CN213514044U - Graphite alkene electricity of safe type concatenation formula warms up - Google Patents

Abstract

The utility model discloses a graphite alkene electricity of safe type concatenation formula warms up, including baffle, mounting panel and main part, the intermediate position department of the inside bottom of main part installs heat conduction structure, the both sides of the inside bottom of main part all are provided with two auxiliary rods, and one side of auxiliary rod outer wall all overlaps and is equipped with buffer spring, the connecting rod is all installed through the articulated elements in the auxiliary rod top of one side, and the top of connecting rod installs the fly leaf through the articulated elements, two second cavities have all been seted up to the inside of main part both sides, and the inside bottom of second cavity all is provided with auxiliary spring. The utility model discloses a device heats the during operation, and unnecessary heat is absorbed by the heat-conducting seat, and rethread first heat-conducting plate, second heat-conducting plate, third heat-conducting plate and fourth heat-conducting plate conduct after that for carry out energy transfer between each main part, make thermal reuse, this energy utilization who is favorable to improving the device.

Description

Graphite alkene electricity of safe type concatenation formula warms up

Technical Field

The utility model relates to an electricity warms up technical field, specifically is a graphite alkene electricity of safe type concatenation formula warms up.

Background

The electric floor heating system takes a heating cable as a heating body, is used for being laid under various floor materials, such as tiles, marble and the like, and is matched with an intelligent temperature controller system, so that the electric floor heating system is comfortable, environment-friendly, efficient, energy-saving, free of maintenance, independent in use of each room, long in service life and hidden, and the existing graphene electric floor heating system has many defects.

Firstly, the traditional graphene electric floor heating is low in energy utilization rate, so that heat is dissipated too fast;

secondly, the traditional graphene electric floor heating device does not have a good protection function, so that long-time stress is caused, and the device is easy to damage;

third, traditional graphite alkene electricity warms up, is not convenient for carry out the dismouting, wastes time and energy when maintaining.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a graphite alkene electricity of safe type concatenation formula warms up to solve the utilization ratio of the energy that proposes in the above-mentioned background art not high, do not have fine safeguard function and be not convenient for carry out the problem of dismouting.

In order to achieve the above object, the utility model provides a following technical scheme: a safe spliced graphene electric floor heating device comprises a baffle, a mounting plate and a main body, wherein a heat conduction structure is installed at the middle position of the bottom end in the main body, two auxiliary rods are arranged on two sides of the bottom end in the main body, a buffer spring is sleeved on one side of the outer wall of each auxiliary rod, a connecting rod is installed at the top end of each auxiliary rod on one side through an articulated piece, a movable plate is installed at the top end of each connecting rod through the articulated piece, two second cavities are formed in two sides of the main body, auxiliary springs are arranged at the bottom ends of the interiors of the second cavities, sliders are connected to the top ends of the auxiliary springs, first cavities are formed in the middle positions of the interiors of four side edges of the main body, the baffle is installed between the inner walls of the two sides of each first cavity, the mounting plate is arranged in each first cavity at the bottom end of the baffle, and the top of graphite alkene board has seted up the standing groove, the inside of standing groove is provided with the cable conductor, and the both sides of cable conductor all extend to the both sides of main part, the hole groove has evenly been seted up on the top of graphite alkene board.

Preferably, the mounting plate outer wall of baffle bottom all overlaps and is equipped with the installation spring, and the top and the bottom of installation spring respectively with baffle and first cavity welding.

Preferably, the heat conduction structure includes first heat-conducting plate, heat conduction seat, second heat-conducting plate, third heat-conducting plate and fourth heat-conducting plate, the heat conduction seat sets up in the central position department of the inside bottom of main part, and the inside bottom of main part of heat conduction seat one side installs the third heat-conducting plate, one side that the heat conduction seat was kept away from to the third heat-conducting plate extends to one side of main part, the second heat-conducting plate is installed to the inside bottom of main part of heat conduction seat one end, and the one end that the heat conduction seat was kept away from to the second heat-conducting plate extends to.

