CN221258905U - Electromagnetic oven - Google Patents

Abstract

The application provides an electromagnetic oven, which comprises a shell, a panel and a temperature sensing assembly, wherein the panel is matched with the shell to define an accommodating space, and a first through hole is formed in the panel; the temperature sensing assembly penetrates through the first through hole and is partially positioned outside the panel, and comprises a temperature sensing end face far away from the accommodating space, wherein the temperature sensing end face is used for being attached to the bottom of the pan to detect the temperature of the bottom of the pan; the temperature sensing end face can move relative to the panel under the action of external force so as to change the inclination angle relative to the panel. According to the induction cooker, under the action of pressure of the cooker, the temperature sensing end face can adaptively change the inclination angle of the temperature sensing end face relative to the panel according to the inclination of the contact surface of the cooker bottom, so that even if the cooker bottom is uneven, the temperature sensing end face can be well attached to the cooker bottom, the accuracy of detecting the temperature of the cooker bottom by the temperature sensing assembly is improved, and the reliability of temperature control of the induction cooker is further ensured.

Description

Electromagnetic oven

Technical Field

The application belongs to the technical field of induction cookers, and particularly relates to an induction cooker.

Background

Some induction cookers on the market at present are provided with through holes on the panel, and the telescopic temperature sensing device extends out of the panel through the through holes. When an external force is applied, the telescopic temperature sensing device is retracted into the panel; when the external force disappears, the telescopic temperature sensing device automatically rebounds to extend out of the panel. Therefore, when the pan is placed on the panel, the telescopic temperature sensing device can be better contacted with the pan bottom so as to ensure that the temperature can be measured. However, when the condition of uneven bottom of the pan exists, the temperature sensing device can not be well attached to the bottom of the pan, and the accuracy of temperature measurement is further affected.

Disclosure of utility model

The embodiment of the application provides an induction cooker, which can solve the problem of inaccurate temperature measurement caused by the fact that a temperature sensing device of the traditional induction cooker cannot be well attached to a cooker bottom.

In order to achieve the above purpose, the present application provides the following technical solutions:

an induction cooker, comprising:

A housing;

A panel which is matched with the shell to limit an accommodating space, and is provided with a first through hole;

The temperature sensing assembly penetrates through the first through hole and is partially positioned outside the panel, and comprises a temperature sensing end face far away from the accommodating space, and the temperature sensing end face is used for being attached to the bottom of the pan to detect the temperature of the bottom of the pan;

the temperature sensing end face can move relative to the panel under the action of external force so as to change the inclination angle relative to the panel.

In some embodiments, the temperature sensing assembly comprises:

The elastic piece is arranged in the first through hole in a penetrating way and is spaced from the inner wall of the first through hole formed by the panel;

The temperature sensing probe is connected to the elastic piece and is partially positioned outside the panel, and the temperature sensing probe comprises the temperature sensing end face;

the elastic piece deforms when the external force is applied to enable the temperature sensing probe to move, so that the inclination angle of the temperature sensing end face relative to the panel is adjusted, and the elastic piece recovers deformation when the external force is eliminated to enable the temperature sensing probe to return.

In some embodiments, the temperature sensing probe comprises:

A temperature sensor limited on the elastic piece and partially outside the panel, wherein the temperature sensor comprises a temperature sensing end far away from the accommodating space;

The heat conduction cap is arranged on one side, deviating from the accommodating space, of the temperature sensor, and covers the temperature sensing end, and the heat conduction cap deviates from the top surface of the temperature sensor to form the temperature sensing end surface.

In some embodiments, the temperature sensing assembly further comprises a sealing ring, one end of the sealing ring is connected with the periphery of the heat conducting cap, and the other end of the sealing ring is connected with the inner wall of the panel forming the first through hole, and is used for sealing a gap between the heat conducting cap and the inner wall of the panel forming the first through hole;

the middle part of sealing washer is equipped with folding section, folding section atress is deployable or folding.

In some embodiments, the temperature sensing assembly further comprises a telescopic mechanism fixedly installed in the accommodating space, and the elastic piece is connected with the telescopic mechanism;

And along the extending direction of the first through hole, the telescopic mechanism stretches when being subjected to external force so as to drive the temperature sensing end face to move relative to the panel.

In some embodiments, the telescoping mechanism comprises:

the fixed bracket is fixed on the shell;

The movable bracket is connected with the elastic piece and is used for supporting the elastic piece;

The two ends of the spring are respectively connected with the movable support and the fixed support, the spring stretches and contracts to enable the movable support to move relative to the fixed support, and the stretching direction of the spring is the same as the extending direction of the first through hole.

