CN209899109U - Pan and electromagnetism stove cooking utensil - Google Patents

Abstract

The utility model provides a cooker and an induction cooker, the cooker comprises a cooker body (20) and a cooker cover (10), the cooker body (20) is provided with an anti-overflow probe (23) which is insulated with the cooker body (20) and is electrically connected with a control panel, one end of the anti-overflow probe (23) extends into the cooker body (20), the cooker body (20) is electrically connected with the control panel, when the soup overflowing from the pot body (20) contacts the anti-overflow probe (23), the pot body (20) is communicated with the anti-overflow probe (23), so that the control panel is according to the heating state of switch on signal control electromagnetism stove, just anti-overflow probe (23) are located one end in the pot body (20) with distance between the pot body (20) inner wall is 1 ~ 5mm, the utility model provides a pan has solved in the current electromagnetism stove cooking utensil because NCT subassembly and anti-overflow electrode establish on the pot cover and cause the pot cover to take off the problem that just can't carry out the anti-overflow.

Description

Pan and electromagnetism stove cooking utensil

Technical Field

The utility model relates to a household electrical appliances field, in particular to pan and electromagnetism stove cooking utensil.

Background

An electromagnetic oven cooker is a widely used cooking appliance, which is an electric cooking appliance heated by electromagnetic induction and consists of a high-frequency induction coil panel (namely an excitation coil), a controller, a ferromagnetic material pot bottom cooker and other units.

At present, in the electromagnetic oven cooker with accurate Temperature control, an accurate Temperature control Negative Temperature Coefficient thermistor (NTC) component is arranged on a cooker cover, food can generate steam and raise the Temperature of air in a cooker during heating, the NTC component detects the change of the steam or the Temperature of the air in the cooker, the NTC component is also used as one electrode of anti-overflow detection, the other electrode is connected with a cooker body through the metal edge of the cooker cover, water bubbles can be generated when soup overflows, the current change is generated when the water bubbles contact the NTC component and is fed back to a circuit on the cooker cover, a wireless transmitting device in a cooker cover handle transmits the Temperature change signal and the overflow signal to a circuit in the cavity of the electromagnetic oven cooker, an intelligent chip processes information, and according to the information, different heating modes of the electromagnetic oven cooker are instructed so as to achieve the purposes of accurate temperature control and overflow prevention.

However, in the above-mentioned induction cooker, since the NTC assembly is mounted on the lid, the lid must be placed on the body to be detected, and the overflow prevention cannot be performed once the lid is removed.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem mentioned in the background art that at least one of the overflow prevention can not be performed when the cover is moved away due to the fact that the NCT assembly is arranged on the cover in the electromagnetic oven cooker, the utility model provides an overflow prevention cooker and electromagnetic oven cooker.

The utility model provides an electromagnetic oven cooker, including the pot body and pot cover, wherein:

the anti-overflow probe is insulated with the pot body and electrically connected with the control board, one end of the anti-overflow probe extends into the pot body, the pot body is electrically connected with the control board, and when soup overflowing from the pot body contacts the anti-overflow probe, the pot body is conducted with the anti-overflow probe, so that the control board controls the heating state of the induction cooker according to a conducting signal;

and the distance between one end of the anti-overflow probe in the pot body and the inner wall of the pot body is 1-5 mm.

The pot provided by the embodiment is characterized in that the pot body is provided with the anti-overflow probe which is insulated from the pot body and is electrically connected with the control board, one end of the anti-overflow probe extends into the pot body, the pot body is electrically connected with the control board, so that when soup overflowing from the pot body contacts the anti-overflow probe, the pot body is communicated with the anti-overflow probe, the control board controls the heating state of the induction cooker according to a conduction signal, the anti-overflow purpose can be still achieved when the pot cover is taken away even if the pot cover is taken away, but when the soup contacts the anti-overflow probe, the anti-overflow probe is communicated with the pot body, the control board can still control the heating state of the induction cooker according to the conduction signal, and moreover, the distance between one end of the anti-overflow probe in the pot body and the inner wall of the pot body is 1-5 mm, so that the anti-overflow probe can accurately sense the overflowe, solves the problem that the prior electromagnetic oven cooker cannot prevent overflow when the cooker cover is taken off because the NCT component and the overflow-proof electrode are arranged on the cooker cover.

