CN113123554B

CN113123554B - SPC (SPC) lock catch floor structure convenient for floor heating heat conduction and mounting process thereof

Info

Publication number: CN113123554B
Application number: CN202110279540.8A
Authority: CN
Inventors: 陶纯鑫; 单永根; 杨华; 孙国龙; 石红星; 吴士彬; 吕云青
Original assignee: Zhejiang Changxing Senda Bamboo & Wood Products Co ltd
Current assignee: Zhejiang Changxing Senda Bamboo & Wood Products Co ltd
Priority date: 2021-03-16
Filing date: 2021-03-16
Publication date: 2022-05-27
Anticipated expiration: 2041-03-16
Also published as: CN113123554A

Abstract

The invention discloses an SPC (special control pressure) lock catch floor structure convenient for floor heating to conduct heat and an installation process thereof, and the SPC lock catch floor structure comprises a floor body and a floor heating pipeline, wherein an L-shaped open slot is formed in one side of the floor body and is positioned on the bottom surface of the floor body, a pressing plate is arranged on the bottom surface of the floor body, one side of the L-shaped open slot is close to the top surface of the floor body and is provided with a plurality of tooth sockets which are uniformly distributed, the other side, corresponding to the L-shaped open slot, is far away from the top surface of the floor body, the pressing plate is positioned on one side, far away from the top surface of the floor body, of the L-shaped open slot and is in shaft connection with the bottom surface of the floor body through a torsion spring, the pressing plate and the L-shaped open slot form a locking slot, a protruding block matched with the locking slot is arranged on the other side, one end of the protruding block is fixedly connected with the floor body, a plurality of tooth posts matched with the tooth sockets one by one to the other end of the protruding block, and the floor heating pipeline is positioned on the bottom surface of the floor body and is in a circuitous way and is fixed on the ground. The invention has the beneficial effects that: the adjacent two floor bodies are connected tightly.

Description

SPC (SPC) lock catch floor structure convenient for floor heating heat conduction and mounting process thereof

Technical Field

The invention relates to the technical field of floors, in particular to an SPC (SPC) lock catch floor structure convenient for floor heating heat conduction and an installation process thereof.

Background

The SPC floor is a novel stone plastic floor, and is divided into a substrate layer, a printing layer, a wear-resistant layer and a UV layer, wherein each layer of connection is formed through hot compress and rolling once, glue adhesion is completely reversed, and the floor has the advantages of water resistance, skid resistance, environmental protection and the like. Therefore, the hard SPC indoor floor is very perfect to be used for home furnishing and decorating. The SPC floor is a 100% formaldehyde-free environment-friendly floor, is nontoxic and tasteless, and is waterproof, fire-resistant and damp-resistant; the SPC floor is superior to a strengthened floor in scratch resistance, resource use and skid resistance. The surface of the SPC floor has no holes and cannot seep water; after the stain is stained, the cleaning cloth is used for lightly wiping the stain, so that the stain can be easily cleaned, marks which are difficult to remove can not be left, and the special maintenance product is not needed for maintenance.

However, in the prior art, after the floor boards are used for a long time, a large gap is formed between two adjacent floor boards, which is caused by that the connection between two adjacent floor boards is not tight enough when the floor boards are laid.

Disclosure of Invention

The invention provides an SPC lock catch floor structure which is tightly connected and is convenient for floor heating heat conduction and an installation process thereof, aiming at overcoming the defect that the connection between two adjacent floors is not tight enough in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme:

an SPC lock catch floor structure convenient for floor heating and heat conduction comprises a floor body and a geothermal pipeline, wherein one side of the floor body is provided with an L-shaped open slot, the L-shaped open slot is positioned at the bottom surface of the floor body, the bottom surface of the floor body is provided with a pressing plate, one side of the L-shaped open slot is close to the top surface of the floor body and is provided with a plurality of tooth sockets which are uniformly distributed, the other side corresponding to the L-shaped open slot is far away from the top surface of the floor body, the pressing plate is positioned at one side of the L-shaped open slot far away from the top surface of the floor body and is in shaft joint with the bottom surface of the floor body through a torsion spring, the pressing plate and the L-shaped open slot form a locking slot, the other side corresponding to the floor body is provided with a convex block matched with the locking slot, one end of the convex block is fixedly connected with the floor body, and a plurality of tooth posts matched with the tooth sockets one by one are arranged from one end to the other end of the convex block, the geothermal pipeline is positioned on the bottom surface of the floor body and is fixed on the ground in a roundabout manner.

