CN220489224U - Electric stove heating structure - Google Patents

Abstract

The utility model relates to an electric furnace heating structure, which comprises a furnace body and a connecting bracket, wherein a coil assembly is fixed at the bottom of the connecting bracket, a bearing part is arranged at the outer side of the connecting bracket, and a magnetic conduction heating plate is fixedly supported by the bearing part; the connecting support, the bearing part and the magnetic conduction heating plate form a cavity with constant vertical distance, and the magnetic conduction heating plate and the coil assembly form a magnetic induction interval with constant vertical distance, so that the coil assembly, the connecting support and the magnetic conduction heating plate are packaged into a heating module. The modularized arrangement of the heating module can reduce the number of components, reduce the production cost, and can be integrally assembled on the furnace body, the assembly process is simple, the production efficiency is high, the maintenance is convenient, the vertical distance among the connecting support, the bearing part and the magnetic conduction heating plate is constant, the magnetic induction distance with constant vertical distance is also formed between the magnetic conduction heating plate and the coil assembly, the magnetic field stability of the coil assembly acting on the magnetic heating plate is improved, the heating effect of the electric furnace is ensured, the effective heat transfer is ensured, and the loss is reduced.

Description

Electric stove heating structure

Technical Field

The utility model relates to an electric furnace heating structure.

Background

The Chinese patent document No. CN2789641Y discloses an electromagnetic oven heat conduction device in 6/21/2006, which is arranged on an electromagnetic oven and comprises a main heating plate and a heat conduction plate, wherein the main heating plate is a ferromagnetic metal plate arranged above the electromagnetic oven; the heat conducting plate is made of a good heat conductor and is attached to the top surface of the main heating plate. The heat conduction device of the induction cooker further comprises a secondary heating plate attached to the top surface of the heat conduction plate and a heat insulation cushion attached to the bottom surface of the primary heating plate. The electromagnetic oven heat conduction device is said to heat the ferromagnetic metal cookware directly by the current electromagnetic oven, and changes the electromagnetic oven into the electromagnetic oven to heat the heat conduction plate through the main heat generation plate and the auxiliary heat generation plate, and then heat the cookware placed on the heat conduction plate by the heat conduction plate, so that cookware made of various materials can be used, and the defect that the current electromagnetic oven must use the ferromagnetic metal cookware is overcome.

However, the following drawbacks also exist:

(1) The induction cooker has the advantages that the production cost of the induction cooker is high due to more integral components, meanwhile, the heat insulation shell, the heat conduction disc, the main heating plate, the auxiliary heating plate and the heat insulation cushion layer are all independent parts, and the components are required to be assembled one by one during production and assembly, so that the production efficiency is low;

(2) When individual components are damaged, the components are required to be disassembled one by one to finish maintenance, so that daily maintenance is not facilitated;

(3) In addition, the products are more in components during production and assembly, and the assembly errors among the components are larger, so that the distance between the induction cooker coil and the main heating plate and the auxiliary heating plate cannot be constant, the stability of the magnetic field of the induction cooker coil acting on the main heating plate and the auxiliary heating plate is reduced, and the stability of the induction cooker during heating operation is directly influenced.

(4) The heat conducting disc and the base plate reserved in the technical scheme have the functions of heat insulation and bearing, but have no function of heat transfer, so that heat of the main heating plate can be transferred to the auxiliary heating plate only by penetrating through the base plate, and the heat efficiency of a product is greatly reduced.

Therefore, further improvements are needed.

Disclosure of Invention

The utility model aims to provide an electric furnace heating structure which overcomes the defects in the prior art.

The electric furnace heating structure designed according to the purpose comprises a furnace body and a connecting support, wherein a coil assembly is fixedly arranged at the bottom of the connecting support, a bearing part is arranged at the outer side of the connecting support, and a magnetic conduction heating plate is fixedly supported by the bearing part.

The connecting support, the bearing part and the magnetic conduction heating plate form a cavity with constant vertical distance, and a magnetic induction distance with constant vertical distance is formed between the magnetic conduction heating plate and the coil assembly, so that the coil assembly, the connecting support and the magnetic conduction heating plate are packaged into a heating module.

The magnetic conduction heating plate and the connecting support or the bearing part are fixedly connected with each other through welding, pasting, buckling or fastening pieces.

The outer side of the connecting bracket is provided with a surrounding edge, and an opening is formed at the upper end of the surrounding edge; the bearing part is concavely arranged at the top of the surrounding edge; the periphery of the magnetic conduction heating plate horizontally extends to form a side wing.