Optionally, a metal area insulated from the pot body is arranged on the pot cover, when the pot cover is covered on the pot body, the metal area is in contact with the anti-overflow probe, and when soup overflowing from the pot body contacts the metal area or the anti-overflow probe, the pot body is conducted with the anti-overflow probe.

Optionally, the metal area is an annular metal edge arranged along the outer edge of the pot cover.

Optionally, one end of the spill-proof probe in the pot body is telescopic.

Optionally, the distance between the spill-proof probe and the edge of the pot opening of the pot body is 5-50 mm.

Optionally, the pot body is provided with a hole for the anti-overflow probe to extend into the pot body, and a sealing element is arranged between the anti-overflow probe and the hole.

Optionally, the method further includes: and the temperature measuring component is electrically connected with the control panel and is attached to the outer side wall of the pot body.

Optionally, the outer side wall of the pot body is provided with an assembly box which can cover the temperature measuring assembly and can be used for the anti-overflow probe to be arranged.

Optionally, the assembly box is provided with a connecting electrode connected with the anti-overflow probe and the temperature measuring component, and the connecting electrode is used for electrically connecting the anti-overflow probe, the temperature measuring component and the pot body with the control panel arranged in the electromagnetic oven.

Optionally, the connection electrode is telescopically arranged on the end face of the bottom end of the assembly box, the anti-overflow probe is telescopically arranged on the top end of the assembly box, and one end of the connection electrode and one end of the anti-overflow probe are both located in the assembly box.

Optionally, be equipped with wireless transmission module in the assembly box, wireless transmission module be used for with anti-overflow probe with switch on signal between the pot body and the temperature signal that temperature measurement component detected sends for the electromagnetism stove, so that the electromagnetism stove is according to switch on signal with temperature signal control heating state.

The utility model also provides an electromagnetism stove cooking utensil, including electromagnetism stove and the aforesaid arbitrary pan.

Optionally, be equipped with on the electromagnetism stove with the response electrode that connecting electrode corresponds on the pan, anti-overflow probe and temperature measurement subassembly on the pan pass through response electrode with connecting electrode contact with the electromagnetism stove electrical property links to each other.

Optionally, be equipped with on the electromagnetism stove with assembly box complex adaptation portion on the pan, so that the pan is in realize the location on the electromagnetism stove, just the response electrode is established on the adaptation portion.

Optionally, the method further includes:

the control panel is arranged in the electromagnetic oven, the anti-overflow probe, the temperature measuring component and the pot body are electrically connected with the control panel through the contact of the connecting electrode and the induction electrode, or,

further comprising: first control panel and second control panel, wherein, first control panel is established in the assembly box of pan and with the connecting electrode links to each other, the anti-overflow probe the temperature measurement subassembly and the pan body all with first control panel electrical property links to each other, the second control panel is established in the electromagnetism stove and with the response electrode links to each other, first control panel with the second control panel passes through the connecting electrode with the response electrode contact realizes that the electrical property links to each other, perhaps, first control panel with the second control panel passes through wireless mode transmission signal.

The structure of the present invention and other objects and advantages thereof will be more clearly understood from the following description of the preferred embodiments taken in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor.

Fig. 1A is a schematic view of a disassembled structure of a pot provided in an embodiment of the present invention;

fig. 1B is a schematic cross-sectional view of a pot according to an embodiment of the present invention;

FIG. 1C is an enlarged schematic view of portion A of FIG. 1B;

fig. 1D is a schematic cross-sectional view of a pot body in a pot provided in an embodiment of the present invention;

FIG. 1E is an enlarged schematic view of portion B of FIG. 1D;

fig. 1F is a schematic perspective view of a pot body in a pot provided in an embodiment of the present invention;

FIG. 2A is a schematic cross-sectional view of an electromagnetic oven cooker according to an embodiment of the present invention;

FIG. 2B is a schematic view of a disassembled structure of the cooker of the electromagnetic oven according to the second embodiment of the present invention;

fig. 2C is a schematic structural diagram of an induction cooker in the induction cooker according to the second embodiment of the present invention.