One side of the floor body is provided with an L-shaped open slot which is positioned at the bottom surface of the floor body, the bottom surface of the floor body is provided with a pressing plate, one side of the L-shaped open slot is close to the top surface of the floor body and is provided with a plurality of tooth sockets which are uniformly distributed, the other side of the L-shaped open slot is far away from the top surface of the floor body, the pressure plate is positioned at one side of the L-shaped open slot far away from the top surface of the floor body and is coupled with the bottom surface of the floor body through a torsion spring, the pressing plate and the L-shaped open slot form a locking slot, the other side corresponding to the floor body is provided with a convex block matched with the locking slot, one end of the convex block is fixedly connected with the floor body, a plurality of tooth columns matched with the tooth grooves one by one are arranged from one end to the other end of the convex block, the geothermal pipeline is positioned on the bottom surface of the floor body and is fixed on the ground in a roundabout manner, so that heat in the geothermal pipeline is transferred to the floor body. One of the floor bodies is arranged in the locking groove on the other floor body through the convex block, one side of the convex block is matched with the tooth grooves one by one through a plurality of tooth columns, meanwhile, the other side corresponding to the convex block is tightly pressed through the pressing plate and enables the tooth columns to be tightly matched with the tooth grooves, and finally the purpose of tight connection between the two adjacent floor bodies is achieved.

Preferably, the top surface of the pressing plate is positioned in the L-shaped open slot, and the bottom surface of the pressing plate and the bottom surface of the floor body are on the same plane. Because the ground is leveled to form a plane before the floor is laid, the floor is beneficial to the full contact between the floor body and the ground, and the floor body can be kept horizontal after being laid; meanwhile, the pressing plate is limited to rotate, and the structural stability of connection between two adjacent floor bodies is improved.

Preferably, the bottom surface of the floor body is provided with a groove, a heat conduction assembly is arranged in the groove and comprises a first heat conduction block matched with the groove, the top of the first heat conduction block is fixedly connected with the groove, the plane where the bottom of the first heat conduction block is located and the bottom surface of the floor body are on the same plane, so that the floor body can be kept horizontal after being laid, the bottom of the first heat conduction block is provided with a plurality of rectangular grooves, a plurality of clamping modules matched with geothermal pipelines are arranged in the rectangular grooves, and the plurality of clamping modules are uniformly distributed along the length direction of the rectangular grooves. The floor body passes through the tight geothermal pipe of clamp module clamp, on the one hand helps the heat in the geothermal pipe to transmit to heat conduction piece one through the tight module of clamp to on transmitting the floor body by heat conduction piece one, realize the high-efficient heat conduction of ground heating, on the other hand has improved the firm in connection nature of floor body and ground.