The magnetic conduction heating plate cover is arranged on the opening and is supported on the bearing part through the side wing; the side wings and the bearing parts are fixedly connected with each other through welding, pasting, buckling or fastening pieces.

The bearing part is provided with a clamping part; the side wings are provided with snap fit parts which are in snap fit with the snap fit parts.

The side wings are also provided with heat insulation sheets; the heat insulation sheet is provided with a positioning part and an avoiding part; the heat insulation sheet is positioned on the side wing through a positioning part; the buckling part penetrates through the avoiding part and the buckling matching part and then is buckled on the heat insulation sheet.

And a heat insulation piece or an air guide and heat dissipation channel is arranged in the cavity.

And a temperature sensing device is arranged in the projection area or outside the projection area of the connecting bracket.

The heat insulation piece is arranged in the cavity, and the assembly part is arranged at the bottom of the cavity; and the heat insulation piece is provided with a via hole, and the via hole is arranged corresponding to the assembly part.

The temperature sensing device is arranged on the assembly part, and the detection end of the temperature sensing device passes through the through hole and then is mutually dependent or clearance fit with the bottom of the magnetic conduction heating plate.

Or, the magnetic conduction heating plate is provided with a through hole; the temperature sensing device is arranged on the assembly part, and the detection end of the temperature sensing device passes through the through hole and then is positioned on the through hole, wherein the detection end of the temperature sensing device is higher than, lower than or flush with the surface of the magnetic conduction heating plate.

The coil assembly comprises a coil and a magnetic stripe; the coil is arranged at the bottom of the connecting bracket; the magnetic stripe is positioned at the bottom of the coil and is fixedly connected with the connecting bracket through adhesion, buckling or fastening pieces so as to realize the fixed connection between the coil, the magnetic stripe and the connecting bracket.

The furnace body comprises a surface shell and a base.

The face shell and the base are fixedly connected with each other through welding, pasting, buckling or fastening pieces, and an assembly cavity is formed between the face shell and the base; the heating module is arranged in the assembly cavity and is fixedly connected with the surface shell and/or the base through welding, pasting, buckling or fastening pieces.

A notch is formed in the face shell; the surface of the magnetic conduction heating plate is at least partially exposed out of the notch.

The face shell bottom is provided with the draw-in groove, and is provided with the sealing member through the draw-in groove.

The bottom of the face shell is also provided with a face shell fixing part; a boss is arranged at the top of the magnetic conduction heating plate; the bearing part is also provided with a second fixing part of the connecting bracket.

The face shell is in sealing action on the boss through the sealing piece and is fixed on the second fixing part of the connecting bracket through the face shell fixing part.

The furnace body is also provided with a temperature detection device, the temperature detection end of the temperature detection device is positioned on the connecting support and detects the temperature on the connecting support, or the temperature detection end of the temperature detection device is positioned between the connecting support and the magnetic conduction heating plate and detects the temperature between the connecting support and the magnetic conduction heating plate.

According to the utility model, through the improvement of the structure, the coil assembly, the connecting support and the magnetic conduction heating plate are mutually assembled and packaged into the heating module, so that the number of components is reduced when the electric furnace is integrally installed, the production cost is reduced, the packaged heating module can be integrally assembled on the furnace body, the assembly process is simple, the production efficiency is high, if the heating module is damaged, the whole maintenance can be performed, the after-sales maintenance pressure is reduced, the upper and lower distances among the connecting support, the bearing part and the magnetic conduction heating plate are constant, the magnetic induction distance between the magnetic conduction heating plate and the coil assembly is also constant, and the characteristics can improve the magnetic field stability of the coil assembly acting on the magnetic heating plate during operation, ensure the heating effect of the electric furnace and simultaneously reduce the energy loss.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model.

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of an assembly structure of a first embodiment of the present utility model.

Fig. 2 is an exploded view of the first embodiment of the present utility model.

Fig. 3 is a schematic view of another exploded view of the first embodiment of the present utility model.

Fig. 4 is a schematic view showing an assembled sectional structure of a first embodiment of the present utility model.

Fig. 5 is an exploded view of a heating module according to a first embodiment of the present utility model.

Fig. 6 is an exploded view of a heating module according to another embodiment of the present utility model.

Fig. 7 is an enlarged schematic view of the structure at a in fig. 4.

Fig. 8 is an exploded view of a heating module according to a second embodiment of the present utility model.

Fig. 9 is an exploded view of a heating module according to a second embodiment of the present utility model.

Fig. 10 is a schematic view showing an assembled sectional structure of a heating module according to a second embodiment of the present utility model.

Fig. 11 is an enlarged schematic view of the structure at B in fig. 10.

