CN110905148A

CN110905148A - Graphene ceramic tile capable of being electrified

Info

Publication number: CN110905148A
Application number: CN201911270749.7A
Authority: CN
Inventors: 夏学云; 夏杨江
Original assignee: Xuanmai Home Technology (shanghai) Co Ltd
Current assignee: Xuanmai Home Technology (shanghai) Co Ltd
Priority date: 2019-12-12
Filing date: 2019-12-12
Publication date: 2020-03-24
Anticipated expiration: 2039-12-12
Also published as: CN110905148B

Abstract

The invention discloses a graphene ceramic tile capable of being electrified, and relates to the technical field of decorative materials. This graphite alkene ceramic tile that can switch on, including ceramic tile and strengthening rib, the strengthening rib runs through fastening layer, graphite alkene heat-conducting layer, graphite alkene layer and the reflection stratum that generates heat respectively, and the equal fixed mounting in back up coat, graphite alkene heat-conducting layer, graphite alkene layer, emission layer and the heat preservation both sides has the waterproof board, and waterproof board one side is provided with the fastener. This graphite alkene ceramic tile that can switch on, when extrudeing the briquetting, the briquetting is extruded in the compression storehouse, the briquetting drives the connecting rod motion, the connecting rod drives and rotates the pearl and rotates, it rotates and drives the kelly and rotates the fixture block that makes its top to the chute in to rotate the pearl, because the size of a dimension of concave piece cooperatees with the size of a dimension of fastening groove, can realize that the concave groove piece fastens in the fastening groove, the block of deuterogamying fixture block and chute, the fixed effect of secondary has been realized, can make more firm and inseparable of two adjacent ceramic tile fastenings, prevent the problem in space and clearance.

Description

Graphene ceramic tile capable of being electrified

Technical Field

The invention relates to the technical field of decorative materials, in particular to a graphene ceramic tile capable of being electrified.

Background

The decorative material is a building material and its products for decorating various civil buildings to improve their functions and appearance and protect the stability and durability of main structure under various environmental factors. The ceramic tile is one kind of decorating material, and is made of refractory metal oxide and semi-metal oxide through the processes of grinding, mixing, pressing, glazing and sintering to form an acid and alkali resistant porcelain or stone material for building or decoration. At present, graphene tiles appear in the market, air conditioners and water heating modes are slowly replaced by the graphene tiles, and the graphene tiles are deeply welcomed by families.

But prior art's graphite alkene porcelain structural design is simple, and the effect of generating heat is general, and the reason lies in that current technique can't come out with the transmission that the heat of the inside production of ceramic tile can be fine, and single only hardly reaches the purpose of height indoor temperature through simple heat transfer to there are some problems in the graphite alkene ceramic tile of prior art in the concatenation installation, for example graphite alkene ceramic tile concatenation is inseparable, leads to the problem of infiltration leakage, the inside short circuit problem of graphite alkene ceramic tile appears even. Therefore, in order to solve the above problems, it is desirable to provide an electrically conductive graphene tile.