Preferably, the rectangular groove is internally provided with a limiting block, the limiting block is positioned at the center of the rectangular groove and is parallel to the length direction of the rectangular groove, two ends of the limiting block are fixedly connected with two ends of the rectangular groove respectively, the clamping module comprises an ejector rod, two gears and a clamp body matched with a geothermal pipeline, the limiting block is provided with a sliding hole matched with the ejector rod, the bottom of the rectangular groove is provided with a first avoiding groove matched with one end of the ejector rod so as to facilitate the up-and-down movement of the ejector rod, the left side and the right side of one end of the ejector rod are respectively provided with a plurality of uniformly distributed tooth blocks, the left side and the right side of the sliding hole are respectively provided with a second avoiding groove matched with the tooth blocks so as to facilitate the up-and-down movement of the ejector rod, the two gears are bilaterally and symmetrically distributed by taking the ejector rod as the center and are respectively meshed with the tooth blocks on the left side and the right side of the ejector rod, and the gears are positioned between the first avoiding groove and the limiting block, the equal fixedly connected with pivot in both ends of gear, the gear is rotated through the bottom of pivot and rectangular channel and is connected, be equipped with L type effect piece in the pivot, the stopper is located L type effect piece, the tip of L type effect piece be equipped with the gear assorted dodge groove three and respectively with the pivot fixed connection at gear both ends, when the ejector pin of being convenient for reciprocates, can mesh with the gear through the tooth piece mutually and drive the gear rotatory for the gear can drive L type effect piece rotatory through the pivot, the both ends of clamp are connected with the both ends of rectangular channel respectively, the clamp is located between stopper and the geothermol power pipeline, the center that the other end of ejector pin runs through slide opening and clamp in proper order contacts with the geothermol power pipeline, ejector pin and clamp elastic connection. In the initial state, the clamp body is in an open state, when an operator lays a floor body, the ejector rod acts on a geothermal pipeline under the action of the self gravity of the floor body, the geothermal pipeline generates a reaction force to enable the ejector rod to move upwards, the ejector rod is meshed with the gear through the tooth block to respectively drive the two gears to rotate, the gear drives one end of the L-shaped action block to rotate through the rotating shaft, the other end of the L-shaped action block rotates downwards and acts on the clamp body, the clamp body clamps the geothermal pipeline, the heat conduction of the geothermal pipeline is realized, the connection firmness of the floor body and the ground is improved, and the operation is simple; meanwhile, the limiting block is favorable for the up-and-down sliding of the ejector rod and plays a limiting role for the ejector rod, and the design is reasonable.

Preferably, the clamp body comprises a rectangular block and two clamp plates matched with the geothermal pipeline, the rectangular block and the limiting block are parallel to each other, two ends of the rectangular block are fixedly connected with two ends of the rectangular groove respectively, the rectangular block is provided with a through hole matched with the ejector rod, a first spring is arranged in the through hole, the first spring is sleeved on the ejector rod, one end of the first spring is fixedly connected with the inner side wall of the through hole, the other end of the first spring is fixedly connected with the ejector rod, in an initial state, the other end of the ejector rod is positioned outside the through hole under the action of the first spring and is convenient to contact with the geothermal pipeline, when the geothermal pipeline acts on the ejector rod in a reverse manner, the ejector rod moves upwards against the action force of the first spring, the first spring can prevent the ejector rod from being separated from the through hole, the stability of the structure is improved, the two clamp plates are distributed in a left-right symmetry manner by taking the rectangular block as a center, and the clamp plates are connected with the limiting block through torsional springs, the inside wall and the geothermal pipeline phase-match of splint are favorable to improving splint and geothermal pipeline's area of contact to be favorable to improving heat conduction efficiency, the lateral wall and the stopper of splint contact, and the effort of torsional spring is overcome to the stopper, makes two splint be in and opens the state, can act on the lateral wall of splint when the L type effect piece of being convenient for rotates downwards, reasonable in design.

Preferably, the left side and the right side of the rectangular groove are both provided with heat conducting grooves, the heat conducting grooves are internally provided with second springs and second heat conducting blocks, one ends of the second heat conducting blocks are elastically connected with the bottoms of the heat conducting grooves through the second springs, the other ends of the second heat conducting blocks are provided with arc-shaped grooves matched with the outer side walls of the clamping plates, one ends of the clamping plates are connected with the limiting blocks through torsional spring shafts, and the other ends of the clamping plates are in contact with the arc-shaped grooves. When the splint hug closely the geothermal pipe wall, the heat in the geothermal pipe is transmitted to the second heat-conducting block through the splint, and is finally transmitted to the floor body on the first heat-conducting block through the second heat-conducting block, thereby being beneficial to improving the heat transmission efficiency.

The invention also provides an installation process of the SPC lock catch floor convenient for floor heating and heat conduction, which comprises the following steps:

firstly, repairing and leveling the ground to form a new base layer;

secondly, paving a moisture-proof layer, a heat-insulation plate and a reflecting film respectively;

step three, laying a geothermal pipeline: the gap for laying the geothermal pipeline is determined according to the distance between two adjacent rectangular grooves on the floor body, and the position of the geothermal pipeline is fixed, so that the floor body is matched with the geothermal pipeline through the clamp bodies in the rectangular grooves conveniently, the floor body is fixedly connected with the geothermal pipeline, the connection firmness of the floor body and the ground is improved, and meanwhile, the heat conduction is facilitated;

step four, connecting a plurality of floor bodies through the matching of the convex blocks and the locking grooves, so that the purpose of tight connection between two adjacent floor bodies is achieved;

and step five, the ejector rods on the floor body act on the corresponding geothermal pipelines, the clamp bodies tightly hold the geothermal pipelines, and meanwhile, the floor body is fixed with the ground, so that the firmness of connection between the floor body and the ground is improved, and meanwhile, heat conduction is facilitated.

