CN218374933U - Assembled ceramic tile module of easily dismantling - Google Patents

Abstract

The application discloses assembled ceramic tile module of easily dismantling, wherein, this assembled ceramic tile module of easily dismantling includes ceramic tile body, rib, fossil fragments, card strip and the module that generates heat, and the rib is fixed in the edge of ceramic tile body back four sides, and fossil fragments connect in two adjacent ribs, and the card strip is inlayed between rib and fossil fragments, the module that generates heat with ceramic tile body's the back links to each other. This application connects two adjacent ceramic tile bodies through fossil fragments, wherein, ceramic tile body's middle part is supported through the module that generates heat, ceramic tile body's the edge of back four sides sets up the rib, the rib is inlayed on fossil fragments through the card strip, be used for realizing that ceramic tile body and fossil fragments can dismantle and be connected, this application makes the ceramic tile lay more portably, can reduce construction cost, and panel can independently dismantle, can greatly improve the convenience that the module that generates heat dismantles the maintenance through dismantling of ceramic tile, be favorable to wideling popularize the actual application of electric floor heating in the building trade.

Description

Assembled ceramic tile module of easily dismantling

Technical Field

The application relates to the technical field of building decoration, and more particularly relates to an easily-detachable assembled ceramic tile module.

Background

In the traditional building decoration industry, the most common method for paving and pasting ceramic tiles is to paste by using cement mortar, but is influenced by factors such as the quality of cement, the viscosity of the mortar, the pasting technology of constructors and the like, the firmness degree of pasting the ceramic tiles and the engineering quality cannot be reliably guaranteed, and the technical level of the constructors is excessively depended. Meanwhile, a large amount of cement and river sand are consumed in the construction process, so that the construction cost is high, and the current development trend of green environmental protection and sustainable development is violated.

On the other hand, with the gradual improvement of living standard, people pursue higher and higher comfort level of houses, floor heating is mostly applied to northern central heating areas in the past, and a lot of southern cities have been walked in now. The traditional floor heating mainly adopts water heating, but the water heating has the defects of complex construction process, need of gas supply of a residential building with a gas pipeline, higher reconstruction cost and the like, and on the basis, the electric heating which does not need gas and can be flexibly and locally reconstructed is generated.

In order to reduce the coal pollution in winter and improve the air quality, the nation vigorously pushes the use of clean energy, and then a series of policies of changing coal into electricity are subsidized, so that the use policy of using electricity when people are willing to use gas and electricity when people are willing to use electricity is encouraged, and the electric heating industry is led to a huge market space.

The floor heating structure mainly comprises two structural forms, wherein one structural form is a mortar layer paved at the bottom of the floor in a heating cable mode, the other structural form is packaged into a modularized graphene film and a modularized graphene module, or the other structural form is directly packaged to the bottom of a ceramic tile, and the modules are connected through a lead.

If the graphene film or the graphene module is packaged, the construction process generally adopts the modes of firstly leveling, laying heat insulation materials, then laying and connecting the graphene film or the graphene module, and finally leveling by cement mortar and laying and pasting floor tiles.

If the heating ceramic tile module is packaged into a whole, the construction process generally adopts the modes of firstly leveling, paving heat insulation materials, leveling by cement mortar and paving and connecting the heating ceramic tile module.

Above two kinds of modes all have a problem, the module that generates heat can be installed at the floor bottom along with ceramic tile, cement mortar non-detachably promptly, and connect with the wire between the module, if appear the wire behind the long-term use and connect badly, when the module trouble scheduling problem that generates heat, it is very difficult to rework the maintenance, need knockout ceramic tile, cement mortar layer are maintained, and because the wire also buries underground at cement mortar layer, when demolising monolithic ceramic tile, damage the connecting wire of ceramic tile on every side very easily, bring very big later maintenance hidden danger from this.

