CN212137945U - Graphite alkene micrite device that generates heat - Google Patents

Abstract

The utility model relates to a firing equipment technical field discloses a graphite alkene micrite device that generates heat for solve current hot plate calorific loss big, the inhomogeneous problem that generates heat, specifically include: the microcrystalline heating plate, microcrystalline heating plate coats and is stamped graphite alkene heating coating, the even interval distribution of upper surface of microcrystalline heating plate has a plurality of bumps, a plurality of bumps with microcrystalline heating plate integrated into one piece.

Description

Graphite alkene micrite device that generates heat

Technical Field

The utility model relates to a firing equipment technical field especially relates to a graphite alkene micrite device that generates heat.

Background

At present, the current container class liquid heating product in the market, like electric kettle, health preserving kettle, electric saucepan etc. adopt traditional heating tube to carry out electrical heating more, the heating tube setting is on stainless steel heating plate, generally uses the brazed dish that generates heat of U type heating tube to heat, has following shortcoming:

1. the heating wire for heating can not be directly covered on the heating plate, so the heating wire is arranged in the heating tube, but the insulating filler of the heating tube causes high loss rate of the heat of the heating wire in the conduction process.

2. After the U-shaped brazing position is heated, local high temperature is generated at the position of the surface of the heating plate which is stained with water, so that the stainless steel material of the heating plate is yellowed and scales are accumulated, and the service life of the heating plate is influenced.

3. The heating plate is made of stainless steel, and in the using process, due to the long-term high temperature of the stainless steel, the heating plate is easy to separate out metal substances into heated food materials, so that the health of a human body is affected.

4. The existing heating plate brazed by the U-shaped heating tube generates heat unevenly, local high temperature is easy to occur, the heated food materials are possibly coked or carbonized, and the food materials are damaged or the nutritional ingredients of the food materials are damaged.

SUMMERY OF THE UTILITY MODEL

In order to overcome prior art's not enough, one of the purposes of the utility model provides a graphite alkene micrite device that generates heat reduces the heat loss, and it is even to generate heat, can avoid the local high temperature of board that generates heat.

The utility model discloses an one of the purpose adopts following technical scheme to realize:

the utility model provides a graphite alkene micrite device that generates heat, includes the micrite hot plate, micrite hot plate coats and is stamped graphite alkene coating that generates heat, the even interval distribution of upper surface of micrite hot plate has a plurality of bumps, a plurality of bumps with micrite hot plate integrated into one piece.

Further, the graphene heating coating is connected with a live wire connection point and a zero line connection point which are not in contact with each other.

Furthermore, the live wire connection point and the zero wire connection point are covered with insulating protective layers.

Further, the microcrystalline heating plate is a microcrystalline glass panel.

Further, the microcrystalline heating plate is circular.

Further, the microcrystal heating plate is oval or triangular or polygonal.

Further, the lower surface of micrite hot plate is equipped with the coating of protecting against radiation layer.

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

1. the graphene heating coating is covered on the microcrystal heating plate, so that the heating bodies are uniformly distributed, and local high temperature is avoided.

2. The graphene heating coating has a good heat conduction effect, can be directly covered on a heating plate, reduces heat conduction links, improves heat energy conversion efficiency, and reduces heat loss.

3. The microcrystal heating plate has stable physical performance, does not generate harmful substances in the heating process, and ensures the edible safety of the heated plate.

4. The microcrystal generates heat and is provided with a plurality of bumps in the evenly distributed way on the board, has increased the surface area that the microcrystal generates heat the board to can be heated the object and generate heat the area of contact between the board, make to be heated the object and be heated more fully.

Drawings

Fig. 1 is a schematic structural diagram of a graphene microcrystalline heating device.

The reference numerals in the figures include: the micro-crystal heating plate comprises a micro-crystal heating plate 1, a graphene heating coating 2, salient points 3, a live wire connection point 4 and a zero line connection point 5.

Detailed Description

The present invention will now be described in more detail with reference to the accompanying drawings, and it is to be understood that the following description of the present invention is made only by way of illustration and not by way of limitation with reference to the accompanying drawings. The various embodiments may be combined with each other to form other embodiments not shown in the following description.