Preferably, in the fourth step, an operator needs to rotate the pressing plate on one of the floor bodies to open the locking groove, then the convex block on the other floor body is arranged in the locking groove, the tooth column is inserted into the corresponding tooth groove, and finally the pressing plate is released, and the pressing plate presses the convex block under the action of the torsion spring to lock the convex block, so that the two adjacent floor bodies are connected. One side of the convex block is matched with the tooth grooves one by one through a plurality of tooth columns, meanwhile, the other side corresponding to the convex block is tightly pressed through the pressing plate, the tooth columns can be tightly matched with the tooth grooves, and finally, the purpose of tight connection between two adjacent floor bodies is achieved.

Preferably, in the fifth step, when the ejector rod on the floor body is in contact with the corresponding geothermal pipeline, the floor body moves downwards under the action of self gravity, meanwhile, the ejector rod moves upwards under the reaction of the geothermal pipeline and drives the two gears to rotate through the gear block, the gears drive one end of the L-shaped action block to rotate through the rotating shaft, so that the other end of the L-shaped action block acts on the outer side wall of the clamping plate and drives the clamping plate to rotate inwards until the clamping plate holds the geothermal pipeline tightly. The connection firmness of the floor body and the ground is improved, heat conduction is facilitated, and meanwhile the heat conduction efficiency is improved; the operation is simple.

Preferably, in the inward rotating process of the clamping plate, the second heat conducting block moves towards one side of the geothermal pipeline under the reset action of the second spring and is always in contact with the outer side wall of the clamping plate. When the splint hug closely the geothermal pipe wall, the heat in the geothermal pipe is transmitted to the second heat-conducting block through the splint, and is finally transmitted to the floor body on the first heat-conducting block through the second heat-conducting block, thereby being beneficial to improving the heat transmission efficiency.

The invention has the beneficial effects that: the purpose of tight connection between two adjacent floor bodies can be achieved; the structural stability of the floor body connection is improved; on one hand, the floor heating structure is beneficial to realizing the high-efficiency heat conduction of the floor heating, and on the other hand, the connection firmness of the floor body and the ground is improved; the operation is simple, and the design is reasonable.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the floor body when connected to a geothermal pipe;

FIG. 3 is a cross-sectional view A-A of FIG. 2;

FIG. 4 is an enlarged view of the structure at B in FIG. 1;

FIG. 5 is an enlarged view of the structure at C in FIG. 2;

fig. 6 is an enlarged view of the structure at D in fig. 3.

In the figure: 1. the heat-conducting floor comprises a floor body, 2 parts of a geothermal pipeline, 3 parts of an L-shaped open slot, 4 parts of a pressing plate, 5 parts of a tooth groove, 6 parts of a locking groove, 7 parts of a convex block, 8 parts of a tooth column, 9 parts of a groove, 10 parts of a heat-conducting assembly, 11 parts of a first heat-conducting block, 12 parts of a rectangular groove, 13 parts of a clamping module, 14 parts of a limiting block, 15 parts of a push rod, 16 parts of a gear, 17 parts of a clamp body, 18 parts of a sliding hole, 19 parts of a first avoiding groove, 20 parts of a tooth block, 21 parts of a second avoiding groove, 22 parts of a rotating shaft, 23 parts of an L-shaped action block, 24 parts of a third avoiding groove, 25 parts of a rectangular block, 26 parts of a clamping plate, 27 parts of a through hole, 28 parts of a first spring, 29 parts of a heat-conducting groove, 30 parts of a second spring, 31 parts of a second heat-conducting block and 32 parts of an arc-shaped groove.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