Disclosure of Invention

The invention aims to provide a graphene ceramic tile capable of being electrified so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a graphene ceramic tile capable of being electrified comprises a ceramic tile, wherein the ceramic tile is composed of a surface layer, a reinforcing layer, a graphene heat-conducting layer, a graphene heating layer, a reflecting layer and a heat-insulating layer, the surface layer is located on the outermost layer and is made of refractory metal oxide and semi-metal oxide through grinding, mixing, pressing, glazing and sintering, the reinforcing layer is located at the bottom of the surface layer and is fixedly connected with the surface layer, the graphene heat-conducting layer is located at the bottom of the reinforcing layer and is fixedly connected with the reinforcing layer, the graphene heating layer is located below the graphene heat-conducting layer, the graphene heating layer and the graphene heat-conducting layer are fixedly connected together, a heating chip is arranged on the graphene heating layer, a circuit lead of the heating chip is fixedly connected to one side of the graphene heating layer, a power supply connecting plug is fixedly connected to the other side of the graphene heating layer, and the reflecting layer is located at the bottom, the reflecting layer is fixedly connected with the graphene heating layer, the heat preservation layer is positioned at the bottom of the reflecting layer, the heat preservation layer is fixedly connected with the reflecting layer, the reinforcing layer, the graphene heat conduction layer, the graphene heating layer, the emission layer and the heat preservation layer are fixedly provided with waterproof boards on two sides, through holes are formed in the left side and the right side of each waterproof board, a fastener is arranged on one side of each waterproof board and consists of a concave block, a pressing block, a spring, a rotating ball and a clamping rod, the concave block is a rectangular block shaped like a Chinese character 'ao', compression bins are arranged in two convex ends of the concave block and are communicated with the outside, the pressing blocks are rectangular blocks, the number of the pressing blocks is two, the two pressing blocks are respectively clamped in the compression bins, limiting blocks are arranged at the upper end and the lower end of each pressing block and are used for preventing the pressing blocks from completely sliding out of the compression bins, under normal conditions, the spring props against the pressing block to extend out of the compression bin, the number of the rotating beads is two, the two rotating beads are respectively and movably arranged in an upper wall surface and a lower wall surface of a concave block groove, the rotating beads can rotate on the concave block wall surfaces, one end of each rotating bead is fixedly provided with a connecting rod, the connecting rod is positioned in the compression bin, the connecting rod has certain stretching and compressing capacity, the other end of the connecting rod is fixedly connected with the wall surface of the pressing block, the clamping rod is fixedly connected with the other end of each rotating bead, the clamping rod is parallel to the connecting rod, under normal conditions, the connecting rod is connected with the pressing block in an outward inclined state, the clamping rod inclines towards the inner side of the concave block groove, the clamping rod is a rectangular rod, the inner side of the top end of the clamping rod is provided with a clamping block, the other side of the waterproof plate is, fastening inslot is provided with the cooperation piece, and the cooperation piece can insert in the recess of spill piece, and the chute that corresponds with the fixture block is seted up at cooperation piece top, and the fixture block is in the chute, and the inside strengthening rib that is provided with of ceramic tile, strengthening rib run through fastening layer, graphite alkene heat-conducting layer, graphite alkene layer and the reflection stratum that generates heat respectively, and the strengthening rib reaches the standard grade both ends respectively the block inside surface course and heat preservation.

Preferably, the heating chips are uniformly distributed on the graphene heating layer.

Preferably, the flashing is a rectangular plate.

Preferably, the through hole is a circular hole.

Preferably, the reinforcing ribs are uniformly distributed inside the ceramic tile.

Preferably, the compression bin is a rectangular bin.

Preferably, the two limiting blocks are symmetrical up and down.

Compared with the prior art, the invention has the beneficial effects that:

(1) this graphite alkene ceramic tile that can switch on, through when extruding the briquetting, the briquetting is extruded in the compression storehouse, the spring is extruded, the briquetting drives the connecting rod motion, the connecting rod drives and rotates the pearl and rotates, it rotates and drives the kelly and rotates to rotate the pearl, make the kelly become toward recess outside slope from inclining to spill piece recess inboard, it rotates to rotate the pearl and drives the kelly and rotate the fixture block to the chute that makes its top, because the size of a dimension of spill piece cooperatees with the size of a dimension of fastening groove, can realize the fastening of groove piece at the fastening inslot, the block of deuterogamying fixture block and chute, the fixed effect of secondary has been realized, can make two adjacent ceramic tiles fastening more firm and inseparable, prevent the problem in space and clearance.

(2) This graphite alkene ceramic tile that can switch on through set up reflection stratum, heat preservation and graphite alkene heat-conducting layer respectively inside the ceramic tile, realized that the even heat dissipation that can produce the heat can be better is opened, disperses to open the back and from the bottom reflection to the ceramic tile intracavity upside, and the heat preservation has good heat preservation effect, and the heat that generates heat the layer production to graphite alkene can play a fine heat preservation effect, can be so that graphite alkene ceramic tile generates heat and dispels the heat more lastingly.

(3) This graphite alkene ceramic tile that can switch on through set up fastener and fastening groove on the ceramic tile waterproof board of difference, has realized can realizing installing fast and splicing two adjacent ceramic tiles, has improved the efficiency of work and the speed of installation.

(4) This graphite alkene ceramic tile that can switch on sets up the back up coat through vertically installing strengthening rib and top in the ceramic tile is inside, strengthening rib and back up coat add inside intensity and the toughness of ceramic tile for better one whole of becoming after the inside each layering of ceramic tile is fixed.

(5) This graphite alkene ceramic tile that can switch on, through set up the waterproof board in ceramic tile both sides, the through-hole is seted up to the waterproof board both sides and is placed power wire and plug in the through-hole, and the waterproof board not only can play the inside erosion that does not receive the water of protection ceramic tile, but also plays a guard action to the power wire and the plug of the chip that generates heat, prevents to leak the problem that the short circuit appears.