The existence of this kind of hidden danger makes the user have to be carefully in ten thousandths when selecting electric floor heating, worrys that the module that generates heat in case the quality reliability is not up to standard, if the back breaks down in the later stage, and it is arduous to maintain, has greatly influenced electric floor heating and has used widely in the building trade.

Therefore, the prior art is in need of improvement.

Disclosure of Invention

An object of this application is to provide an assembled ceramic tile module of easily dismantling, aims at solving among the prior art electric floor heating and installs on the floor because of ceramic tile non-detachably, leads to being difficult to dismantle, is unfavorable for the technical problem who maintains.

In order to achieve the purpose, the technical scheme adopted by the application is as follows:

the application provides an assembled ceramic tile module of easily dismantling, wherein, include:

a tile body;

the ribs are fixed on the edges of the four edges of the back of the tile body;

the keels are positioned on one sides, far away from the tile body, of the ribs, and the keels are connected to two adjacent ribs and used for connecting two adjacent tile bodies;

the clamping strip is embedded between the rib and the keel;

the heating module is connected with the back of the tile body.

In one embodiment, the method further comprises:

and the bolt fixing piece is connected with the rib and the keel and is used for preventing the tile body from being separated from the keel in the vertical direction.

In one embodiment, the bolt fastener includes the following:

the expansion bolts, expansion bolts one end is fixed in fossil fragments, and the other end is fixed in the rib, just expansion bolts is located two adjacent between the rib.

In one embodiment, the keel comprises:

the first body is positioned on one side, away from the tile body, of the rib;

the two first clamping grooves are arranged on the first body in parallel, the first clamping grooves are used for embedding the ribs, and the first body is connected with two adjacent ribs through the two first clamping grooves;

the square grooves are arranged on the first body at intervals and located between the two first clamping grooves, and the square grooves are used for connecting expansion bolts.

In one embodiment, the tendon comprises:

the second body is fixed on the edges of the four sides of the back of the tile body;

the second clamping groove is arranged on the second body, matched with the first clamping groove and connected with the first clamping groove to form a clamping groove for embedding the clamping strip;

the screw holes are formed in the second body and matched with the square grooves, and the screw holes are used for being connected with the expansion bolts.

In one embodiment, the heat generating module includes the following structure:

the heat insulation plate is embedded in the metal protection frame;

the heating film is fixed on the metal protection frame, one side of the heating film is attached to the ceramic tile body, and the other side of the heating film is attached to the heat preservation plate.

In one embodiment, a gap is arranged between two adjacent tile bodies, and the width of the gap is 1.5-2.5mm.

In one embodiment, the gap is filled with a removable underfill.

The application provides a pair of assembled ceramic tile module of easily dismantling's beneficial effect lies in at least:

the application discloses assembled ceramic tile module of easily dismantling, wherein, this assembled ceramic tile module of easily dismantling includes ceramic tile body, rib, fossil fragments, card strip and the module that generates heat, the rib is fixed in the edge of ceramic tile body back four sides, fossil fragments are located the rib is kept away from one side of ceramic tile body, just fossil fragments are connected in adjacent two the rib is used for connecting double-phase neighbour ceramic tile body, the card strip inlay in the rib with between the fossil fragments, the module that generates heat links to each other with ceramic tile body's the back. This application connects two adjacent ceramic tile bodies through fossil fragments, wherein, ceramic tile body's middle part is supported through the module that generates heat, ceramic tile body's the edge of back four sides sets up the rib, the rib is inlayed on fossil fragments through the card strip, be used for realizing that ceramic tile body and fossil fragments can dismantle and be connected, this application makes the ceramic tile lay more portably, can reduce construction cost, and panel can independently dismantle, can greatly improve the convenience that the module that generates heat dismantles the maintenance through dismantling of ceramic tile, be favorable to wideling popularize the actual application of electric floor heating in the building trade.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of an easily demountable fabricated tile module according to an embodiment of the present application;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a schematic structural view of an expansion bolt provided in an embodiment of the present application;

fig. 4 is a schematic view of an assembly structure of a tile body according to an embodiment of the present application;