In the embodiment shown in fig. 1 and 2, an SPC locking floor structure convenient for floor heating and heat conduction comprises a floor body 1 and a floor heating pipeline 2, wherein one side of the floor body 1 is provided with an L-shaped open slot 3, the L-shaped open slot 3 is positioned at the bottom surface of the floor body 1, the bottom surface of the floor body 1 is provided with a pressing plate 4, one side of the L-shaped open slot 3 is close to the top surface of the floor body 1 and is provided with a plurality of uniformly distributed tooth sockets 5, the other side corresponding to the L-shaped open slot 3 is far away from the top surface of the floor body 1, the pressing plate 4 is positioned at one side of the L-shaped open slot 3 far away from the top surface of the floor body 1 and is coupled with the bottom surface of the floor body 1 through a torsion spring, the pressing plate 4 and the L-shaped open slot 3 form a locking slot 6, the other side corresponding to the floor body 1 is provided with a convex block 7 matched with the locking slot 6, one end of the convex block 7 is fixedly connected with the floor body 1, one end to the other end of the convex block 7 is provided with a plurality of tooth sockets 8 one to one another end, the geothermal pipeline 2 is positioned on the bottom surface of the floor body 1 and is fixed on the ground in a roundabout manner. The top surface of the pressing plate 4 is positioned in the L-shaped open slot 3, and the bottom surface of the pressing plate 4 and the bottom surface of the floor body 1 are on the same plane.

As shown in fig. 1, fig. 2 and fig. 3, the bottom surface of the floor body 1 is provided with a groove 9, a heat conduction assembly 10 is arranged in the groove 9, the heat conduction assembly 10 comprises a first heat conduction block 11 matched with the groove 9, the top of the first heat conduction block 11 is fixedly connected with the groove 9, the plane where the bottom of the first heat conduction block 11 is located and the bottom surface of the floor body 1 are on the same plane, the bottom of the first heat conduction block 11 is provided with a plurality of rectangular grooves 12, the rectangular grooves 12 are internally provided with a plurality of clamping modules 13 matched with the geothermal pipelines 2, and the plurality of clamping modules 13 are uniformly distributed along the length direction of the rectangular grooves 12.

As shown in fig. 4, 5 and 6, a limiting block 14 is arranged in the rectangular groove 12, the limiting block 14 is positioned at the center of the rectangular groove 12 and is parallel to the length direction of the rectangular groove 12, two ends of the limiting block 14 are fixedly connected with two ends of the rectangular groove 12 respectively, the clamping module 13 comprises a top rod 15, two gears 16 and a clamp 17 matched with the geothermal pipeline 2, a sliding hole 18 matched with the top rod 15 is arranged on the limiting block 14, an avoiding groove 19 matched with one end of the top rod 15 is arranged at the bottom of the rectangular groove 12, a plurality of tooth blocks 20 are uniformly distributed on the left side and the right side of one end of the top rod 15, avoiding grooves 21 matched with the tooth blocks 20 are arranged on the left side and the right side of the sliding hole 18, the two gears 16 are symmetrically distributed on the left side and the right side by taking the top rod 15 as the center and are respectively engaged with the tooth blocks 20 on the left side and the right side of the top rod 15, the gear 16 is positioned between the avoiding groove 19 and the limiting block 14, the equal fixedly connected with pivot 22 in both ends of gear 16, gear 16 rotates through the bottom of pivot 22 with rectangular channel 12 and is connected, be equipped with L type effect piece 23 on the pivot 22, stopper 14 is located L type effect piece 23, the tip of L type effect piece 23 is equipped with and dodges groove three 24 with gear 16 assorted and respectively with the pivot 22 fixed connection at gear 16 both ends, the both ends of clamp 17 are connected with the both ends of rectangular channel 12 respectively, clamp 17 is located between stopper 14 and geothermol power pipeline 2, the other end of ejector pin 15 runs through slide opening 18 and clamp 17's center in proper order and contacts with geothermol power pipeline 2, ejector pin 15 and clamp 17 elastic connection.

