CN217877128U - Electric stove outer temperature detecting structure - Google Patents

Abstract

The utility model relates to an electric furnace external temperature detection structure, which comprises a heat generation module, a bearing plate, a temperature detector and a heated container; the heat generation module is arranged below the bearing plate; the heated container is placed above the bearing plate; the temperature detector is arranged below the bearing plate and positioned outside the heat generation module. This structure places thermodetector in the heat generation module outside to avoid the heat generation module to be in the interference to thermodetector at the during operation, arrange thermodetector's sense terminal in the container bottom projection region of being heated simultaneously, make thermodetector can detect the temperature of the container of being heated, can not cause the interference to thermodetector's work in order to ensure the heat generation module at the during operation, thereby improve thermodetector's temperature detection precision.

Description

Electric stove outer temperature detecting structure

Technical Field

The utility model relates to an electric stove technical field specifically is an electric stove is outer to be visited temperature structure.

Background

The electric stove heating working method of prior art divide into the thermal radiation heating of heat-generating body and electromagnetic heating, simultaneously, in order to realize better culinary art effect and guarantee safe in utilizationly, the electric stove need carry out temperature-detecting to the container that is heated at the during operation.

The principle of the heat radiation heating structure of the heating element is shown in fig. 5 and 6, the heating element 1 'is arranged below the bearing plate 2', the heating element is used for heating a heated container 4 'arranged above the bearing plate 2' by heat transfer during operation, and the temperature detector 3 'is arranged in the middle position between the heating element 1' and the bearing plate 2 '(shown in fig. 5) or in the middle position below the heating element 1' (shown in fig. 6). Since the heat of the heating element 1 'is radiated to the surroundings, the temperature detector 3' detects the temperature of the heating element 1 'and cannot detect the temperature of the heated container 4' in more cases when it is operated.

The principle of the electromagnetic heating structure is shown in fig. 7, the coil panel 5' is arranged below the bearing plate 2', when the electromagnetic heating structure works, the electromagnetic induction is used for heating the metal heated container 6' arranged above the bearing plate 2', and the temperature detector 3' passes through the middle positions of the coil panel 5' and the bearing plate 2' and then contacts with the bottom of the metal heated container 6', so that the temperature of the metal heated container 6' is detected. However, the electromagnetic field generated by the coil disk 5 'during operation affects the temperature detector 3', so that the temperature detector 3 'cannot accurately detect the temperature of the metal heat receiving container 6'.

Therefore, further improvements are necessary.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an electric stove is outer to visit temperature structure to overcome the weak point among the prior art.

According to the outer temperature detecting structure of electric stove of this purpose design, including heat generation module, bearing board, thermodetector, the container that is heated, its characterized in that:

the heat generation module is arranged below the bearing plate.

The heated container is placed above the bearing plate.

The temperature detector is arranged below the bearing plate and positioned outside the heat generation module.

The detection end of the temperature detector is positioned in the projection area of the bottom of the heated container.

The detection end of the temperature detector is attached to or matched with the bottom of the bearing plate at intervals.

The structure also comprises a furnace body; the bearing plate is fixedly arranged at the upper opening of the furnace body; the heat generation module and the temperature detector are respectively and fixedly arranged between the bearing plate and the furnace body.

The furnace body is provided with a bracket, the bracket is provided with an assembly part, and the assembly part is positioned outside the projection area of the heat generation module; the temperature detector is arranged in the assembling part, and the detection end of the temperature detector is attached to the bottom of the bearing plate.

The furnace body and the support are integrally formed, or the furnace body and the support are arranged in a split mode and fixed with each other.

A supporting part is arranged at the upper opening of the furnace body; the support is provided with a supporting matching part and is positioned and supported on the supporting part through the supporting matching part.

The furnace body is provided with a fixing part; the bracket is provided with a fixed matching part and is fixedly arranged on the fixed part through the fixed matching part.

The bearing plate is supported on the bearing matching part.