FIG. 5 is an enlarged view of portion B of FIG. 4;

fig. 6 is a schematic view of an assembly structure of the keel and two adjacent tile bodies provided by the embodiment of the application;

fig. 7 is a schematic structural diagram of a heat generating module according to an embodiment of the present application;

FIG. 8 is an illustration of the effect of tile module assembly on the ground according to an embodiment of the present application;

fig. 9 is a schematic flow chart of a method for laying an easily detachable assembled tile module according to an embodiment of the present application.

Wherein, in the figures, the various reference numbers:

100. a tile body; 200. ribs; 300. a keel; 400. clamping the strip; 500. a heat generating module; 600. a bolt fixing member; 110. a gap; 210. a second body; 220. a second card slot; 230. a screw hole; 310. a first body; 320. a first card slot; 330. a square groove; 340. a gap; 510. a heat generating film; 520. a thermal insulation board; 530. a metal protective frame; 610. an expansion bolt; 611. expanding the casing; 612. the plunger is tightened.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly or indirectly secured to the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positions based on the orientations or positions shown in the drawings, and are for convenience of description only and not to be construed as limiting the technical solution. The terms "first", "second" and "first" are used merely for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.

Referring to fig. 1, the present embodiment provides an easily detachable assembled tile module, which includes: ceramic tile body 100, rib 200, fossil fragments 300, card strip 400 and the module 500 that generates heat (shown in fig. 4), rib 200 is fixed in the edge of ceramic tile body 100 back four sides, fossil fragments 300 are located one side that ceramic tile body 100 was kept away from to rib 200, and fossil fragments 300 connect in two adjacent ribs 200, be used for connecting two adjacent ceramic tile bodies 100, card strip 400 inlays between rib 200 and fossil fragments 300, the module 500 that generates heat links to each other with ceramic tile body 100's back, the module 500 that generates heat is located the hollow structure at ceramic tile body 100 back promptly, the module 500 that generates heat can support ceramic tile body 100's middle part.

It will be appreciated that an easily demountable modular tile module comprises: ceramic tile body 100, rib 200, fossil fragments 300, card strip 400 and module 500 generates heat, and wherein, rib 200 is fixed in the edge of ceramic tile body 100 back four sides, and fossil fragments 300 are located one side that ceramic tile body 100 was kept away from to rib 200, and rib 200 lays on fossil fragments 300 promptly, and card strip 400 inlays between rib 200 and fossil fragments 300, and fossil fragments 300 connect in two adjacent ribs 200 for connect two adjacent ceramic tile bodies 100. The heating module 500 is used for floor heating, the heating module 500 is located in the hollow structure at the back of the tile body 100, and the heating module 500 can support the middle of the tile body 100. For example, the ribs 200 are arranged on the edges of the four sides of the back of the tile body 100 in advance, for example, the ribs 200 can be adhered to the edges of the four sides of the back of the tile body 100 by glue; lay fossil fragments 300 on ground according to the specification of ceramic tile, the direction, later install the module 500 that generates heat in the central zone position of corresponding fossil fragments 300, in the meantime, can imbed fossil fragments 300 with calorie strip 400, later lay ceramic tile body 100 on fossil fragments 300 together with rib 200, make the rib 200 at the ceramic tile body 100 back align with each calorie strip 400 one by one, make rib 200 inlay with calorie strip 400 and target in place, restrict the removal of rib 200 through calorie strip 400, and then reach and fix ceramic tile body 100 the mesh on fossil fragments 300. When the tile body 100 needs to be disassembled, the tile body 100 only needs to be pulled out upwards, namely the ribs 200 are separated from the clamping strips 400, and the disassembly is simple. It can be seen that, in this embodiment, the embedding and matching of the ribs 200, the clamping strips 400 and the keels 300 enables the tile body 100 to be transversely assembled and laid on the ground, so as to reduce the amount of cement mortar, ensure the consistency of the tile seam size by improving the processing precision of the ribs 200, the clamping strips 400 and the keels 300, simplify the construction process, and enable the tile to be disassembled and assembled at the later stage. When the ceramic tile receives external force striking damage in daily use, or when electric heat module later stage broke down and need maintain, this embodiment easily dismantles alone, improves the convenience of maintaining.