Description of reference numerals:

100-a pot;

10-a pot cover;

11-a metal region;

20-a pot body;

21-assembling a box;

211-inner housing;

212-an outer shell;

22-connecting electrodes;

23-an anti-overflow probe;

24-a temperature measuring component;

25-a silicone piece;

26-well;

200-induction cooker;

30-an induction cooker;

31 — an adaptation portion;

32-sensing electrode.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings in the embodiments of the present invention are combined below to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the described embodiments are embodiments of a unit of the present invention, rather than embodiments of a whole unit. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As described in the background art, the existing electromagnetic oven cooker with the anti-overflow function has the problem that the anti-overflow cannot be performed when the pot cover is removed, and the problem is caused by that: in the existing electromagnetic oven cooker with accurate temperature control, because the NTC component and the anti-overflow electrode are positioned on the cooker cover, when the cooker cover is taken away, the temperature measurement and the anti-overflow of the cooker can not be carried out, so that the soup in the cooker is easy to overflow.

For the above reasons, the present embodiment provides a pot, which is exemplified as follows:

example one

Fig. 1A is the utility model provides a split structure schematic diagram of pan, fig. 1B is the utility model provides a section structure schematic diagram of pan, fig. 1C is the enlarged structure schematic diagram of part a in fig. 1B, fig. 1D is the utility model provides a section structure schematic diagram of the pan body in the pan, fig. 1E is the enlarged structure schematic diagram of part B in fig. 1D, fig. 1F is the utility model provides a three-dimensional structure schematic diagram of the pan body in the pan.

In this embodiment, as shown in fig. 1A-1F, the pot 100 includes a pot body 20 and a pot cover 10, the pot body 20 is provided with an anti-overflow probe 23 insulated from the pot body 20 and electrically connected to a control board, one end of the anti-overflow probe 23 extends into the pot body 20, wherein, in order to form an anti-overflow loop, in this embodiment, the anti-overflow probe 23 is one of the electrodes, the pot body 20 is the other electrode, that is, in this embodiment, the pot body 20 is specifically a conductive metal pot body 20, and when the pot cover 10 covers the pot body 20, the pot body 20 is electrically connected between the pot and the control board, so that when soup in the pot 100 contacts the anti-overflow probe 23, the pot body 20 and the soup are conducted to form the anti-overflow loop, the control board determines that the pot body 20 is conducted with the anti-overflow probe 23 according to a conduction signal (such as a current change, at this time, the control board controls the heating state of the electromagnetic oven 30, the heating state may be, for example, a state of suspending heating or reducing heating power, etc., so as to reduce the temperature in the cooker 100 and prevent the soup from overflowing from the inside of the cooker body 20, in this embodiment, the anti-overflow probe 23 is disposed on the cooker body 20, once the soup in the cooker body 20 contacts the anti-overflow probe 23, the control board controls the electromagnetic oven 30 according to the signal of the anti-overflow probe 23 communicating with the cooker body 20, thereby achieving a good anti-overflow effect, so that the soup in the cooker body 20 is not easy to overflow, and the anti-overflow probe 23 is disposed on the cooker body 20, so that even if the cooker cover 10 is taken away, when the soup contacts the anti-overflow probe 23, the anti-overflow probe 23 communicates with the cooker body 20, the control board can still control the heating state of the electromagnetic oven 30 according to the communication signal, therefore, in this embodiment, the purpose of still achieving the anti, the problem that soup cannot be prevented from overflowing when the pot cover 10 is taken away is solved, and therefore the pot 100 provided by the embodiment achieves the purpose that the soup can still overflow when the pot cover 10 is taken away.

Wherein, in this embodiment, when the one end of anti-overflow probe 23 stretched into in the pot body, if anti-overflow probe 23 stretched into the part of pot body too long, touch anti-overflow probe 23 easily when putting into food or pouring out food, make anti-overflow probe 23 easily crash bad, and anti-overflow probe 23 stretched into the part of pot body too short, can lead to anti-overflow probe 23 and the bad influence anti-overflow performance of hot water contact, can accurately play the anti-overflow effect in order to ensure anti-overflow probe 23, it is concrete, anti-overflow probe 23 is located the one end of pot body 20 and the distance L between the 20 inner walls of pot body is 1 ~ 5mm, for example, the distance L that anti-overflow probe 23 is located between one end of pot body 20 and the 20 inner walls of pot body can be 3mm, or 4mm etc., ensured that anti-overflow probe 23 can accurately sense the hot water that overflows like this, simultaneously not easy to be hit bad by food.