In some embodiments, the fixed bracket comprises a top plate opposite to the panel at intervals, the movable bracket comprises a main body part, and a first limiting part opposite to the top plate at intervals is arranged on the outer side wall of the main body part;

the spring is sleeved on the main body part, and two ends of the spring are respectively abutted with the first limiting part and the top plate.

In some embodiments, the top plate is provided with a second through hole, the main body part is partially penetrated through the second through hole, and the spring stretches to enable the main body part to move in the second through hole.

In some embodiments, the movable bracket further comprises a second limiting part connected with the first limiting part in a bending way;

A baffle plate is further bent and connected to the top plate around the second through hole, and the baffle plate defines a sliding track for the second limiting part to slide;

The second limiting part slides along the sliding track so as to ensure that the movable support moves along the extending direction of the first through hole relative to the fixed support.

In some embodiments, the induction cooker further comprises a circuit board fixedly mounted in the accommodating space, the elastic member and the main body part are cylindrical, the elastic member is communicated with the main body part, and the temperature sensor comprises:

The sensing element is used for sensing temperature;

And the wiring terminal penetrates through the elastic piece and the main body part, one end of the wiring terminal is connected with the sensing element, and the other end of the wiring terminal is connected with the circuit board.

According to the induction cooker provided by the embodiment of the application, under the pressure action of the cooker, the temperature sensing end face can be adaptively adjusted relative to the inclination angle of the panel according to the inclination of the contact surface of the cooker bottom, so that even if the cooker bottom is uneven, the temperature sensing end face can be well attached to the cooker bottom, the accuracy of detecting the temperature of the cooker bottom by the temperature sensing assembly is improved, the reliability of temperature control of the induction cooker is further ensured, the use safety of the induction cooker is improved, and the use experience of a user is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings that are required to be used in the description of the embodiments will be briefly described below. It is evident that the figures in the following description are only some embodiments of the application, from which other figures can be obtained without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an induction cooker according to an embodiment of the present application.

Fig. 2 is an exploded view of a part of the structure of the induction cooker shown in fig. 1.

Fig. 3 is a partial cross-sectional view of the induction cooker shown in fig. 1 along the A-A direction.

Fig. 4 is an exploded view of a temperature sensing assembly and a panel according to an embodiment of the present application.

Fig. 5 is a first state diagram of the temperature sensing assembly when the pan provided by the embodiment of the application is placed on the induction cooker.

Fig. 6 is a second state diagram of the temperature sensing assembly when the pan provided by the embodiment of the application is placed on the induction cooker.

Fig. 7 is an exploded view of a telescopic mechanism according to an embodiment of the present application.

Fig. 8 is a schematic structural diagram of an elastic member according to an embodiment of the present application.

Fig. 9 is a schematic structural diagram of a telescopic mechanism according to an embodiment of the present application.

Reference numerals illustrate:

10. an electromagnetic oven;

100. a housing; a panel 200; a temperature sensing assembly 300;

110. An accommodation space;

210. a first through hole; 220. a connecting bracket;

310. a temperature sensing probe; 320. an elastic member; 330. a seal ring; 340. a telescoping mechanism;

311. A temperature sensing end face; 312. a temperature sensor; 313. a heat conducting cap; 321. a connection portion; 322 a limit part; 323. a moving part; 331. a folding section; 332. a bending part; 341. a fixed bracket; 342. a movable bracket; 343. a spring;

3121. A sensing element; 3122. a connection terminal; 3411. a top plate; 3412. a second through hole; 3413. a baffle; 3421. a main body portion; 3422. a first limit part; 3423. a second limit part; 3424. and a connecting groove.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. It will be apparent that the described embodiments are only some, but not all, embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to fall within the scope of the application.

For a more complete understanding of the present application and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings. Wherein like reference numerals refer to like parts throughout the following description.

An embodiment of the present application provides an induction cooker, and for example, please refer to fig. 1-2, fig. 1 is a schematic structural diagram of the induction cooker provided in the embodiment of the present application, and fig. 2 is an exploded view of a part of the induction cooker shown in fig. 1. The induction cooker 10 includes a housing 100, a panel 200, and a temperature sensing assembly 300.