Therefore, this embodiment connects two adjacent ceramic tile bodies 100 through fossil fragments 300, wherein, ceramic tile body 100's middle part supports through module 500 that generates heat, ceramic tile body 100's the edge of back four sides sets up rib 200, rib 200 inlays on fossil fragments 300 through calorie strip 400, be used for realizing that ceramic tile body 100 is connected with dismantling of fossil fragments 300, this application makes the ceramic tile lay more portably, can reduce construction cost, and panel can independently dismantle, can greatly improve the convenience that module 500 that generates heat dismantles the maintenance through dismantling of ceramic tile, be favorable to wideling popularize electric floor heating at the practical application of building trade.

Referring to fig. 1 and 2, in the specific structure of the present embodiment, the easily detachable assembled tile module further includes:

and a bolt holder 600, the bolt holder 600 being connected to the rib 200 and the keel 300, the bolt holder 600 being used to prevent the tile body 100 from being separated from the keel 300 from the vertical direction. For example, bolt fasteners 600 secure the ribs 200 to the keels 300 and prevent the tile body 100 from falling off the keels 300 in a vertical direction. When ceramic tile body 100 is needed, bolt fixing piece 600 can be firstly disassembled, and then ceramic tile body 100 is pulled out upwards, namely rib 200 is separated from clamping strip 400, so that the disassembly is simple.

Referring to fig. 3, optionally, the bolt fastener 600 may include the following structure: expansion bolts 610. The expansion bolts 610 are fixed at one end to the keel 300 and at the other end to the ribs 200, and the expansion bolts 610 are located between two adjacent ribs 200. For example, the expansion sleeve 611 of the expansion bolt 610 may be mounted on the keel 300 with the tightening plunger 612 of the expansion bolt 610 placed over the interior bore of the expansion sleeve 611. When the ribs 200 are embedded on the clamping strips 400, the tightening plunger 612 can be screwed down by using an inner hexagonal tool, so that the adjacent ribs 200 are fixed on the keels 300, and the adjacent tile bodies 100 and the keels 300 are tightly installed in place.

Referring to fig. 4 and 5, in the specific structure of the present embodiment, the keel 300 includes: first body 310, two parallel first draw-in grooves 320 and a plurality of square groove 330, first body 310 is located the one side that ceramic tile body 100 was kept away from to rib 200, two first draw-in grooves 320 all set up on first body 310, first draw-in groove 320 is used for inlaying rib 200, first body 310 connects two adjacent ribs 200 through two first draw-in grooves 320, a plurality of square groove 330 intervals set up on first body 310, and square groove 330 is located between two first draw-in grooves 320, square groove 330 is used for connecting expansion bolts 610's unable adjustment base, can understand, square groove 330 can set up other shapes and be used for adapting expansion bolts 610's unable adjustment base's shape, for example, expansion bolts 610's unable adjustment base can be the hexagon shape, square groove 330 then can set up the hexagonal prism cavity.

Referring to fig. 4 and 5, in the specific structure of the present embodiment, the rib 200 includes: the tile comprises a second body 210, a second clamping groove 220 and a plurality of screw holes 230, wherein the second body 210 is fixed at the edges of the four sides of the back of the tile body 100, the second clamping groove 220 is arranged on the second body 210, the second clamping groove 220 is matched with the first clamping groove 320, the second clamping groove 220 is connected with the first clamping groove 320 to form a clamping groove used for embedding the clamping strip 400, the screw holes 230 are arranged on the second body 210, the screw holes 230 are matched with the square grooves 330, and the screw holes 230 are used for connecting expansion bolts 610.