An assembly cavity is formed between the bearing plate and the furnace body; and a space is formed between the heat generation module and the temperature detector, and the heat generation module and the temperature detector are respectively and fixedly arranged in the assembly cavity.

The utility model discloses place thermodetector in the heat generation module outside to avoid the heat generation module to make thermodetector can detect the temperature of the container that is heated at the interference of during operation to thermodetector, in order to ensure that the heat generation module can not cause the interference to thermodetector's work at the during operation, thereby improve thermodetector's temperature detection precision.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention.

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

Fig. 1 is a schematic view of an assembly structure according to an embodiment of the present invention.

Fig. 2 is a schematic view of an assembly cross-sectional structure according to an embodiment of the present invention.

Fig. 3 and 4 are schematic exploded structural diagrams according to an embodiment of the present invention.

Fig. 5-7 are schematic structural diagrams of the prior art.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

The present invention will be further described with reference to the accompanying drawings and examples.

Referring to fig. 1-4, the external temperature detecting structure of the electric furnace comprises a heat generating module 1, a bearing plate 2, a temperature detector 3 and a heated container 4.

The heat generating module 1 is disposed below the carrier plate 2.

The heated vessel 4 is placed above the rest plate 2.

The temperature detector 3 is disposed below the receiving plate 2 and outside the heat generating module 1.

Wherein the number of the temperature detectors 3 is at least one.

This embodiment places thermodetector 3 in the heat generation module 1 outside to avoid heat generation module 1 to be at the interference to thermodetector 3 at the during operation, make thermodetector 3 can detect the temperature of being heated container 4, in order to ensure that heat generation module 1 can not cause the interference to thermodetector 3's work at the during operation, thereby improve thermodetector 3's temperature detection precision.

Specifically, the detection end of the temperature detector 3 is located within the bottom projected area of the heated container 4.

The detection end of the temperature detector 3 is attached to the bottom of the bearing plate 2 or matched with the bottom of the bearing plate at intervals, namely the temperature detector 3 is indirectly matched with the heated container 4, and the detection end of the temperature detector 3 can indirectly detect the temperature of the heated container 4 through the bearing plate 2.

The structure also comprises a furnace body 5; the bearing plate 2 is fixedly arranged at the upper opening of the furnace body 5; the heat generation module 1 and the temperature detector 3 are respectively and fixedly arranged between the bearing plate 2 and the furnace body 5.

The heat generating module 1 may be a heating coil that automatically generates heat after being powered on, or a coil that generates a magnetic field and realizes heating of the metal heated container 4 after being powered on.

Furthermore, an assembly cavity 12 is formed between the bearing plate 2 and the furnace body 5; a space is formed between the heat generating module 1 and the temperature detector 3, so that the influence of the heat generating module 1 on the temperature detector 3 during working is reduced, and meanwhile, the heat generating module 1 and the temperature detector 3 are respectively and fixedly arranged in the assembling cavity 12.

In order to improve the assembly stability of the temperature detector 3, the furnace body 5 is provided with a bracket 6, the bracket 6 is provided with an assembly part 7, and the assembly part 7 is positioned outside the projection area of the heat generation module 1, namely, the assembly part 7 can be positioned on the transverse periphery of the heat generation module 1, and besides, the assembly part 7 can also be positioned on the longitudinal periphery of the heat generation module 1; the temperature detector 3 is arranged in the assembling part 7, and the detection end of the temperature detector is abutted against the bottom of the bearing plate 2, so that the temperature of the heated container 4 can be transmitted to the bearing plate 2 and then is indirectly detected by the temperature detector 3. Since the receiving plate 2 can transmit the temperature of the heat receiving container 4, the temperature detected by the temperature detector 3 during operation can simulate the temperature of the heat receiving container 4.

Further, the furnace body 5 and the bracket 6 are integrally formed, or the furnace body 5 and the bracket 6 are separately arranged and fixed to each other.

In the present embodiment, the furnace body 5 and the support 6 are preferably provided separately.