As shown in fig. 4 and fig. 6, the clamp 17 includes a rectangular block 25 and two clamp plates 26 matched with the geothermal pipe 2, the rectangular block 25 is parallel to the limiting block 14, two ends of the rectangular block 25 are respectively fixedly connected with two ends of the rectangular groove 12, the rectangular block 25 is provided with a through hole 27 matched with the ejector rod 15, a first spring 28 is arranged in the through hole 27, the first spring 28 is sleeved on the ejector rod 15, one end of the first spring 28 is fixedly connected with the inner side wall of the through hole 27, the other end of the first spring 28 is fixedly connected with the ejector rod 15, the two clamp plates 26 are symmetrically distributed around the rectangular block 25, the clamp plates 26 are coupled with the limiting block 14 through torsion springs, the inner side wall of the clamp plate 26 is matched with the geothermal pipe 2, and the outer side wall of the clamp plate 26 is in contact with the limiting block 14.

As shown in fig. 4 and 5, the left and right sides of the rectangular groove 12 are provided with heat conducting grooves 29, two springs 30 and two heat conducting blocks 31 are arranged in the heat conducting grooves 29, one ends of the two heat conducting blocks 31 are elastically connected with the bottom of the heat conducting grooves 29 through the two springs 30, the other ends of the two heat conducting blocks 31 are provided with arc-shaped grooves 32 matched with the outer side walls of the clamping plates 26, one ends of the clamping plates 26 are connected with the limiting blocks 14 through torsion springs in a shaft mode, and the other ends of the clamping plates 26 are in contact with the arc-shaped grooves 32.

firstly, repairing and leveling the ground to form a new base layer;

step three, laying a geothermal pipeline 2: determining a gap for laying the geothermal pipeline 2 according to the distance between two adjacent rectangular grooves 12 on the floor body 1, and fixing the position of the geothermal pipeline 2;

step four, connecting a plurality of floor bodies 1 with locking grooves 6 through lugs 7 in a matching manner;

and step five, enabling the ejector rods 15 on the floor body 1 to act on the corresponding geothermal pipelines 2, enabling the clamp bodies 17 to tightly hold the geothermal pipelines 2, and meanwhile fixing the floor body 1 and the ground.

In the fourth step, an operator needs to rotate the pressing plate 4 on one of the floor bodies 1 to open the locking groove 6, then the convex block 7 on the other floor body 1 is arranged in the locking groove 6, the tooth column 8 is inserted into the corresponding tooth groove 5, and finally the pressing plate 4 is released, and the pressing plate 4 presses the convex block 7 under the action of the torsion spring and locks the convex block 7, so that the connection of two adjacent floor bodies 1 is realized.

In step five, when the top rod 15 on the floor body 1 contacts with the corresponding geothermal pipe 2, the floor body 1 moves downwards under the action of its own gravity, and at the same time, the top rod 15 moves upwards under the reaction of the geothermal pipe 2 and drives the two gears 16 to rotate through the gear block 20, the gear 16 drives one end of the L-shaped action block 23 to rotate through the rotating shaft 22, so that the other end of the L-shaped action block 23 acts on the outer side wall of the clamping plate 26 and drives the clamping plate 26 to rotate inwards until the clamping plate 26 holds the geothermal pipe 2 tightly.

During the inward rotation of the clamping plate 26, the second heat conducting block 31 moves towards the side where the geothermal pipe 2 is located under the reset action of the second spring 30 and is always in contact with the outer side wall of the clamping plate 26.

One of them floor body 1 is packed into locking groove 6 on another floor body 1 through lug 7 in, one side of lug 7 is through a plurality of tooth post 8 and tooth's socket 5 phase-match one by one, and meanwhile, the opposite side that lug 7 corresponds compresses tightly it and makes tooth post 8 closely cooperate with tooth's socket 5 through clamp plate 4, makes to be connected more closely between two adjacent floor bodies 1 finally.

Under the initial condition, two splint 26 are in the state of opening, when the operator lays floor body 1, ejector pin 15 acts on geothermol power pipeline 2 under floor body 1's self action of gravity, geothermol power pipeline 2 produces the reaction force and makes ejector pin 15 shift up, ejector pin 15 meshes with gear 16 through tooth piece 20 and drives two gears 16 rotatoryly respectively, gear 16 drives the one end rotation of L type effect piece 23 through pivot 22, make the other end of L type effect piece 23 rotate downwards and act on corresponding splint 26, make two splint 26 rotate downwards and press from both sides tight geothermol power pipeline 2, realize geothermol power pipeline 2's heat-conduction, floor body 1 and the fastness of being connected on ground have been improved, and the operation is simple.