Fig. 12 is an exploded view of a heating module according to a third embodiment of the present utility model.

Fig. 13 is an exploded view of a heating module according to a third embodiment of the present utility model.

Fig. 14 is a schematic view showing an assembled sectional structure of a heating module according to a third embodiment of the present utility model.

Fig. 15 is an enlarged schematic view of the structure at C in fig. 14.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. The present utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the utility model, whereby the utility model is not limited to the specific embodiments disclosed below.

The utility model is further described below with reference to the drawings and examples.

First embodiment

Referring to fig. 1-7, the electric furnace heating structure comprises a furnace body and a connecting bracket 3, wherein a coil assembly is fixedly arranged at the bottom of the connecting bracket 3, a bearing part 9 is arranged at the outer side of the connecting bracket, and a magnetic conduction heating plate 4 is fixedly supported by the bearing part 9.

The connecting bracket 3, the bearing part 9 and the magnetic conduction heating plate 4 form a cavity with constant vertical distance, and the magnetic conduction heating plate 4 and the coil assembly form a magnetic induction interval with constant vertical distance, so that the bearing part heating module among the coil assembly, the connecting bracket 3 and the magnetic conduction heating plate 4.

The coil assembly, the connecting support 3 and the magnetic conduction heating plate 4 are assembled with each other respectively and are packaged into the heating module, so that the number of components is reduced during integral installation of the electric furnace, the production cost is reduced, the packaged heating module can be integrally assembled on the furnace body, the assembly process is simple, the production efficiency is high, if the heating module is damaged, the integral maintenance can be performed, the after-sales maintenance pressure is reduced, the upper and lower distances among the connecting support 3, the bearing part 8 and the magnetic conduction heating plate 4 are constant, the magnetic induction distance between the magnetic conduction heating plate 4 and the coil assembly is also constant, and the magnetic induction distance between the magnetic conduction heating plate 4 and the coil assembly is also formed.

Wherein, the magnetic conduction heating plate 4 and the connecting bracket 3 or the bearing part 9 are fixedly connected with each other through welding, pasting, buckling or fastening pieces.

Specifically, the outer side of the connecting bracket 3 of the embodiment is provided with a surrounding edge 8, and the upper end of the surrounding edge 8 forms an opening; the bearing part 9 is concavely arranged at the top of the surrounding edge 8; the periphery of the magnetic conduction heating plate 4 horizontally extends to form a side wing 10.

The magnetic conduction heating plate 4 is covered on the opening and is supported on the bearing part 9 through the side wings 10; the side wings 10 and the receiving part 9 are fixedly connected with each other by welding or pasting.

The inside of the cavity is provided with a heat insulation piece 5 or an air guide heat dissipation channel.

The heat insulation member 5 can be arranged to partially insulate the heat inside the cavity; the arrangement of the air guide heat dissipation channel can dissipate heat in the cavity.

A temperature sensing device 6 is arranged in the projection area of the connecting bracket 3 or outside the projection area.

Specifically, the inside of the cavity is provided with a heat insulating piece 5, and the bottom is provided with an assembling part 7; the heat insulator 5 is provided with a via hole 30, and the via hole 30 is provided corresponding to the mounting portion 7.

The temperature sensing device 6 is arranged on the assembly part 7, and the detection end of the temperature sensing device passes through the through hole 30 and then is mutually dependent or clearance fit with the bottom of the magnetic conduction heating plate 4.

That is, the temperature sensing device 6 is disposed in the projection area of the connection bracket 3, and at the same time, the detection end of the temperature sensing device 6 and the magnetically conductive heating plate 4 depend on each other to accurately detect the temperature of the magnetically conductive heating plate 4.

Besides, a through hole is arranged on the magnetic conduction heating plate 4; the temperature sensing device 6 is arranged on the assembly part 7, and the detection end of the temperature sensing device 6 passes through the through hole 30 and then is positioned on the through hole, wherein the detection end of the temperature sensing device 6 is higher than, lower than or flush with the surface of the magnetic conduction heating plate 4.

That is, the temperature sensing device 6 is disposed in the projection area of the connection bracket 3, and at the same time, the detection end of the temperature sensing device 6 is exposed to the via hole 30 and the through hole, which can detect the temperature of the magnetically conductive heating plate 4 and the pot body placed on the magnetically conductive heating plate 4.

The coil component comprises a coil 1 and a magnetic stripe 2; the coil 1 is arranged at the bottom of the connecting bracket 3; the magnetic stripe 2 is positioned at the bottom of the coil 1 and is fixedly connected with the connecting bracket 3 through adhesion, buckling or fastening pieces so as to realize the fixed connection among the coil 1, the magnetic stripe 2 and the connecting bracket 3.