Wherein the housing 100 cooperates with the panel 200 to define the accommodating space 110. Illustratively, the housing 100 is a box-shaped body with an upper end opening, and the panel 200 includes a glass panel body and a mounting frame, wherein the glass panel body is assembled in the mounting frame, and the mounting frame is buckled on the upper end of the housing to complete the assembly. The material of the glass panel body is antimagnetic material such as ceramic microcrystalline glass. The panel 200 is provided with a first through hole 210. It is understood that the first through hole 210 should be formed on the glass panel body.

One end of the temperature sensing component 300 is fixedly installed in the accommodating space 110, and the other end is penetrated through the first through hole 210 and is partially positioned outside the panel 200. The temperature sensing assembly 300 includes a temperature sensing end surface 311 far away from the accommodating space 110, and the temperature sensing end surface 311 is used for being attached to the bottom of the pan to detect the temperature of the bottom of the pan.

The temperature sensing end surface 311 can move relative to the panel 200 under an external force to change the inclination angle relative to the panel 200. Illustratively, when the temperature sensing end surface 311 is not subjected to an external force, the temperature sensing end surface 311 is parallel to the panel 200, and when the temperature sensing end surface 311 is subjected to an external force, the temperature sensing end surface 311 is inclined with respect to the panel 200.

In practical application, when a user places a pan on the panel 200, the temperature sensing end face 311 moves under the pressure action of the pan and inclines to be parallel to and abutted against the contact surface of the pan bottom, so that even if the pan bottom is uneven, the temperature sensing end face 311 can be well attached to the pan bottom.

According to the induction cooker provided by the embodiment of the application, under the pressure action of the cooker, the temperature sensing end face can adaptively change the inclination angle of the temperature sensing end face relative to the panel according to the inclination of the contact surface of the cooker bottom, so that even if the cooker bottom is uneven, the temperature sensing end face can be well attached to the cooker bottom, the accuracy of detecting the temperature of the cooker bottom by the temperature sensing assembly is improved, the reliability of temperature control of the induction cooker is further ensured, the use safety of the induction cooker is improved, and the use experience of a user is improved.

Further, referring to fig. 3-4, fig. 3 is a partial cross-sectional view of the induction cooker shown in fig. 1 along A-A direction, and fig. 4 is an exploded view of a temperature sensing assembly and a panel according to an embodiment of the present application. The temperature sensing assembly 300 includes a temperature sensing probe 310, an elastic member 320, a sealing ring 330, and a telescopic mechanism 340.

The elastic member 320 is disposed through the first through hole 210 and spaced from an inner wall of the panel 200 forming the first through hole 210. The temperature sensing probe 310 is connected to the elastic member 320 and is partially located outside the panel 200. The temperature sensing probe 310 includes the temperature sensing end face 311 described above. It will be appreciated that the end surface of the temperature sensing probe 310, which is far from the accommodating space 110, forms a temperature sensing end surface 311 in the portion of the panel 200 that protrudes.

The elastic piece 320 deforms when an external force is applied to enable the temperature sensing probe 310 to move, so that the inclination angle of the temperature sensing end face 311 relative to the panel is changed; when the external force is removed, the elastic member 320 resumes the deformation to return the temperature sensing probe 310 to the original position. Illustratively, the elastic member 320 is made of rubber, and in other embodiments, the elastic member 320 may be a spring.

Illustratively, the temperature sensing probe 310 includes a temperature sensor 312 and a thermally conductive cap 313. The temperature sensor 312 is retained in the elastic member 320 and partially outside the panel 200. The temperature sensor 312 includes a temperature-sensing end remote from the accommodating space 110. The heat conducting cap 313 is disposed on a side of the temperature sensor 312 facing away from the accommodating space 110, and the heat conducting cap 313 is covered on the temperature sensing end. The top surface of the heat conducting cap 313 facing away from the temperature sensor 312 forms a temperature sensing end surface 311. In some embodiments, the edge of the heat conducting cap 313 abuts against the elastic element 320 towards the outer wall of the heat conducting cap 313, so that the elastic element 320 deforms to drive the heat conducting cap 313 to move, so that the top surface of the heat conducting cap 313, i.e. the temperature sensing end surface 311, is inclined relative to the panel 200.

In practical application, referring to fig. 5, fig. 5 is a first state diagram of the temperature sensing assembly when the pan provided by the embodiment of the application is placed on the induction cooker. When a user places the pan on the panel 200, pressure of the pan acts on the elastic member 320 through the heat conductive cap 313 to bend and deform the elastic member 320, and the heat conductive cap 313 is inclined with respect to the panel 200 and well fits with the uneven pan bottom.