Preferably, the heat conducting seat is far away from the inside bottom of main part of third heat-conducting plate one side and is installed first heat-conducting plate, the heat conducting seat is far away from the inside bottom of main part of second heat-conducting plate one end and is installed the fourth heat-conducting plate.

Preferably, the top end of the mounting plate extends to the upper side of the main body, and one side of the bottom end of the mounting plate extends to the inside of the hole groove.

Preferably, the second cavities are connected to the movable plate through the sliding blocks, and the movable plate and the second cavities form a sliding structure through the sliding blocks.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) by arranging the mounting plate, the first cavity, the hole groove and the graphene plate, a worker pulls the mounting plate, so that the mounting plate moves upwards to a limit position, the mounting plate extends inside the first cavity, the mounting spring deforms under the obstruction of the baffle plate, the graphene plate is mounted at the top end of the movable plate inside the main body, the mounting plate is loosened, under the reaction force of the mounting spring, the mounting plate can be automatically inserted into the hole groove, the graphene plate is quickly fixed, then a cable is mounted inside the placing groove at the top end of the graphene plate, the mounting can be completed, otherwise, the mounting plate can be quickly dismounted, and the structure realizes the function of quickly dismounting and mounting the device;

(2) by arranging the heat conducting seat, the first heat conducting plate, the second heat conducting plate, the third heat conducting plate and the fourth heat conducting plate, when the device is heated, redundant heat is absorbed by the heat conducting seat, and then the first heat conducting plate, the second heat conducting plate, the third heat conducting plate and the fourth heat conducting plate conduct, so that energy is transferred among the main bodies, the heat is recycled, and the energy utilization rate of the device is improved by the structure;

(3) through being provided with graphite alkene board, the fly leaf, slider and second cavity, when the device received external force, graphite alkene board took place the activity to make the fly leaf activity, the fly leaf removes, make the slider slide in the second cavity is inside, can prevent that the fly leaf from taking place the skew, connecting rod extrusion buffer spring on the auxiliary rod simultaneously, make buffer spring and auxiliary spring take place deformation simultaneously, the increase buffering can effectively weaken the influence of pressure to the device, thereby protection device, this structure has realized the safeguard function to the device.

Drawings

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

fig. 2 is a schematic top view of the present invention;

FIG. 3 is a schematic side view of the main body of the present invention;

fig. 4 is a schematic top view of the heat conducting structure of the present invention.

In the figure: 1. installing a spring; 2. a connecting rod; 3. a buffer spring; 4. an auxiliary lever; 5. a movable plate; 6. a first cavity; 7. a baffle plate; 8. a cable wire; 9. a heat conducting structure; 901. a first heat-conducting plate; 902. a heat conducting base; 903. a second heat-conducting plate; 904. a third heat-conducting plate; 905. a fourth heat-conducting plate; 10. mounting a plate; 11. a hole groove; 12. a graphene plate; 13. a placement groove; 14. a main body; 15. a second cavity; 16. an auxiliary spring; 17. a slide block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a safe spliced graphene electric floor heating device comprises a baffle 7, a mounting plate 10 and a main body 14, wherein a heat conducting structure 9 is mounted in the middle of the bottom end inside the main body 14;

the heat conducting structure 9 comprises a first heat conducting plate 901, a heat conducting seat 902, a second heat conducting plate 903, a third heat conducting plate 904 and a fourth heat conducting plate 905, wherein the heat conducting seat 902 is arranged at the central position of the bottom end in the main body 14, the third heat conducting plate 904 is arranged at the bottom end in the main body 14 on one side of the heat conducting seat 902, one side of the third heat conducting plate 904, which is far away from the heat conducting seat 902, extends to one side of the main body 14, the second heat conducting plate 903 is arranged at the bottom end in the main body 14 on one end of the heat conducting seat 902, and one end of the second heat conducting plate 903;

specifically, as shown in fig. 1, 2, 3 and 4, when the device is used, when the device is heated, the excess heat is absorbed by the heat-conducting base 902, and then conducted through the first heat-conducting plate 901, the second heat-conducting plate 903, the third heat-conducting plate 904 and the fourth heat-conducting plate 905, so that energy is transferred between the main bodies 14, and the heat is reused;