Drawings

FIG. 1 is a schematic view of the main structure of the tile of the present invention;

FIG. 2 is a cross-sectional view of a tile according to the present invention;

FIG. 3 is an enlarged view taken at A of FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the invention at B of FIG. 2;

FIG. 5 is an enlarged view of the invention at C in FIG. 4.

In the figure: 1 ceramic tile, 101 surface layers, 102 reinforcing layers, 103 graphene heat conducting layers, 104 graphene heat generating layers, 105 reflecting layers, 106 heat insulating layers, 2 heat generating chips, 3 power supply leads, 4 plugs, 5 waterproof plates, 6 through holes, 7 fasteners, 701 concave blocks, 702 pressing blocks, 703 springs, 704 rotating beads, 705 clamping rods, 8 compression bins, 9 limiting blocks, 10 connecting rods, 11 clamping blocks, 12 fastening grooves, 13 matching blocks, 14 chutes and 15 reinforcing ribs.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an electrified graphene ceramic tile comprises a ceramic tile 1, wherein the ceramic tile 1 is composed of a surface layer 101, a reinforcing layer 102, a graphene heat conduction layer 103, a graphene heat generation layer 104, a reflection layer 105 and a heat insulation layer 106, the surface layer 101 is located on the outermost layer, the surface layer 101 is made of refractory metal oxides and semi-metal oxides and is formed by grinding, mixing, pressing, glazing and sintering, the reinforcing layer 102 is located at the bottom of the surface layer 101, the reinforcing layer 102 is fixedly connected with the surface layer 101, the reinforcing layer 102 is woven by metal grids, the reinforcing layer 102 can increase strength and toughness of a ceramic tile 1 body, the graphene heat conduction layer 103 is located at the bottom of the reinforcing layer 102, the graphene heat conduction layer 103 is fixedly connected with the reinforcing layer 102, the graphene heat conduction layer 103 is made of graphene materials, the graphene heat conduction layer 103 has a good heat conduction effect, the quantity of heat is large, the graphene heat generation layer 104 is located below the graphene, the graphene heating layer 104 is fixedly connected with the graphene heat conduction layer 103, the heating chip 2 is arranged on the graphene heating layer 104, the heating chip 2 is uniformly distributed on the graphene heating layer 104, the uniform upward side transmission of the generated heat is facilitated, the heating chip 2 is a combination of carbon crystal and graphene, a circuit wire 3 of the heating chip 2 is fixedly connected with one side of the graphene heating layer 104, a power supply connection plug 4 is fixedly connected with the other side of the graphene heating layer 104, the reflection layer 105 is positioned at the bottom of the graphene heating layer 104, the reflection layer 105 is fixedly connected with the graphene heating layer 104, the reflection layer 105 is made of a far infrared reflection film, the far infrared reflection film is adopted to save more energy, the heating uniformity is good, the heat can be better reflected upward, the heat preservation 106 is positioned at the bottom of the reflection layer 105, the heat preservation 106 is fixedly connected with the reflection layer 105, the heat preservation layer 106 is a polyurethane foaming heat preservation plate, the heat preservation layer 106 has a good heat preservation effect, a good heat preservation effect can be achieved on heat generated by the graphene heating layer 104, the heat is prevented from being dissipated from the bottom of the ceramic tile 1, and the heat is prevented from being lost, the reinforcing layer 102, the graphene heat conduction layer 103, the graphene heating layer 104, the emission layer 105 and the heat preservation layer 106 are fixedly provided with waterproof plates 5 on two sides, each waterproof plate 5 is a rectangular plate, each waterproof plate 5 can achieve the effect of preventing water seepage inside the ceramic tile 1, through holes 6 are formed in the left side and the right side of each waterproof plate 5, each through hole 6 is a circular hole, a power supply wire 3 and a plug 4 connected with the heating layer 104 are placed in the through hole 6, a connected power supply wire 3 and the plug 4 can be inserted into the through holes 6 through a patch board, a protection effect is formed by alignment, the fastener 7 consists of a concave block 701, pressing blocks 702, springs 703, rotating balls 704 and a clamping rod 705, wherein the concave block 701 is a rectangular block shaped like a Chinese character 'ao', compression bins 8 are arranged in two convex ends of the concave block 701, the compression bins 8 are communicated with the outside, the pressing blocks 702 are rectangular blocks, the number of the pressing blocks 702 is two, the two pressing blocks 702 are respectively clamped in the compression bins 8, the upper and lower ends of the pressing blocks 702 are respectively provided with a limiting block 9, the limiting blocks 9 prevent the pressing blocks 702 from completely sliding out of the compression bins 8, the number of the springs 703 is two, the two springs 703 are respectively fixedly arranged on the wall surface in the cavity of the compression bins 8, the other ends of the two springs are connected with the wall surface of the pressing blocks 702, under normal conditions, the springs 703 prop against the pressing blocks 702 to extend out of the compression bins 8, the number of the rotating balls 704 is two, the two rotating balls 704 are respectively movably arranged in the upper, a connecting rod 10 is fixedly installed at one end of a rotating ball 704, the connecting rod 10 is positioned in a compression bin 8, the connecting rod 10 has certain extension and compression capacity, the other end of the connecting rod 10 is fixedly connected with the wall surface of a pressing block 702, a clamping rod 705 is fixedly connected at the other end of the rotating ball 704, the clamping rod 705 is parallel to the connecting rod 10, under normal conditions, the connecting rod 10 is connected with the pressing block 702 in an outward inclined state, the clamping rod 705 inclines towards the inner side of a groove of a concave block 701, the clamping rod 705 is a rectangular rod, a clamping block 11 is arranged on the inner side of the top end of the clamping rod 705, when the pressing block 702 is extruded, the pressing block 702 is extruded into the compression bin 8, a spring 703 is extruded, the pressing block 702 drives the connecting rod 10 to move, the connecting rod 10 drives the rotating ball 704 to rotate, the rotating ball 704 drives the clamping rod 705 to rotate, so that the clamping rod is inclined towards the outer, the fastening groove 12 is a concave groove, the concave block 701 is clamped in the fastening groove 12 and can realize the state of finishing the fastening clamping, the matching block 13 is arranged in the fastening groove 12, the matching block 13 can be inserted into the groove of the concave block 701, the top of the matching block 13 is provided with a chute 14 corresponding to the clamping block 11, the clamping block 11 is clamped in the chute 14, the fastening piece 7 and the fastening groove 12 are respectively arranged at two sides of the ceramic tile 1, the two connected ceramic tiles 1 can be fastened and clamped together through the fastening piece 7 and the fastening groove 12, the pressing block 702 enters the fastening groove 12 to carry out the extrusion motion, the rotating ball 704 rotates to drive the clamping rod 705 to rotate to enable the clamping block 11 at the top to be clamped in the chute 14, because the size of the concave block 701 is matched with the size of the fastening groove 12, the fastening of the concave block 701 in the fastening groove 12 can be realized, the clamping of the clamping block 11 and the chute 14 is matched, and the, can make more firm and inseparable of two adjacent ceramic tiles 1 fastening, prevent the problem in space and clearance, simultaneously also realized can realizing quick installation and two adjacent ceramic tiles 1 of concatenation, the efficiency of work and the speed of installation have been improved, 1 inside reinforcing rib 15 that is provided with of ceramic tile, reinforcing rib 15 runs through fastening layer 102 respectively, graphite alkene heat-conducting layer 103, graphite alkene generates heat layer 104 and