Therefore, in the pot 100 provided by the embodiment, the anti-overflow probe 23 insulated from the pot body 20 and electrically connected to the control board is disposed on the pot body 20, and one end of the anti-overflow probe 23 extends into the pot body 20, the pot body 20 is electrically connected to the control board, so that when the soup overflowing from the pot body 20 contacts the anti-overflow probe 23, the pot body 20 is conducted to the anti-overflow probe 23, so that the control board controls the heating state of the induction cooker 30 according to the conduction signal, even if the pot cover 10 is taken off, when the soup contacts the anti-overflow probe 23, the anti-overflow probe 23 is conducted to the pot body 20, the control board can still control the heating state of the induction cooker 30 according to the conduction signal, thereby achieving the purpose of preventing overflow when the pot cover 10 is taken off, and the distance between one end of the anti-overflow probe 23 located in the pot body and the inner wall of the pot body is 1-5 mm, so that the anti-overflow probe 23 can accurately sense the overf, therefore, the pot 100 of the present embodiment solves the problem that the existing induction cooker cannot prevent overflow when the lid is taken off due to the fact that the NCT assembly and the overflow prevention electrode are disposed on the lid.

In this embodiment, when one end of the overflow-preventing probe 23 extends into the pot body 20 to sense the overflowing soup, the overflow-preventing probe 23 can only sense the overflowing soup at one position, the contact point is small, the foam cannot be fully contacted, the foam is easily overflowed but the foam does not reach the overflow-preventing probe 23, and the overflow-preventing effect cannot be achieved, in order to increase the sensing area of the overflow-preventing probe 23, specifically, in this embodiment, the metal region 11 insulated from the pot body 20 is disposed on the pot cover 10, when the pot cover 10 is covered on the pot body, the metal region 11 is contacted with the overflow-preventing probe 23, so that, when the overflowing soup in the pot body 20 contacts the metal region 11 or the overflow-preventing probe 23, the pot body 20 is conducted with the overflow-preventing probe 23, that is, in this embodiment, the overflow-preventing probe 23 is contacted with the metal region 11 of the pot cover 10, and the metal region 11 is a plane, so as compared with the point sensing of the, the area for sensing the foam is enlarged, so that the overflow-preventing probe 23 can sense the soup overflowing from the cooker body in an all-around manner.

In this embodiment, the metal area 11 may be specifically an annular metal covering edge arranged on the outer edge of the pot cover 10, and the rest of the pot cover 10 may be made of glass material or ceramic material, and the metal covering edge is arranged in a circle along the outer edge of the glass portion of the pot cover 10, or in this embodiment, the whole pot cover 10 may be made of metal material, so that the whole outer surface of the pot cover 10 is the metal area 11.

Wherein, in this embodiment, for the induction zone of further increase anti-overflow probe 23, the annular metal limit that metal zone 11 set up for the outward flange along pot cover 10, when pot cover 10 lid was established on pot body 20, annular metal limit can be around a week along the inner wall of pot body 20, like this when the hot water juice of arbitrary position in the pot body 20 spills over and start the anti-overflow function with homoenergetic trigger when the metal limit contacts, the anti-overflow is more comprehensive effect better, so, in this embodiment, when setting up to annular through the metal zone, the scope of hot water juice and the regional 112 contact of metal in the pot body 20 has been enlarged, 360 degrees induction foam's mesh has been realized, make the anti-overflow more comprehensive.

In the embodiment, when the anti-overflow probe 23 extends into the pot body 20 and contacts with the metal area 11 of the pot cover, since the anti-overflow probe 23 and the metal area 11 are both made of metal, the contact therebetween is easily damaged by hard-on-hard, and for this reason, in the present embodiment, in order to avoid the situation that the metal area 11 of the pot cover 10 and the anti-overflow probe 23 are hard to touch and damage the two, specifically, one end of the anti-overflow probe 23 positioned in the pot body 20 is telescopic, namely, one end of the anti-overflow probe 23 has elasticity, so that when the pot cover 10 is covered on the pot body 20 and the metal area 11 touches the anti-overflow probe 23, the anti-overflow probe 23 is squeezed and retracted, meanwhile, the anti-overflow probe 23 is tightly abutted on the metal area 11 under the action of the elastic force, so that the anti-overflow probe 23 is tightly contacted with the metal area 11, and the anti-overflow probe 23 is easily electrically connected with the metal area 11.