Specifically, the coil 1 is fixedly wound on a coil groove at the bottom of the connecting support 3, or the coil 1 is fixedly wound on an intermediate piece, and then the intermediate piece is fixed at the bottom of the connecting support 3, the magnetic strip 2 is positioned at the bottom of the coil 1 and is provided with a plurality of assembly parts 18, the assembly parts 18 are provided with assembly holes 19, the bottom of the connecting support 3 is provided with a hole boss 17 corresponding to the assembly holes 19, and the assembly holes 19 and the hole boss 17 are fixed through fasteners, so that the coil 1, the magnetic strip 2 and the connecting support 3 are fixed.

The furnace body comprises a face shell 20 and a base 21.

The face shell 20 and the base 21 are fixedly connected with each other through welding, pasting, buckling or fastening pieces, and an assembly cavity is formed between the face shell and the base; the heating module is disposed in the assembly cavity and is fixedly connected with the face shell 20 and/or the base 21 by welding, pasting, buckling or fastening.

Specifically, the face shell 20 is provided with a notch 23; the surface of the magnetically permeable heating plate 4 is at least partially exposed to the notch 23.

The bottom of the face shell 20 is provided with a clamping groove 24, and a sealing member 27 is arranged through the clamping groove 24.

The bottom of the face shell 20 is also provided with a face shell fixing part 25; a boss 22 is arranged at the top of the magnetic conduction heating plate 4; the receiving portion 9 is further provided with a connection bracket second fixing portion 26.

The face-piece 20 acts on the boss 22 in a sealing manner by means of a sealing element 27 and is fixed to the connecting-bracket second fixing portion 26 by means of a face-piece fixing portion 25.

In order to detect the temperature on the connecting bracket 3 or the temperature between the connecting bracket 3 and the magnetic conduction heating plate 4, a temperature detecting device is also arranged on the furnace body; the temperature detection end of the temperature detection device is positioned on the connecting support 3 and detects the temperature on the connecting support 3, or the temperature detection end of the temperature detection device is positioned between the connecting support 3 and the magnetic conduction heating plate 4 and detects the temperature between the connecting support 3 and the magnetic conduction heating plate 4.

Second embodiment

Referring to fig. 8 to 11, the present electric furnace heating structure is different from the first embodiment in that: the side wings 10 and the bearing parts 9 are fixedly connected with each other through buckles.

Specifically, the receiving portion 9 is provided with a catching portion 11; the side wing 10 is provided with a snap-fit portion 12, and is snap-fitted with the snap-fit portion 11 through the snap-fit portion 12.

Other undescribed portions are the same as the first embodiment.

Third embodiment

Referring to fig. 12 to 15, the present electric furnace heating structure is different from the first embodiment in that: the side wings 10 and the bearing parts 9 are fixedly connected with each other through buckles.

Specifically, the receiving portion 9 is provided with a catching portion 11; the side wing 10 is provided with a snap-fit portion 12, and is snap-fitted with the snap-fit portion 11 through the snap-fit portion 12.

More specifically, the side wings 10 are further provided with heat insulating sheets 13; the heat insulating sheet 13 is provided with a positioning part 14 and an avoiding part 15; the heat insulating sheet 13 is positioned on the side wing 10 by the positioning portion 14; the fastening portion 11 is fastened to the heat insulating sheet 13 after passing through the escape portion 15 and the fastening mating portion 12.

Other undescribed portions are the same as the first embodiment.

The foregoing is a preferred embodiment of the utility model showing and describing the general principles, features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing embodiments and description merely illustrates the principles of the utility model, and that various changes and modifications may be effected therein without departing from the spirit and scope of the utility model as defined in the appended claims and their equivalents.

Claims (12)

1. The utility model provides an electric stove heating structure, includes furnace body, its characterized in that: the magnetic conduction heating device is characterized by further comprising a connecting bracket (3), wherein a coil assembly is fixedly arranged at the bottom of the connecting bracket (3), a bearing part (9) is arranged at the outer side of the connecting bracket, and a magnetic conduction heating plate (4) is fixedly supported by the bearing part (9);

the magnetic conduction heating device comprises a connecting support (3), a bearing part (9) and a magnetic conduction heating plate (4), wherein a cavity with a constant vertical distance is formed between the connecting support and the magnetic conduction heating plate, and a magnetic induction interval with a constant vertical distance is formed between the magnetic conduction heating plate (4) and the coil assembly so that the coil assembly, the connecting support (3) and the magnetic conduction heating plate (4) are packaged into a heating module.