the bottom end of the interior of the main body 14, at the side of the heat conducting seat 902 far away from the third heat conducting plate 904, is provided with a first heat conducting plate 901, and the bottom end of the interior of the main body 14, at the side of the heat conducting seat 902 far away from the second heat conducting plate 903, is provided with a fourth heat conducting plate 905;

specifically, as shown in fig. 1, 2, 3 and 4, when the mechanism is used, the second heat conduction plate 903 and the third heat conduction plate 904 extend into the other main body 14, so that the second heat conduction plate 903 is connected with the first heat conduction plate 901, and the third heat conduction plate 904 is connected with the fourth heat conduction plate 905, and the splicing work among the main bodies 14 can be completed;

two auxiliary rods 4 are arranged on two sides of the bottom end inside the main body 14, a buffer spring 3 is sleeved on one side of the outer wall of each auxiliary rod 4, a connecting rod 2 is mounted at the top end of each auxiliary rod 4 on one side through an articulated piece, a movable plate 5 is mounted at the top end of each connecting rod 2 through an articulated piece, two second cavities 15 are formed in the two sides of the main body 14, auxiliary springs 16 are arranged at the bottom ends inside the second cavities 15, and sliding blocks 17 are connected to the top ends of the auxiliary springs 16;

the second cavities 15 are connected to the movable plate 5 through the sliding blocks 17, and the movable plate 5 and the second cavities 15 form a sliding structure through the sliding blocks 17;

specifically, as shown in fig. 3, when the mechanism is used, the movable plate 5 moves, so that the slider 17 slides inside the second cavity 15, preventing the movable plate 5 from shifting;

the middle positions of the interior of the four side edges of the main body 14 are all provided with first cavities 6, baffles 7 are arranged between the inner walls of the two sides of the first cavities 6, and mounting plates 10 are arranged in the first cavities 6 at the bottom ends of the baffles 7;

the outer walls of the mounting plates 10 at the bottom ends of the baffles 7 are sleeved with mounting springs 1, and the top ends and the bottom ends of the mounting springs 1 are respectively welded with the baffles 7 and the first cavities 6;

specifically, as shown in fig. 1 and 3, when the mechanism is used, the mounting plate 10 is pulled, so that the mounting plate 10 moves upwards to the limit position, the mounting plate 10 extends inside the first cavity 6, the mounting spring 1 deforms under the obstruction of the baffle 7, the graphene plate 12 is mounted at the top end of the movable plate 5 inside the main body 14, the mounting plate 10 is released, and the mounting plate 10 can be automatically inserted into the hole groove 11 under the reaction force of the mounting spring 1;

a graphene plate 12 is mounted inside a main body 14 at the top end of the movable plate 5, a placing groove 13 is formed in the top end of the graphene plate 12, a cable 8 is arranged inside the placing groove 13, two sides of the cable 8 extend to two sides of the main body 14, and hole grooves 11 are uniformly formed in the top end of the graphene plate 12;

the top ends of the mounting plates 10 extend to the upper side of the main body 14, and one sides of the bottom ends of the mounting plates 10 extend to the inner parts of the hole grooves 11;

specifically, as shown in fig. 1, 2 and 3, when the mechanism is used, the mounting plate 10 is inserted into the hole slot 11, so that the graphene plate 12 can be quickly fixed;

the working principle is as follows: when using this device, at first, install the device, pulling mounting panel 10, make mounting panel 10 rebound extreme position, mounting panel 10 extends in first cavity 6 is inside, under the separation of baffle 7, deformation takes place for installation spring 1, install graphite alkene board 12 on the inside fly leaf 5 top of main part 14 again, loosen mounting panel 10, under installation spring 1's reaction force, mounting panel 10 can insert in the middle of the hole groove 11 automatically, carry out quick fixed to graphite alkene board 12, install inside the standing groove 13 on graphite alkene board 12 top with cable conductor 8 again after that, can accomplish the installation, otherwise can dismantle fast.