For example, keel 300 includes: the first body 310, the two parallel first card slots 320 and the plurality of square slots 330, wherein the first card slots 320 may extend along the length direction of the first body 310, in this embodiment, the first card slots 320 penetrate through the whole first body 310, so that the first card slots 320 and the card strip 400 may be conveniently installed. The square groove 330 is shaped to fit the fixed base of the expansion sleeve 611 and the square groove 330 is used to connect the fixed base of the expansion bolt 610. The rib 200 includes: the second body 210, the second slot 220 and the plurality of screw holes 230, the screw holes 230 are matched with the square groove 330, the screw holes 230 may be configured in a semi-cylindrical shape, and are matched with the adjacent ribs 200, two adjacent screw holes 230 form a cavity for assembling the expansion bolt 610, the screw holes 230 are used for installing the expansion sleeve 611 of the expansion bolt 610, as described above, the fixing base of the expansion sleeve 611 is matched with the square groove 330, that is, the fixing base of the expansion sleeve 611 is fixed in the square groove 330, the cylindrical portion of the expansion sleeve 611 is provided with an inner hole along the direction of the circle center, and is provided with a slot penetrating through the cylindrical body, the inner hole of the cylindrical body is in a stepped hole diameter, a portion near the tail end is larger, and can accommodate the tightening plunger 612, a portion near the base is smaller, when the tightening plunger 612 is tightened, the expansion sleeve 611 is simultaneously expanded, so as to tighten the ribs 200 at both sides of the expansion sleeve 611, the ribs 200 are forced in the direction far from the center line of the tile body 100, and the screw holes 230 are formed in a tapered shape. In addition, the lower part of the rib 200 is embedded and transversely clamped on the keel 300 through the clamping strip 400, and the expansion action of the expansion sleeve 611 can increase the lateral pressure of the clamping strip 400 with the rib 200 and the keel 300, so that the lateral friction force of the clamping strip 400 with the rib 200 and the keel 300 is increased, the embedding is more compact, and the vertical direction is not easy to be separated.

Referring to fig. 7, in the specific structure of the present embodiment, the heat generating module 500 includes: metal protective frame 530 and heating film 510, the embedded heated board 520 that is equipped with of metal protective frame 530, heating film 510 are fixed in on metal protective frame 530, and heating film 510 one side pastes with ceramic tile body 100 mutually, and heating film 510 opposite side pastes with heated board 520 mutually.

Optionally, the heating film 510 may be a graphene heating film, and the insulation board 520 may be a foamed polyurethane insulation board. The graphene heating film is used for floor heating, and the foamed polyurethane heat-insulation board has the functions of heat preservation, heat insulation, cavity reduction and support.

For example, when the heating film 510 is a graphene heating film and the insulation board 520 is a foamed polyurethane insulation board, the heating module 500 may be an integrated structure, that is, the graphene heating film, the foamed polyurethane insulation board and the metal protection frame 530 form a whole. When the heating module 500 is manufactured, the periphery of the metal protection frame 530 is firstly set to be an inner folded edge, and then the graphene heating film is fixed on the inner folded edge. The inner folded edge in this embodiment forms a certain angle with the bottom surface of the metal protection frame 530, for example, forms a 90 ° angle, and in this embodiment, the size of the graphene heating film is 0.5-2cm smaller than that of the metal frame, and the extension width of the inner folded edge is 0.5-3cm, which is convenient for fixing the graphene heating film. Therefore, when the graphene heating film is fixed to the inner flange, a gap layer is formed between the graphene heating film and the metal bezel 530, and the gap layer is filled with the polyurethane foam material. The metal protection frame 530 in this embodiment is provided with an injection hole for injecting a polyurethane foam material and an opening hole for placing the connection line of the graphene heating film, and when the graphene heating film is fixed, the connection line of the graphene heating film is placed at the opening hole on the metal protection frame 530. Next, in this embodiment, the metal protection frame 530 fixed with the graphene heating film is placed in a preset mold, and a polyurethane foam material is injected into an injection hole of the metal protection frame 530 and heated, so that the polyurethane foam material is preheated and expanded to obtain a foamed polyurethane insulation board. The mold in this embodiment is used to shape the metal protection frame 530, so as to avoid deformation of the metal protection frame 530 due to the preheating expansion of the polyurethane foam material. Finally, when the polyurethane foam material is filled in the gap layer, the polyurethane foam material is cooled, and the heating module 500 is obtained.