Example 1

The embodiment provides a graphite alkene micrite device that generates heat, aims at reducing heat loss, and the board that generates heat is even, can avoid generating heat the local high temperature of board, and can increase the heated area of being heated the thing.

The utility model provides a graphite alkene micrite device that generates heat, includes micrite hot plate 1, micrite hot plate physical properties is stable, can not produce harmful substance in the heating process, can guarantee the food safety after the heating. The microcrystalline heating plate 1 is covered with the graphene heating coating 2, so that the uniform distribution of the heating body is realized, the heat is uniformly distributed, and the local high temperature is avoided. And the heat conduction effect of graphene is good, and the graphene can be directly covered on the microcrystalline heating plate, so that the heat conduction link is reduced, and the heat loss is reduced.

The upper surface evenly distributed of micrite hot plate 1 has a plurality of bumps 3, and the interval of these a plurality of bumps 3 sets up, and these a plurality of bumps 3 and 1 integrated into one piece of micrite hot plate, this bump 3 is circular bump in this embodiment, through evenly setting up the bump on the micrite panel, has increased the surface area of the board that generates heat to can increase by heating the thing (especially liquid) and generate heat the area of contact between the board, make to be heated more fully.

Preferably, the both ends of graphite alkene coating 2 that generate heat are connected with live wire binding post 4 and zero line binding post 5, and live wire binding post 4 and zero line binding post 5 contactless each other for with graphite alkene micrite device access commercial power that generates heat, realize electrical heating.

In this embodiment, the micrite generates heat board 1 and is the microcrystalline glass board, and physical properties is stable, can not yellow or accumulate the incrustation scale, and the micrite generates heat board 1 and is circular, can install in container class liquid heating products such as current electric kettle, health preserving kettle, electric saucepan on the market for the realization is to the heating of liquid, makes the heating heat distribute evenly, and the liquid in the container is big with the area of contact who generates heat board, makes to be heated more fully.

The graphene microcrystalline heating device in the embodiment can be applied to a heating lunch box and used for heating meals.

Preferably, the micro crystal heating plate 1 may be in an oval shape or a triangular shape or a polygonal shape in other embodiments, and the shape of the micro crystal heating plate 1 is not limited to the specific shape.

Similarly, the properties and the use effect of the graphene heating coating are not affected by the different shapes of the graphene heating coating, and are not particularly limited herein.

Example 2

The present embodiment is different from the above embodiments in that the live wire terminal 4 and the neutral wire terminal 5 are covered with an insulating protective layer to prevent a user from touching the terminals and from getting an electric shock, and the insulating protective layer may be a structure made of an insulating material, such as a plate or a housing.

Preferably, the lower surface of micrite hot plate 1 is equipped with the radiation protection dope layer, and when micrite hot plate 1 circular telegram heating, can be through the isolated thermal radiation of this radiation protection dope layer.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (7)

1. The utility model provides a graphite alkene micrite device that generates heat, includes the micrite hot plate, its characterized in that, micrite hot plate coats and is stamped graphite alkene coating that generates heat, the even interval distribution of upper surface of micrite hot plate has a plurality of bumps, a plurality of bumps with micrite hot plate integrated into one piece.

2. The graphene microcrystalline heating device according to claim 1, wherein the graphene heating coating is connected with a live wire connection point and a zero wire connection point which are not in contact with each other.

3. The graphene microcrystalline heating device according to claim 2, wherein the live wire connection point and the zero wire connection point are covered with an insulating protection layer.

4. The graphene microcrystalline heat generating device according to claim 1, wherein the microcrystalline heating plate is a microcrystalline glass panel.

5. The graphene microcrystalline heat generating device according to claim 1, wherein the microcrystalline heating plate is circular.

6. The graphene microcrystalline heat generating device according to claim 1, wherein the microcrystalline heating plate is oval or triangular or polygonal.

7. The graphene microcrystalline heating device according to claim 1, wherein a radiation-proof coating layer is arranged on the lower surface of the microcrystalline heating plate.

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