Namely, a supporting part 8 is arranged at the upper opening of the furnace body 5; the bracket 6 is provided with a support matching part 9, and is positioned and supported on the support part 8 through the support matching part 9.

The supporting part 8 of the embodiment is annularly arranged along the edge of the upper opening of the furnace body 5, and the supporting matching part 9 is annularly arranged along the edge of the bracket 6, so when the supporting matching part 9 is positioned and supported on the supporting part 8, the positioning matching between the bracket 6 and the furnace body 5 can be realized, and meanwhile, the supporting plate 2 is also supported on the supporting matching part 9, thereby improving the support of the furnace body 5 to the supporting plate 2 and the bracket 6.

When the supporting matching part 9 is positioned and supported on the supporting part 8, a step is formed between the supporting matching part 9 and the upper opening of the furnace body 5, and the bearing plate 2 can be positioned through the step, so that the assembling stability of the bearing plate 2 is improved.

The furnace body 5 is provided with a fixed part 10; the bracket 6 is provided with a fixed matching part 11 and is fixedly arranged on the fixed part 10 through the fixed matching part 11. Wherein, the fixed matching part 11 and the fixed part 10 are fixed by screws.

The foregoing is a preferred embodiment of the present invention showing and describing the basic principles, main features and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are intended to illustrate the principles of the invention, but rather that various changes and modifications may be made without departing from the spirit and scope of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims (10)

1. The utility model provides an electric stove is structure of surveying temperature outward, includes heat generation module (1), holds and puts board (2), thermodetector (3), heated container (4), its characterized in that:

the heat generation module (1) is arranged below the bearing plate (2);

the heated container (4) is placed above the bearing plate (2);

the temperature detector (3) is arranged below the bearing plate (2) and is positioned outside the heat generation module (1).

2. The electric furnace external temperature detecting structure according to claim 1, wherein: the detection end of the temperature detector (3) is positioned in the bottom projection area of the heated container (4).

3. The electric furnace external temperature detecting structure according to claim 1, wherein: the detection end of the temperature detector (3) is attached to or matched with the bottom of the bearing plate (2) at intervals.

4. The electric furnace external temperature detecting structure according to claim 1, wherein: also comprises a furnace body (5); the bearing plate (2) is fixedly arranged at the upper opening of the furnace body (5); the heat generation module (1) and the temperature detector (3) are respectively and fixedly arranged between the bearing plate (2) and the furnace body (5).

5. The electric furnace outer temperature detecting structure according to claim 4, characterized in that: the furnace body (5) is provided with a support (6), the support (6) is provided with an assembly part (7), and the assembly part (7) is positioned outside the projection area of the heat generation module (1); the temperature detector (3) is arranged in the assembling part (7), and the detection end of the temperature detector is abutted against the bottom of the bearing plate (2).

6. The electric furnace external temperature detecting structure according to claim 5, wherein: the furnace body (5) and the bracket (6) are integrally formed, or the furnace body (5) and the bracket (6) are separately arranged and fixed with each other.

7. The electric furnace external temperature detecting structure according to claim 5, wherein: a supporting part (8) is arranged at the upper opening of the furnace body (5); the support (6) is provided with a supporting matching part (9) and is positioned and supported on the supporting part (8) through the supporting matching part (9).

8. The electric furnace external temperature detecting structure according to claim 7, wherein: the furnace body (5) is provided with a fixing part (10); the bracket (6) is provided with a fixed matching part (11) and is fixedly arranged on the fixed part (10) through the fixed matching part (11).

9. The electric furnace external temperature detecting structure according to claim 7, characterized in that: the bearing plate (2) is supported on the bearing matching part (9).

10. The electric furnace external temperature detecting structure according to claim 4, wherein: an assembly cavity (12) is formed between the bearing plate (2) and the furnace body (5); the heat generation module (1) and the temperature detector (3) form a space therebetween and are respectively and fixedly arranged in the assembly cavity (12).

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