When splint 26 hugged closely geothermol power pipeline 2 wall, heat in geothermol power pipeline 2 passes through on splint 26 transmits two 31 heat conduction pieces to transmit on one 11 heat conduction piece through two 31 heat conduction pieces, finally transmit on floor body 1, be favorable to improving thermal transmission efficiency.

Claims

1. The utility model provides a SPC hasp floor structure convenient to warm up heat conduction, characterized by, including floor body (1) and geothermol power pipeline (2), one side of floor body (1) is equipped with L type open slot (3), L type open slot (3) are located the bottom surface of floor body (1), the bottom surface of floor body (1) is equipped with clamp plate (4), one side of L type open slot (3) is close to the top surface of floor body (1) and is equipped with a plurality of evenly distributed's tooth's socket (5), the top surface of floor body (1) is kept away from to the corresponding opposite side of L type open slot (3), clamp plate (4) are located L type open slot (3) and keep away from one side of floor body (1) top surface and pass through the torsional spring coupling with the bottom surface of floor body (1), clamp plate (4) form locking groove (6) with L type open slot (3), the corresponding opposite side of floor body (1) is equipped with locking groove (6) assorted lug (7) One end of the convex block (7) is fixedly connected with the floor body (1), a plurality of tooth posts (8) which are matched with the tooth grooves (5) one by one are arranged from one end to the other end of the convex block (7), the geothermal pipeline (2) is positioned on the bottom surface of the floor body (1) and is fixed on the ground in a circuitous manner, the top surface of the pressing plate (4) is positioned in the L-shaped open slot (3), the bottom surface of the pressing plate (4) and the bottom surface of the floor body (1) are positioned on the same plane, the bottom surface of the floor body (1) is provided with a groove (9), a heat conducting assembly (10) is arranged in the groove (9), the heat conducting assembly (10) comprises a first heat conducting block (11) matched with the groove (9), the top of the first heat conducting block (11) is fixedly connected with the groove (9), the plane where the bottom of the first heat conducting block (11) is positioned on the same plane as the bottom surface of the floor body (1), the bottom of the first heat conducting block (11) is provided with a plurality of rectangular grooves (12), a plurality of clamping modules (13) matched with the geothermal pipeline (2) are arranged in the rectangular grooves (12), the clamping modules (13) are uniformly distributed along the length direction of the rectangular grooves (12), limiting blocks (14) are arranged in the rectangular grooves (12), the limiting blocks (14) are positioned at the centers of the rectangular grooves (12) and are parallel to the length direction of the rectangular grooves (12), two ends of each limiting block (14) are fixedly connected with two ends of each rectangular groove (12), each clamping module (13) comprises an ejector rod (15), two gears (16) and a clamp body (17) matched with the geothermal pipeline (2), each limiting block (14) is provided with a sliding hole (18) matched with the ejector rod (15), the bottom of each rectangular groove (12) is provided with a first avoiding groove (19) matched with one end of the ejector rod (15), the one end left and right sides of ejector pin (15) all is equipped with a plurality of evenly distributed's rack (20), the left and right sides of slide opening (18) all is equipped with and dodges groove two (21) with rack (20) assorted, and two gears (16) use ejector pin (15) to be bilateral symmetry distribution and mesh mutually with rack (20) of ejector pin (15) left and right sides respectively as the center, gear (16) are located and dodge between groove one (19) and stopper (14), the equal fixedly connected with pivot (22) in both ends of gear (16), gear (16) are rotated through the bottom of pivot (22) with rectangular channel (12) and are connected, be equipped with L type effect piece (23) on pivot (22), stopper (14) are located L type effect piece (23), the tip of L type effect piece (23) is equipped with and dodges groove three (24) assorted with gear (16) and respectively with pivot (22) fixed connection at gear (16) both ends, the two ends of the clamp body (17) are respectively connected with the two ends of the rectangular groove (12), the clamp body (17) is located between the limiting block (14) and the geothermal pipeline (2), the other end of the ejector rod (15) sequentially penetrates through the sliding hole (18) and the center of the clamp body (17) to be in contact with the geothermal pipeline (2), and the ejector rod (15) is elastically connected with the clamp body (17).