2. The electric furnace heating structure according to claim 1, wherein: the magnetic conduction heating plate (4) is fixedly connected with the connecting bracket (3) or the bearing part (9) through welding, pasting, buckling or fastening pieces.

3. The electric furnace heating structure according to claim 1, wherein: a surrounding edge (8) is arranged on the outer side of the connecting bracket (3), and an opening is formed at the upper end of the surrounding edge (8); the bearing part (9) is concavely arranged at the top of the surrounding edge (8); the periphery of the magnetic conduction heating plate (4) horizontally extends to form a side wing (10);

the magnetic conduction heating plate (4) is arranged on the opening in a covering way and is supported on the supporting part (9) through the side wings (10); the side wings (10) and the bearing part (9) are fixedly connected with each other through welding, pasting, buckling or fastening pieces.

4. The electric furnace heating structure according to claim 3, wherein: a clamping part (11) is arranged on the bearing part (9); the side wing (10) is provided with a snap fit part (12), and is in snap fit with the snap fit part (11) through the snap fit part (12).

5. The electric furnace heating structure according to claim 4, wherein: the side wings (10) are also provided with heat insulation sheets (13); the heat insulation sheet (13) is provided with a positioning part (14) and an avoiding part (15); the heat insulation sheet (13) is positioned on the side wing (10) through a positioning part (14); the buckling part (11) penetrates through the avoidance part (15) and the buckling matching part (12) and then is buckled on the heat insulation sheet (13).

6. The electric furnace heating structure according to claim 1, wherein: the cavity is internally provided with a heat insulation piece (5) or an air guide and heat dissipation channel.

7. The electric furnace heating structure according to claim 1, wherein: a temperature sensing device (6) is arranged in the projection area or outside the projection area of the connecting bracket (3).

8. The electric furnace heating structure according to claim 7, wherein: the inside of the cavity is provided with a heat insulation piece (5), and the bottom of the cavity is provided with an assembly part (7); the heat insulation piece (5) is provided with a through hole (30), and the through hole (30) is arranged corresponding to the assembly part (7);

the temperature sensing device (6) is arranged on the assembly part (7), and the detection end of the temperature sensing device passes through the through hole (30) and then is mutually dependent on or in clearance fit with the bottom of the magnetic conduction heating plate (4);

or the magnetic conduction heating plate (4) is provided with a through hole; the temperature sensing device (6) is arranged on the assembly part (7), and the detection end of the temperature sensing device passes through the through hole (30) and then is positioned on the through hole, wherein the detection end of the temperature sensing device (6) is higher than, lower than or flush with the surface of the magnetic conduction heating plate (4).

9. The electric furnace heating structure according to claim 1, wherein: the coil assembly comprises a coil (1) and a magnetic strip (2); the coil (1) is arranged at the bottom of the connecting bracket (3); the magnetic stripe (2) is located at the bottom of the coil (1), and is fixedly connected with the connecting support (3) through adhesion, clamping or fastening pieces, so that the coil (1), the magnetic stripe (2) and the connecting support (3) are fixedly connected.

10. The electric furnace heating structure according to claim 1, wherein: the furnace body comprises a surface shell (20) and a base (21);

the face shell (20) and the base (21) are fixedly connected with each other through welding, pasting, buckling or fastening pieces, and an assembly cavity is formed between the face shell and the base; the heating module is arranged in the assembly cavity and is fixedly connected with the surface shell (20) and/or the base (21) through welding, pasting, buckling or fastening pieces.

11. The electric furnace heating structure according to claim 10, wherein: a notch (23) is arranged on the face shell (20); the surface of the magnetic conduction heating plate (4) is at least partially exposed out of the notch (23);

a clamping groove (24) is formed in the bottom of the face shell (20), and a sealing piece (27) is arranged through the clamping groove (24);

the bottom of the face shell (20) is also provided with a face shell fixing part (25); a boss (22) is arranged at the top of the magnetic conduction heating plate (4); the bearing part (9) is also provided with a second fixing part (26) of the connecting bracket;

the face shell (20) acts on the boss (22) in a sealing way through a sealing piece (27), and is fixed on the second fixing part (26) of the connecting bracket through a face shell fixing part (25).

12. The electric furnace heating structure according to claim 1, wherein: the furnace body is further provided with a temperature detection device, the temperature detection end of the temperature detection device is positioned on the connecting support (3) and detects the temperature on the connecting support (3), or the temperature detection end of the temperature detection device is positioned between the connecting support (3) and the magnetic conduction heating plate (4) and detects the temperature between the connecting support (3) and the magnetic conduction heating plate (4).