reflection stratum

105, 15 upper line both ends of reinforcing rib block are inside surface course 101 and heat preservation 106 respectively, 15 evenly distributed of reinforcing rib are inside ceramic tile 1, reinforcing rib 15 can increase 1 inside intensity of ceramic tile and toughness, make 1 inside each layering of ceramic tile better become a whole after fixed, through the effect of cooperation back up layer 102, make ceramic tile 1 become more firm.

The working steps are as follows:

the first step is as follows: the back up coat 102 adopts the metal mesh to work out and forms, and back up coat 102 can be for 1 body of ceramic tile increase strength and toughness, and graphite alkene heat-conducting layer 103 has good heat conduction effect, and the transfer heat is more, and chip 2 evenly distributed that generates heat is favorable to the even past side transfer of heat with the production on graphite alkene layer 104 that generates heat.

The second step is that: reflecting layer 105's material is far infrared reflectance coating, adopt far infrared reflectance coating more energy-conserving, and the homogeneity that generates heat is good, can be better with the heat up upper reflection, heat preservation 106 adopts polyurethane foam heated board, heat preservation 106 has good heat preservation effect, the heat that generates heat layer 104 to graphite alkene produced can play a fine heat preservation effect, prevent that the heat from distributing away from 1 bottom of ceramic tile, lead to the problem of heat loss, waterproof board 5 can play the problem of playing waterproof infiltration to 1 inside of ceramic tile.