2. The SPC lock catch floor structure convenient for floor heating to conduct heat is characterized in that the clamp body (17) comprises a rectangular block (25) and two clamp plates (26) matched with a floor heating pipeline (2), the rectangular block (25) and the limiting block (14) are parallel to each other, two ends of the rectangular block (25) are respectively and fixedly connected with two ends of the rectangular groove (12), a through hole (27) matched with the ejector rod (15) is formed in the rectangular block (25), a first spring (28) is arranged in the through hole (27), the first spring (28) is sleeved on the ejector rod (15), one end of the first spring (28) is fixedly connected with the inner side wall of the through hole (27), the other end of the first spring (28) is fixedly connected with the ejector rod (15), the two clamp plates (26) are distributed in bilateral symmetry by taking the rectangular block (25) as a center, and the clamp plates (26) are connected with the limiting block (14) through a torsion spring in a shaft joint mode, the inner side wall of the clamping plate (26) is matched with the geothermal pipeline (2), and the outer side wall of the clamping plate (26) is contacted with the limiting block (14).

3. The SPC lock catch floor structure convenient for floor heating heat conduction as claimed in claim 2, wherein heat conduction grooves (29) are formed in the left side and the right side of the rectangular groove (12), a second spring (30) and a second heat conduction block (31) are arranged in the heat conduction grooves (29), one end of the second heat conduction block (31) is elastically connected with the bottom of the heat conduction grooves (29) through the second spring (30), an arc-shaped groove (32) matched with the outer side wall of the clamping plate (26) is formed in the other end of the second heat conduction block (31), one end of the clamping plate (26) is connected with the limiting block (14) through a torsion spring in a shaft mode, and the other end of the clamping plate (26) is in contact with the arc-shaped groove (32).

4. The installation process of the SPC latched floor structure convenient for floor heating to conduct heat as claimed in claim 3, is characterized by comprising the following steps:

firstly, repairing and leveling the ground to form a new base layer;

step three, laying a geothermal pipeline (2): determining a gap for laying the geothermal pipeline (2) according to the distance between two adjacent rectangular grooves (12) on the floor body (1), and fixing the position of the geothermal pipeline (2);

step four, connecting a plurality of floor bodies (1) with locking grooves (6) in a matching way through lugs (7);

fifthly, enabling an ejector rod (15) on the floor body (1) to act on the corresponding geothermal pipeline (2), enabling the clamp body (17) to hold the geothermal pipeline (2) tightly, and fixing the floor body (1) and the ground;

in the fifth step, when the ejector rod (15) on the floor body (1) is in contact with the corresponding geothermal pipeline (2), the floor body (1) moves downwards under the action of self gravity, meanwhile, the ejector rod (15) moves upwards under the reaction of the geothermal pipeline (2) and drives the two gears (16) to rotate through the tooth blocks (20), the gears (16) drive one end of the L-shaped action block (23) to rotate through the rotating shaft (22), so that the other end of the L-shaped action block (23) acts on the outer side wall of the clamping plate (26) and drives the clamping plate (26) to rotate inwards until the clamping plate (26) holds the geothermal pipeline (2) tightly.

5. The installation process of an SPC lock catch floor structure convenient for floor heating heat conduction is characterized in that in the fourth step, an operator needs to rotate a pressing plate (4) on one floor body (1) to open a locking groove (6), then a lug (7) on the other floor body (1) is installed in the locking groove (6), a tooth column (8) is inserted into a corresponding tooth groove (5), and finally the pressing plate (4) is released, so that the pressing plate (4) presses the lug (7) tightly under the action of a torsion spring and locks the lug, and therefore connection of two adjacent floor bodies (1) is achieved.

6. The installation process of an SPC lock floor structure convenient for floor heating heat conduction according to claim 4, characterized in that in the inward rotation process of the clamping plate (26), the second heat conduction block (31) moves towards one side of the floor heating pipeline (2) under the reset action of the second spring (30) and is always in contact with the outer side wall of the clamping plate (26).