The sealing ring 330 has a ring shape, one end of which is hermetically connected to the outer circumference of the heat conductive cap 313, and the other end of which is hermetically connected to the inner wall of the panel 200, for sealing the gap between the heat conductive cap 313 and the inner wall of the panel 200 forming the first through hole 210. It can be appreciated that by adding the sealing ring 330, external water can be prevented from entering the induction cooker 10 through the first through hole 210 to damage internal components. The middle part of sealing washer 330 is equipped with folding section 331, and folding section 331 atress is deployable or folding to avoid sealing washer 330 to cause the restriction to the removal of heat conduction cap 313, improved the structural strength of temperature sensing subassembly 300 simultaneously. It should be noted that, the sealing ring 330 may be made of rubber, and the folded section 331 may be unfolded or folded laterally or may be unfolded or folded longitudinally.

In some embodiments, around the first through hole 210, an inner wall of the panel 200 is provided with a connection bracket 220, for example, and the connection bracket 220 extends in a thickness direction of the panel 200, for example. The outer wall of the connecting bracket 220 facing the first through hole 210 is provided with a first groove for accommodating the outer ring part of the sealing ring 330, and the outer ring part of the sealing ring 330 is in sealing connection with the groove wall of the first groove, such as by gluing with sealant, so that the reliability of the sealing connection between the sealing ring 330 and the panel 200 is improved. The inner ring portion of the sealing ring 330 is formed with, for example, a bent portion 332 with an L-shaped vertical section, one end of the bent portion 332 is clamped between the edge of the heat conducting cap 313 and the elastic member 320, and the other end is in sealing connection with the outer periphery of the heat conducting cap 313, so that the reliability of connection between the sealing ring 330 and the heat conducting cap 313 is improved. Preferably, the bending part 332 is glued to the heat conducting cap 313 and the elastic member 320 by sealant.

The telescopic mechanism 340 is fixedly installed in the accommodating space 110. The elastic member 320 is connected with the telescopic mechanism 340. Along the extending direction of the first through hole 210, the telescopic mechanism 340 stretches under an external force to drive the temperature sensing end face 311 to move relative to the panel 200.

In practical application, referring to fig. 6, fig. 6 is a second state diagram of the temperature sensing assembly when the pan provided by the embodiment of the application is placed on the induction cooker. When a user places the pan on the panel 200, under the pressure of the pan, the elastic member 320 and the heat conducting cap 313 move relative to the panel 200 toward the direction of the side of the accommodating space 110, and the sealing ring 330 deforms, so that the telescopic mechanism 340 contracts along the extending direction of the first through hole 210. Meanwhile, as the telescopic mechanism 340 is contracted to generate resilience force, the elastic piece 320 can apply thrust force to the heat conduction cap 313 towards the movement of the pot, so that the top surface of the heat conduction cap 313 and the temperature sensing end surface 311 are tightly attached to the pot bottom, and the accuracy of measuring the temperature of the pot bottom by the temperature sensing assembly 300 is improved.

In some embodiments, referring to fig. 7, fig. 7 is an exploded view of a telescopic mechanism according to an embodiment of the present application. The telescopic mechanism 340 includes a fixed bracket 341, a movable bracket 342, and a spring 343.

Wherein the fixed bracket 341 is fixed to the housing 100, for example, by a connector. The movable bracket 342 is connected to the elastic member 320 for supporting the elastic member 320. The two ends of the spring 343 are respectively connected with the fixed bracket 341 and the movable bracket 342, and the spring 343 is used for stretching to enable the movable bracket 342 to move relative to the fixed bracket 341. The extension and retraction direction of the spring 343 is the same as the extension direction of the first through hole 210, so that the movable bracket 342 moves with respect to the extension direction along the first through hole 210 of the fixed bracket 341.

Further, the movable bracket 342 includes a main body portion 3421. The fixed bracket 341 includes a top plate 3411 spaced opposite to the panel 200. The outer side wall of the main body 3421 is provided with a first stopper 3422 facing the top plate 3411 at a distance. The spring 343 is sleeved on the main body 3421 and is located between the first limiting portion 3422 and the top plate 3411. Both ends of the spring 343 are respectively abutted against the first stopper 3422 and the top plate 3411. Preferably, the top plate 3411 is perpendicular to the extending direction of the first through hole 210. The extending direction of the first limiting portion 3422 is perpendicular to the extending direction of the first through hole 210. The first limiting portion 3422 is, for example, annular in shape, so as to improve stability of the spring 343 after assembly and reduce difficulty of assembly.