It is easy to think that the heating module 500 can be replaced by an extruded sheet, and the extruded sheet is placed on the back of the tile body 100, so as to form a common non-heating tile module, for example, please refer to fig. 4 and 5, the extruded sheet is located in the hollow structure on the back of the tile body 100, and the extruded sheet can be used for heat preservation and insulation, cavity reduction and supporting of the middle part of the tile body 100. Extruded sheets are generally referred to as extruded polystyrene foam sheets. The extruded sheet is a material formed by continuous extrusion foaming through a special process, hard films formed on the surface of the extruded sheet are uniform and flat, and the interior of the extruded sheet is completely closed and foamed continuously and uniformly and is of a honeycomb structure, so that the extruded sheet has the characteristics of high compression resistance, light weight, no water absorption, no air permeability, wear resistance and no degradation.

In the specific structure of this embodiment, please refer to fig. 5 and 6, a gap 110 is disposed between two adjacent tile bodies 100, and the width of the gap 110 is 1.5-2.5mm. Preferably, the width of the slit 110 is 2mm. For example, the width of the gap 110 is 2mm, in order to make the allen key enter the lower part from the seam, the specification size of the allen key is selected to be 1.5mm, and the specification of the corresponding tightening plunger 612 is M3; correspondingly, the hole diameter of the upper part of the expansion bolt 610 for accommodating the tightening plunger 612 is set to 3.2mm, and the hole diameter of the lower part is set to 2.5mm, so that the expansion sleeve 611 can be expanded after the hexagon socket head cap screw enters the hole diameter of the lower part.

Referring to fig. 6 and 8, in the specific structure of the present embodiment, a detachable gap filler is filled in the gap 110 for preventing external dust and impurities from entering the gap 110.

Referring to fig. 1, a gap 340 is formed between adjacent keels 300. The heating module 500 can be provided with an exhaust hole, a fluid channel is reserved between the tile body 100 and the heating module 500, the exhaust hole is communicated with the fluid channel and the gap 340, when the heating module 500 is heated and expanded, gas can escape from the gap 340, and the phenomenon that the tile body 100 is jacked up due to continuous expansion of the heating module 500 and the tile is tilted is effectively avoided. For example, one keel 300 may be disposed in the width direction of the back surface of one tile body 100, two keels 300 may be disposed in the length direction, and the keel 300 in the width direction is not closed to the keel 300 in the length direction, that is, a gap 340 is disposed between the keel 300 in the width direction and the keel 300 in the length direction, and two adjacent keels 300 in the length direction are not closed, that is, a gap 340 is also disposed between two adjacent keels 300 in the length direction.

Based on the easily detachable assembled tile module of the above embodiment, please refer to fig. 9, the present application further provides a laying method of the easily detachable assembled tile module, wherein the laying method comprises the following steps:

s100, ground pretreatment, namely leveling the ground so that the surface of the ground is flat.

Specifically, step S100 includes: ground preliminary treatment can carry out basic unit's processing to ground earlier, mainly is restoreing problem ground, forms new basic unit, avoids arousing the floor arch because original basic unit hollowing and chap, later can make level to ground, if make level through mud mortar for ground surfacing.