In this embodiment, the anti-overflow probe 23 may have elasticity, for example, the anti-overflow probe 23 is made of an elastic material, or the anti-overflow probe 23 is supported by a silicon rubber or a spring to have elasticity, so that the anti-overflow probe 23 can extend and contract in the pot body 20.

In this embodiment, when the anti-overflow probe 23 is disposed on the pot body 20 and is low, when one end of the anti-overflow probe 23 extends into the pot body 20, the soup is easily contacted with the anti-overflow probe 23 to cause misjudgment, and when the anti-overflow probe 23 is disposed on the pot body 20 and is high, the soup is easily contacted with the anti-overflow probe 23 when overflowing from the pot body 20, so that the anti-overflow function of the pot 100 is delayed, in this embodiment, in order to ensure that the anti-overflow probe 23 plays a role of preventing overflow, the anti-overflow probe 23 is disposed on the upper portion of the pot body 20, specifically, the vertical distance h between the anti-overflow probe 23 and the pot mouth may be 5-50mm, for example, the vertical distance h between the anti-overflow probe 23 and the pot mouth may be 25mm or 35 mm.

In this embodiment, when one end of the anti-overflow probe 23 passes through the pot body 20 and extends into the pot body 20, specifically, the pot body 20 is provided with a hole 26 through which the anti-overflow probe 23 extends into the pot body 20, and a sealing member is disposed between the anti-overflow probe 23 and the hole 26, and the sealing member is specifically a silicon rubber member 25.

Among them, in the prior art, because the NCT subassembly is established on pot cover 10, so, the NTC subassembly detects the temperature of ambient air, and is not the temperature of food, and there is an error in the test, especially under cryogenic state, the steam that liquid produced is few, and the temperature of air is lower again, and the temperature of test is inaccurate, does not have the function of accurate accuse temperature and anti-overflow when pot cover 10 removes away, and in this embodiment, in order to solve above-mentioned problem, it is concrete, still include: the temperature measuring component 24 is arranged on the outer side wall of the pot body 20, the temperature measuring component 24 is electrically connected with the control panel, and the temperature measuring component 24 is used for detecting the temperature of the pot 100, namely in the embodiment, the temperature measuring component 24 is arranged on the pot body 20, so that the temperature of the pot body 20 can be always detected even if the pot cover 10 is taken away in the cooking process, wherein in the embodiment, in order to realize that the temperature detected by the temperature measuring component 24 is close to the temperature in the pot body 20, specifically, the temperature measuring component 24 is arranged at the bottom end of the outer side wall of the pot body 20, and because the temperature at the bottom end of the pot body 20 solves the actual temperature of the pot body 20, in the embodiment, the accurate temperature measurement is realized by arranging the temperature measuring component 24 at the bottom end of the outer side wall of the pot body 20, wherein in the embodiment, the temperature measuring component 24 specifically comprises a metal, wherein, when temperature measurement subassembly 24 established on the lateral wall of the pot body 20, temperature measurement subassembly 24's metal casing hugs closely on the lateral wall of the pot body 20, the metal casing of temperature measurement subassembly 24 is given in the temperature transmission of the pot body 20 like this, temperature measurement component realizes the detection to pot body 20 temperature through the temperature that detects metal casing, therefore, in this embodiment, through set up anti-overflow probe 23 and temperature measurement subassembly 24 on the pot body 20 and realized the purpose of accurate temperature measurement and anti-overflow to pan 100, just can't carry out the problem of temperature measurement and anti-overflow when having solved among the current electromagnetism stove 30 cooking utensil because NCT subassembly and anti-overflow electrode establish on pot cover 10 and cause pot cover 10 to take off.

Wherein, in this embodiment, set up on the pot body 20 when anti-overflow probe 23 and temperature measurement component 24, in order to prevent to cause the damage to anti-overflow probe 23 and temperature measurement component 24 in the use, it is concrete, in this embodiment, be equipped with the assembly box 21 that the cover established on temperature measurement component 24 on the lateral wall of pot body 20, this embodiment promptly, assembly box 21 covers and establishes on temperature measurement component 24, has played the protection effect that shelters from to temperature measurement component 24, prevent that temperature measurement component 24 exposes outside the pot body 20, and simultaneously, in this embodiment, the one end of anti-overflow probe 23 sets up on the pot body 20, one end stretches into in the pot body 20, assembly box 21 also can cover the one end that anti-overflow probe 23 is located on the pot body 20 this moment, the one end of anti-overflow probe 23 is fixed in assembly.