In some embodiments, the top plate 3411 has a second through hole 3412 formed therein, and the main body 3421 is disposed through the second through hole 3412. The spring 343 expands and contracts to move the body portion 3421 in the second through hole 3412.

In some embodiments, induction cooker 10 also includes a circuit board (not shown). The elastic member 320 and the main body portion 3421 are both cylindrical in shape, and the elastic member 320 communicates with the main body portion 3421. The temperature sensor 312 includes a sensing element 3121 and a connection terminal 3122. The sensing element 3121 is used for sensing temperature. The connection terminal 3122 is disposed through the elastic member 320 and the main body 3421, and one end of the connection terminal 3122 is connected to the sensing element 3121 and the other end is connected to the circuit board of the induction cooker 10. It will be appreciated that the sensing element 3121 is configured to detect the temperature of the bottom of the pan through the heat conducting cap 313 and send a feedback signal to the circuit board through the connection terminal 3122, so that the circuit board obtains the detected temperature of the bottom of the pan according to the feedback signal, and the circuit board is configured to perform temperature control of the induction cooker 10 according to the temperature of the bottom of the pan.

For example, referring to fig. 8, fig. 8 is a schematic structural diagram of an elastic member according to an embodiment of the application. The elastic member 320 includes a connection portion 321, a limiting portion 322, and a moving portion 323, which are sequentially connected.

Wherein, the connecting part 321 and the moving part 323 are in a cylinder/ring shape and are communicated with each other. The diameter of the moving portion 323 is, for example, larger than that of the connecting portion 321, and when the temperature sensing end face 311 receives an external force, the moving portion 323 is inclined to one side with respect to the connecting portion 321, thereby driving the temperature sensing end face 311 to change the inclination angle with respect to the panel 200.

The connecting portion 321 is for connecting to an outer wall of the main body portion 3421 remote from the top plate 3411. Referring to fig. 9, fig. 9 is a schematic structural diagram of a telescopic mechanism according to an embodiment of the present application. The outer wall of the main body 3421 facing the panel 200 is provided with a connecting groove 3424. The connection portion 321 is inserted into the connection groove 3424 to connect the elastic member 320 with the movable bracket 342. The bottom wall of the connecting groove 3424 is provided with a through hole through which the main body portion 3421 communicates with the connecting portion 321.

The limiting portion 322 is provided on an outer sidewall of an end of the connecting portion 321 remote from the main body portion 3421. The limiting portion 322 is, for example, annular in shape, and is configured to abut against an outer wall of the main body 3421 facing the panel 200, so as to limit the main body 3421. Meanwhile, the limiting portion 322 is spaced apart from the moving portion 323 to reserve a tilting movement space of the moving portion 323.

In some embodiments, the movable bracket 342 further includes a second limiting portion 3423 in bending connection with the first limiting portion 3422. Around the second through hole 3412 on the top plate 3411, the top plate 3411 is bent towards the surface of the movable bracket 342 to be connected with a baffle plate 3413, and the baffle plate 3413 defines a sliding track for the second limiting part 3423 to slide. The second limiting portion 3423 slides along the sliding track to ensure that the movable bracket 342 moves along the extending direction of the first through hole 210 relative to the fixed bracket 341. Preferably, the shape of the baffle 3413 is cylindrical, and the shape of the second limiting portion 3423 is cylindrical matched with the shape of the baffle 3413, and the baffle 3413 is at least partially sleeved with the second limiting portion 3423, so as to improve the structural strength when the baffle 3413 and the second limiting portion are matched. More preferably, the baffle 3413 and the second limiting part 3423 are cylindrical in shape, so as to reduce the complexity of assembly.

According to the induction cooker 10 provided by the embodiment of the application, the temperature sensing end face 311 can move up and down relative to the panel 200 by additionally arranging the telescopic mechanism 340, so that the temperature sensing end face is closely attached to the bottom of a pot. In addition, by adding the elastic piece 320, the temperature sensing end face 311 can adjust the inclination angle relative to the panel 200 according to the contact surface with the pan bottom, so that the temperature sensing end face can be well attached to the pan bottom. Therefore, even under the condition of uneven bottom, the induction cooker 10 of the application can ensure that the temperature sensing end face 311 is well attached to the bottom, thereby ensuring the accuracy of temperature measurement of the temperature sensing assembly 300 and improving the reliability of temperature control of the induction cooker 10.