S200, laying keels, and laying the keels on the ground according to the specifications and the directions of the tiles.

S300, laying a heating module, and installing the heating module at the central area of the corresponding keel.

Specifically, the heating module 500 is laid, and the heating module 500 is installed at a central region of the corresponding keel 300, for example, the heating module 500 is installed at a central region of the corresponding keel 300.

And S400, mounting a bolt fixing piece at a preset position on the keel.

Specifically, step S400 includes: the expansion bolts 610 are installed at predetermined positions on the keel 300 such that the fixing bases of the expansion bolts 610 are fixed in the square grooves 330 of the keel 300.

S500, embedding the clamping strips into the clamping grooves of the keels.

S600, bonding the ribs at the edges of the four sides of the back of the tile body in advance, then placing the tile body and the ribs above the keels, adjusting the positions of the tile body and the keels, aligning the ribs on the back of the tile body with the clamping strips and the bolt fixing pieces one by one, and enabling the ribs to be embedded in the clamping strips.

Specifically, the ribs 200 are bonded to the edges of the four sides of the back of the tile body 100 in advance, then the tile body 100 and the ribs 200 are placed above the keels 300, the positions of the tile body 100 and the keels 300 are adjusted, and the ribs 200 on the back of the tile body 100 are aligned with the clamping strips 400 and the bolt fixing pieces 600 one by one, so that the ribs 200 are embedded in the clamping strips 400. For example, the tile body 100 and the rib 200 are placed above the keel 300, the positions of the tile body 100 and the keel 300 are adjusted, the rib 200 at the back of the tile body 100 is aligned with the clamping strips 400 and the bolt fixing members 600 one by one, namely, the rib 200 at the back of the tile body 100 is aligned with the clamping strips 400 one by one, and the rib 200 is aligned with the expansion bolts 610, so that the rib 200 is embedded on the clamping strips 400, and bolt holes of the rib 200 are sleeved on fixing bases of the expansion bolts 610.

S700, adjusting the bolt fixing piece to fix the ribs on the keels by the bolt fixing piece, and further enabling the adjacent tile bodies to be tightly connected with the keels.

Specifically, step S700 includes: the socket head of the expansion bolt 610 is tightened so that the expansion bolt 610 fixes the rib 200 on the keel 300, thereby tightly connecting the adjacent tile body 100 with the keel 300. For example, when the tightening plunger 612 is tightened, the expansion sleeve 611 expands outwardly in a synchronous manner, thereby tightening the ribs 200 on both sides of the expansion sleeve 611, and forcing the ribs 200 away from the centerline of the joint of the tile body 100. In addition, the lower part of the rib 200 is embedded and transversely clamped on the keel 300 through the clamping strip 400, and the expansion action of the expansion sleeve 611 can increase the lateral pressure of the clamping strip 400 with the rib 200 and the keel 300, so that the lateral friction force of the clamping strip 400 with the rib 200 and the keel 300 is increased, the embedding is more compact, and the vertical direction is not easy to be separated.

And S800, filling a detachable gap filler in the gap between the adjacent ceramic tile bodies to prevent external dust and impurities from entering the gap.

The laying method of the assembled ceramic tile module easy to disassemble provided by the embodiment has the beneficial effects that:

1. the embedding cooperation of rib 200, card strip 400 and fossil fragments 300 makes the ceramic tile transversely assemble and lays subaerial, reduces the quantity of cement mortar, and the accessible improves the machining precision of rib 200, card strip 400 and fossil fragments 300 and guarantees the uniformity of ceramic tile crack size, simplifies construction process.

2. The screw holes 230 of the adjacent ribs 200 are conical holes formed by expansion of the expansion bolts, the upper ends of the conical holes are larger, the lower ends of the conical holes are smaller, namely, the conical holes and the expansion sleeve 611 form an inverted cone structure, so that the tile, the ribs 200 and the keels 300 are connected more tightly, the resistance of the tile to be pulled out of the keels 300 in the vertical direction is increased, and the whole assembled tile module is laid more firmly.

