat dissipation plug-in unit (201) is including heat conducting disk (202) and the groups of fins (203) that is set in the heat conducting disk (202), metal heat-conducting layer (5) upper surface is provided with out Slot (204), the heat conducting disk (202) are movably installed in the fluting (204).
4. The floor 4. graphene as claimed in claim 3 radiates, which is characterized in that described heat dissipation blind hole (6) madial wall top is set It is equipped with spring (205).
5. The floor 5. graphene as claimed in claim 3 radiates, which is characterized in that the metal heat-conducting between the fluting (204) Layer (5) through-thickness is provided with multiple through-holes (303).
6. 6. the graphene heat dissipation floor as described in claim 3-5 is any, which is characterized in that the heat dissipation blind hole (6) is including circle The first hole portion of cylindricality and the second hole portion of cone above the cylindrical first hole portion, the cylindrical first hole portion Highly it is less than the half of upper strata panel (4) thickness, the total height of the heat dissipation blind hole (6) is less than the upper strata panel (4) 3/4ths of thickness.
7. The floor 7. graphene as claimed in claim 6 radiates, which is characterized in that the groups of fins (203) is multiple longitudinal directions The cooling fin (301) being arranged in parallel is formed.
8. 8. the graphene heat dissipation floor as described in claim 1-5 is any, which is characterized in that set among the upper strata panel (4) The heat dissipation channel (302) for connecting the adjacent heat dissipation blind hole (6) is equipped with, the cross-sectional diameter of the heat dissipation channel (302) is less than The cross-sectional diameter of the heat dissipation blind hole (6).
9. 9. graphene heat dissipation floor as described in claim 1, which is characterized in that the base material (1) and nano-carbon film hair Far-infrared reflection film layer is additionally provided among thermosphere (3).