The above description of the induction cooker provided by the embodiment of the present application has been provided in detail, and specific examples are applied to illustrate the principle and implementation of the present application, and the above description of the embodiment is only used to help understand the method and core idea of the present application; meanwhile, as those skilled in the art will vary in the specific embodiments and application scope according to the ideas of the present application, the present description should not be construed as limiting the present application in summary.

Claims (10)

1. An induction cooker, comprising:

A housing;

A panel which is matched with the shell to limit an accommodating space, and is provided with a first through hole;

The temperature sensing assembly penetrates through the first through hole and is partially positioned outside the panel, and comprises a temperature sensing end face far away from the accommodating space, and the temperature sensing end face is used for being attached to the bottom of the pan to detect the temperature of the bottom of the pan;

the temperature sensing end face can move relative to the panel under the action of external force so as to change the inclination angle relative to the panel.

2. The induction hob according to claim 1, characterized in, that the temperature sensing assembly comprises:

The elastic piece is arranged in the first through hole in a penetrating way and is spaced from the inner wall of the first through hole formed by the panel;

The temperature sensing probe is connected to the elastic piece and is partially positioned outside the panel, and the temperature sensing probe comprises the temperature sensing end face;

the elastic piece deforms when the external force is applied to enable the temperature sensing probe to move, so that the inclination angle of the temperature sensing end face relative to the panel is adjusted, and the elastic piece recovers deformation when the external force is eliminated to enable the temperature sensing probe to return.

3. The induction hob according to claim 2, characterized in, that the temperature sensing probe comprises:

A temperature sensor limited on the elastic piece and partially outside the panel, wherein the temperature sensor comprises a temperature sensing end far away from the accommodating space;

The heat conduction cap is arranged on one side, deviating from the accommodating space, of the temperature sensor, and covers the temperature sensing end, and the heat conduction cap deviates from the top surface of the temperature sensor to form the temperature sensing end surface.

4. The induction cooker according to claim 3, wherein said temperature sensing assembly further comprises a sealing ring, one end of said sealing ring is connected to an outer periphery of said heat conducting cap, and the other end is connected to an inner wall of said panel forming said first through hole for sealing a gap between said heat conducting cap and said inner wall of said panel forming said first through hole;

the middle part of sealing washer is equipped with folding section, folding section atress is deployable or folding.

5. The induction cooker of claim 3, wherein said temperature sensing assembly further comprises a telescoping mechanism fixedly mounted within said receiving space, said elastic member being connected to said telescoping mechanism;

And along the extending direction of the first through hole, the telescopic mechanism stretches when being subjected to external force so as to drive the temperature sensing end face to move relative to the panel.

6. The induction hob according to claim 5, characterized in, that the telescopic mechanism comprises:

the fixed bracket is fixed on the shell;

The movable bracket is connected with the elastic piece and is used for supporting the elastic piece;

The two ends of the spring are respectively connected with the movable support and the fixed support, the spring stretches and contracts to enable the movable support to move relative to the fixed support, and the stretching direction of the spring is the same as the extending direction of the first through hole.

7. The induction cooker of claim 6, wherein said fixed bracket includes a top plate spaced apart from said panel, said movable bracket includes a main body portion, and a first spacing portion spaced apart from said top plate is provided on an outer side wall of said main body portion;

the spring is sleeved on the main body part, and two ends of the spring are respectively abutted with the first limiting part and the top plate.

8. The induction cooker of claim 7, wherein said top plate defines a second through hole, said body portion is disposed through said second through hole, and said spring expands and contracts to move said body portion within said second through hole.

9. The induction cooker of claim 8, wherein the movable bracket further comprises a second limiting portion in bending connection with the first limiting portion;

A baffle plate is further bent and connected to the top plate around the second through hole, and the baffle plate defines a sliding track for the second limiting part to slide;

The second limiting part slides along the sliding track so as to ensure that the movable support moves along the extending direction of the first through hole relative to the fixed support.

10. The induction cooker according to claim 8 or 9, further comprising a circuit board fixedly mounted in the accommodation space, the elastic member and the main body portion each have a cylindrical shape, and the elastic member communicates with the main body portion, the temperature sensor comprising:

The sensing element is used for sensing temperature;

And the wiring terminal penetrates through the elastic piece and the main body part, one end of the wiring terminal is connected with the sensing element, and the other end of the wiring terminal is connected with the circuit board.