3. The assembled tile modules are installed in a mechanical fastening mode, so that the assembled tile modules can be disassembled and assembled at the later stage. When the ceramic tile receives external force striking damage, or electric heat module later stage break down and need maintain, this embodiment is easily dismantled alone, improves the convenience of maintaining.

To sum up, the application discloses an assembled ceramic tile module of easily dismantling, wherein, this assembled ceramic tile module of easily dismantling includes ceramic tile body, rib, fossil fragments, card strip and the module that generates heat, and the rib is fixed in the edge of ceramic tile body back four sides, and fossil fragments connect in two adjacent ribs, and the card strip is inlayed between rib and fossil fragments, and the module that generates heat links to each other with ceramic tile body's back. This application connects two adjacent ceramic tile bodies through fossil fragments, wherein, ceramic tile body's middle part is supported through the module that generates heat, ceramic tile body's the edge of back four sides sets up the rib, the rib is inlayed on fossil fragments through the card strip, be used for realizing that ceramic tile body and fossil fragments can dismantle and be connected, this application makes the ceramic tile lay more portably, can reduce construction cost, and panel can independently dismantle, can greatly improve the convenience that the module that generates heat was dismantled and is maintained through dismantling of ceramic tile, be favorable to popularizing greatly that the electricity warms up the practical application in the building trade.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (8)

1. An easily removable, fabricated tile module, comprising:

a tile body;

the ribs are fixed on the edges of the four edges of the back of the tile body;

the keels are positioned on one sides, far away from the ceramic tile body, of the ribs, and the keels are connected to two adjacent ribs and used for connecting two adjacent ceramic tile bodies;

the clamping strip is embedded between the rib and the keel;

the heating module is connected with the back of the tile body.

2. An easy-to-disassemble fabricated tile module of claim 1 further comprising:

the bolt fixing piece is connected with the ribs and the keels and used for preventing the tile body from being separated from the keels in the vertical direction.

3. An easy to disassemble fabricated tile module as claimed in claim 2, wherein said bolt securing member comprises the following structure:

the expansion bolts, expansion bolts one end is fixed in fossil fragments, and the other end is fixed in the rib, just expansion bolts is located two adjacent between the rib.

4. An easy to disassemble fabricated tile module as claimed in claim 3, wherein said keel comprises:

the first body is positioned on one side, away from the tile body, of the rib;

the two first clamping grooves are arranged on the first body in parallel, the first clamping grooves are used for embedding the ribs, and the first body is connected with two adjacent ribs through the two first clamping grooves;

the square grooves are arranged on the first body at intervals and located between the two first clamping grooves, and the square grooves are used for connecting expansion bolts.

5. An easy to disassemble fabricated tile module as claimed in claim 4, wherein said ribs comprise:

the second body is fixed on the edges of the four sides of the back of the tile body;

the second clamping groove is arranged on the second body, matched with the first clamping groove and connected with the first clamping groove to form a clamping groove for embedding the clamping strip;

the screw holes are formed in the second body and matched with the square grooves, and the screw holes are used for being connected with the expansion bolts.

6. An easy-to-disassemble fabricated tile module according to claim 1, wherein said heat generating module comprises the following structure:

the heat insulation plate is embedded in the metal protection frame;

the heating film is fixed on the metal protection frame, one side of the heating film is attached to the ceramic tile body, and the other side of the heating film is attached to the heat preservation plate.

7. An easily demountable fabricated tile module according to claim 1, wherein a gap is provided between two adjacent tile bodies, and the width of said gap is 1.5-2.5mm.

8. An easily demountable, fabricated tile module according to claim 7, wherein the gap is filled with a removable caulk.

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