The third step: when the pressing block 702 is pressed, the pressing block 702 is pressed into the compression bin 8, the spring 703 is pressed, the pressing block 702 drives the connecting rod 10 to move, the connecting rod 10 drives the rotating ball 704 to rotate, the rotating ball 704 drives the clamping rod 705 to rotate, so that the clamping rod 705 inclines from the inner side of the groove of the concave block 701 to the outer side of the groove, the rotating ball 704 rotates to drive the clamping rod 705 to rotate, so that the clamping block 11 at the top of the clamping rod is clamped in the inclined groove 14, because the size of the concave block 701 is matched with that of the fastening groove 12, the concave block 701 can be fastened in the fastening groove 12, and then the clamping of the clamping block 11 and the inclined groove 14 is matched, the secondary fixing effect is realized, two adjacent ceramic tiles 1 can be fastened more firmly and tightly, the problems of gaps and clearances are prevented, meanwhile, the quick installation and splicing of the two adjacent ceramic tiles 1 can be realized, and the working efficiency and the installation speed are improved.

The fourth step: the reinforcing ribs 15 can increase the strength and toughness of the interior of the ceramic tile 1, so that the interior of the ceramic tile 1 can be better integrated after being layered and fixed, and the ceramic tile 1 can be firmer under the action of the reinforcing layer 102.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a graphite alkene ceramic tile that can energize, includes ceramic tile (1) and strengthening rib (15), its characterized in that: ceramic tile (1) from the top down comprises surface course (101), back up coat (102), graphite alkene heat-conducting layer (103), graphite alkene layer (104) that generates heat, reflector layer (105) and heat preservation (106) fixed connection in proper order, strengthening rib (15) run through back up coat (102) respectively, graphite alkene heat-conducting layer (103), graphite alkene layer (104) and reflector layer (105) generate heat, back up coat (102), graphite alkene heat-conducting layer (103), graphite alkene layer (104) that generates heat, emitter layer (105) and heat preservation (106) both sides are equal fixed mounting have waterproof board (5), waterproof board (5) one side is provided with fastener (7), fastening groove (12) that correspond with fastener (7) are seted up to waterproof board (5) opposite side.

2. An energizable graphene tile according to claim 1, wherein: and two ends of the upper line of the reinforcing rib (15) are respectively clamped inside the surface layer (101) and the heat-insulating layer (106).

3. An energizable graphene tile according to claim 1, wherein: fastener (7) comprise concave piece (701), briquetting (702), spring (703), rotation pearl (704) and kelly (705), concave piece (701) fixed mounting has seted up compression storehouse (8) at waterproof board (5) wall middle part, two protruding end insides of concave piece (701), compression storehouse (8) and external intercommunication.

4. An energizable graphene tile according to claim 3, wherein: the briquetting (702) is a rectangular block, the quantity of briquetting (702) is two, and two briquetting (702) block respectively in compression storehouse (8), and both ends all are provided with stopper (9) about briquetting (702).

5. An energizable graphene tile according to claim 3, wherein: the number of the springs (703) is two, the two springs (703) are respectively and fixedly installed on the wall surface in the cavity of the compression bin (8), and the other end of the springs is connected with the wall surface of the pressing block (702).

6. An energizable graphene tile according to claim 3, wherein: the number of the rotating balls (704) is two, the two rotating balls (704) are respectively movably mounted in the upper wall surface and the lower wall surface of the groove of the concave block (701), one end of each rotating ball (704) is fixedly provided with a connecting rod (10), the connecting rod (10) is located in the compression bin (8), and the other end of each connecting rod (10) is fixedly connected with the wall surface of the pressing block (702).

7. An energizable graphene tile according to claim 3, wherein: the clamping rod (705) is a rectangular rod, the clamping rod (705) is fixedly connected to the other end of the rotating bead (704), the clamping rod (705) is parallel to the connecting rod (10), the clamping rod (705) inclines towards the inner side of the groove of the concave block (701), and the clamping block (11) is arranged on the inner side of the top end of the clamping rod (705).

8. An energizable graphene tile according to claim 7, wherein: the fixture block (11) is a triangular prism.

9. An energizable graphene tile according to claim 1, wherein: the fastening groove (12) is a concave groove, a matching block (13) is arranged in the fastening groove (12), and the matching block (13) is clamped in the concave groove of the concave block (701).

10. An energizable graphene tile according to claim 9, wherein: the upper end and the lower end of the matching block (13) are provided with inclined grooves (14) corresponding to the clamping blocks (11), and the clamping blocks (11) are clamped in the inclined grooves (14).