Wherein, in this embodiment, the assembly box 21 includes interior casing 211 and outer casing 212, interior casing 211 and the outer lateral wall sealing connection of pot body 20, outer casing 212 lid is established on interior casing 211, in this embodiment, the interior casing 211 of assembly box 21 specifically is the base, the one end of anti-overflow probe 23 is located the assembly box 21 and is connected with interior casing 211, the other end of anti-overflow probe 23 stretches into in the pot body 20 and contacts with metal area 11, wherein, in this embodiment, when the one end of anti-overflow probe 23 is located the assembly box 21, specifically, fix through fastener (for example screw) between anti-overflow probe 23 and the interior casing 211, be equipped with the through-hole that can supply the one end of anti-overflow probe 23 to pass on the interior casing 211, the other end and interior casing 211 of anti-overflow probe 23 are connected, in this embodiment, outer casing 212 specifically can be as the.

In the embodiment, when the assembly box 21 is disposed on the outer side wall of the pot body 20, the assembly box 21 not only shields the temperature measuring component 24 and can be used for the anti-overflow probe 23, but also in this embodiment, the assembly box 21 can be used as a handle of the pot 100, that is, the outer surface of the assembly box 21 can be set as a handle for a user to carry, so as to avoid additionally disposing the handle of the pot 100 on the pot body 20, and meanwhile, in order to facilitate carrying, in this embodiment, the number of the assembly boxes 21 can be two, and the two assembly boxes 21 are symmetrically disposed on the outer side wall of the pot body 20, so that the two assembly boxes 21 are used as a pair of handles of the pot 100. In this embodiment, when the number of the assembly boxes 21 is two, the anti-overflow probe 23 and the temperature measuring component 24 may be disposed in one assembly box 21, or the anti-overflow probe 23 and the temperature measuring component 24 may be disposed in both of the two assembly boxes 21, specifically, the temperature measuring components 24 of the anti-overflow probes 23 in corresponding numbers are disposed according to practical applications.

Wherein, in the prior art, because the NCT assemblies are all arranged on the pot cover 10, the temperature or the anti-overflow signal detected by the NCT assemblies are all sent to the control board in the induction cooker 30 in a wireless manner, but a wireless connection mode is adopted, the cost of the wireless transmitting and receiving device is high, and the wireless transmitting and receiving device may be interfered, and the signal is unstable, for this reason, in order to solve the above problems, in this embodiment, specifically, the bottom end of the assembly box 21 is provided with the retractable connection electrode 22 connected with the anti-overflow probe 23 and the temperature measuring assembly 24, the connection electrode 22 is used for electrically connecting the anti-overflow probe 23, the temperature measuring assembly 24, and the pot body 20 with the control board arranged in the induction cooker 30, specifically, in this embodiment, the pot body 20 is provided with the connection electrode 22, the induction electrode 32 is arranged on the induction cooker 30, the induction electrode 22 and the induction, therefore, the anti-overflow probe 23, the temperature measuring component 24 and the cooker body 20 are directly electrically connected with the control panel in the induction cooker 30 through the contact of the connecting electrode 22 and the induction electrode 32, and the problems of high cost and unstable signals when the signals are transmitted between the cooker 100 and the induction cooker 30 in a wireless mode are solved.

In this embodiment, when the connection electrode 22 is disposed on the assembly box 21, specifically, the connection electrode 22 is located in the bottom end of the assembly box 21, and one end of the connection electrode 22 extends out from the bottom end of the assembly box 21 and contacts with the induction electrode 32 of the induction cooker 30, wherein the connection electrode 22 may have elasticity itself, or the connection electrode 22 may elastically stretch out and draw back through silica gel or a spring support, wherein in this embodiment, it should be noted that, when the number of the assembly boxes 21 is two, when the anti-overflow probes 23 and the temperature measurement assemblies 24 are disposed in two assembly boxes 21, the connection electrode 22 also needs to be disposed on two assembly boxes 21 at this time.