Afterwards, each main body 14 is spliced, the main body extends into another main body 14 through the second heat conduction plate 903 and the third heat conduction plate 904, so that the second heat conduction plate 903 and the first heat conduction plate 901 are connected, the third heat conduction plate 904 and the fourth heat conduction plate 905 are connected, the splicing work among the main bodies 14 can be completed, when the device is heated, redundant heat is absorbed by the heat conduction seat 902, and then the first heat conduction plate 901, the second heat conduction plate 903, the third heat conduction plate 904 and the fourth heat conduction plate 905 conduct, so that the energy is transferred among the main bodies 14, and the heat is reused.

Finally, when the device receives external force, graphite alkene board 12 takes place the activity to make fly leaf 5 activity, fly leaf 5 removes, makes slider 17 slide in second cavity 15 is inside, can prevent fly leaf 5 from taking place the skew, connecting rod 2 extrudees buffer spring 3 on the auxiliary rod 4 simultaneously, makes buffer spring 3 and auxiliary spring 16 take place deformation simultaneously, and the increase buffering can effectively weaken the influence of pressure to the device, thereby protection device.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides a graphite alkene electricity of safe type concatenation formula warms up, includes baffle (7), mounting panel (10) and main part (14), its characterized in that: the heat conduction structure (9) is installed at the middle position of the inner bottom end of the main body (14), two auxiliary rods (4) are arranged on two sides of the inner bottom end of the main body (14), the buffer springs (3) are sleeved on one sides of the outer walls of the auxiliary rods (4), the connecting rods (2) are installed at the top ends of the auxiliary rods (4) on one sides through hinge parts, the movable plate (5) is installed at the top end of the connecting rod (2) through the hinge parts, two second cavities (15) are formed in the inner parts of two sides of the main body (14), the auxiliary springs (16) are arranged at the bottom ends of the inner parts of the second cavities (15), the sliding blocks (17) are connected to the top ends of the auxiliary springs (16), the first cavities (6) are formed in the middle positions of the inner parts of four sides of the main body (14), and the baffle plates (7), the utility model discloses a portable electronic device, including baffle (7), main part (14) internally mounted on fly leaf (5) top has graphite alkene board (12), and standing groove (13) have been seted up on the top of graphite alkene board (12), the inside of standing groove (13) is provided with cable conductor (8), and the both sides of cable conductor (8) all extend to the both sides of main part (14), hole groove (11) have evenly been seted up on the top of graphite alkene board (12).

2. The safe spliced graphene electric floor heating system according to claim 1, characterized in that: the mounting plate (10) outer wall of baffle (7) bottom all overlaps and is equipped with installation spring (1), and the top and the bottom of installation spring (1) weld with baffle (7) and first cavity (6) respectively.

3. The safe spliced graphene electric floor heating system according to claim 1, characterized in that: heat conduction structure (9) include first heat-conducting plate (901), heat-conducting seat (902), second heat-conducting plate (903), third heat-conducting plate (904) and fourth heat-conducting plate (905), heat-conducting seat (902) set up in the central point department of the inside bottom of main part (14), and the inside bottom of main part (14) of heat-conducting seat (902) one side installs third heat-conducting plate (904), one side that heat-conducting seat (902) were kept away from in third heat-conducting plate (904) extends to one side of main part (14), second heat-conducting plate (903) are installed to the inside bottom of main part (14) of heat-conducting seat (902) one end, and the one end that heat-conducting seat (902) was kept away from in second heat-conducting plate (903) extends to the one end of main.

4. The safe spliced graphene electric floor heating system according to claim 3, characterized in that: the heat conduction seat (902) is far away from the inside bottom of main part (14) on one side of third heat-conducting plate (904) and is installed first heat-conducting plate (901), the heat conduction seat (902) is far away from the inside bottom of main part (14) of second heat-conducting plate (903) one end and is installed fourth heat-conducting plate (905).

5. The safe spliced graphene electric floor heating system according to claim 1, characterized in that: the top of mounting panel (10) all extends to the top of main part (14), and the inside of mounting panel (10) bottom all extends to hole groove (11).

6. The safe spliced graphene electric floor heating system according to claim 1, characterized in that: the second cavities (15) are connected to the movable plate (5) through the sliding blocks (17), and the movable plate (5) and the second cavities (15) form a sliding structure through the sliding blocks (17).

Images