In this embodiment, the number of the connecting electrodes 22 is three, wherein the anti-overflow probe 23 is connected to one of the connecting electrodes 22, two electrodes of the temperature measuring assembly 24 are respectively connected to the other two connecting electrodes 22, one end of the anti-overflow lead is connected to one of the connecting electrodes 22 connected to the temperature measuring assembly 24, that is, the anti-overflow lead and one of the electrodes of the temperature measuring assembly 24 share one connecting electrode 22, wherein in this embodiment, when the number of the connecting electrodes 22 is three, the number of the sensing electrodes 32 on the induction cooker 30 is also three.

In the embodiment, the induction cooker 30 is provided with an adapting portion 31 which is matched with the assembling box 21, and specifically, when the cooker 100 is placed on the induction cooker 30, the assembly box 21 on the pan body 20 is matched with the adaptive part 31 on the induction cooker 30, specifically, the assembly box 21 on the pan body 20 is inserted and matched with the adaptive part 31 on the induction cooker 30, this has a positioning effect on the pot 100, especially when the number of the assembling boxes 21 is two, in this case, the number of the adapting parts 31 on the induction cooker 30 is two, thus, the pan body 20 and the induction cooker 30 realize better positioning effect through the two assembling boxes 21 and the adapting part 31, and the pan body 20 is prevented from rotating on the induction cooker 30, wherein, in the embodiment, because the connecting electrode 22 is arranged on the assembling box 21, therefore, when the induction electrode 32 of the induction cooker 30 is disposed on the adapting portion 31, the connection electrode 22 is in contact with the induction electrode 32 when the assembling box 21 is inserted into the adapting portion 31.

Wherein, in this embodiment, the control board can be disposed in the induction cooker 30, and the control board is connected to the induction electrode 32, so that the overflow prevention probe 23 and the temperature measuring assembly 24 are electrically connected with the control board in the induction cooker 30 through the contact between the connecting electrode 22 and the induction electrode 32, or, in this embodiment, control panels may be disposed on both the pan body 20 and the induction cooker 30, specifically, the control panels may include a first control panel and a second control panel, wherein, the first control board is arranged in the assembly box 21 and is connected with the connecting electrode 22, the anti-overflow probe 23, the temperature measuring component 24 and the pan body 20 are all electrically connected with the first control board, that is, the anti-overflow probe 23 and the temperature measuring component 24 are not directly connected to the connecting electrode 22, but are connected to the first control board, the second control board is disposed in the induction cooker 30 and is connected to the induction electrode 32, and the first control board and the second control board are electrically connected by the contact of the connecting electrode 22 and the induction electrode 32.

In this embodiment, signal transmission can be performed between the pot body 20 and the induction cooker 30 in a wireless manner, specifically, a wireless transmission module can be arranged in the assembly box 21, and the wireless transmission module is used for transmitting a conduction signal between the anti-overflow probe 23 and the pot body 20 and a temperature signal detected by the temperature measurement component 24 to the induction cooker 30, so that the induction cooker 30 controls a heating state according to the conduction signal and the temperature signal, wherein in this embodiment, when the wireless transmission module is set, specifically, the wireless transmission module can be set on the first control board, and the first control board controls the wireless transmission module to transmit a signal to the induction cooker 30.

Example two

Fig. 2A is a schematic view of a cross-sectional structure of an electromagnetic oven cooker provided by the second embodiment of the present invention, fig. 2B is a schematic view of a split structure of an electromagnetic oven cooker provided by the second embodiment of the present invention, and fig. 2C is a schematic view of an electromagnetic oven in an electromagnetic oven cooker provided by the second embodiment of the present invention.

The present embodiment provides an induction cooker 200, which includes an induction cooker 30 and any one of the cookers 100 described above, wherein the structure and the spill-proof process of the cooker 100 can specifically refer to the above embodiments, and details are not repeated in this embodiment.

In this embodiment, the induction electrode 32 contacting the connection electrode 22 on the pot body 20 is disposed on the induction cooker 30, the induction electrode 32 is electrically connected to the control board disposed in the induction cooker 30, and the anti-overflow electrode and the temperature measurement component 24 on the pot body 20 are electrically connected to the control board through the contact between the connection electrode 22 and the induction electrode 32.

Wherein, in this embodiment, be equipped with on the electromagnetism stove 30 with the assembly box 21 complex adaptation portion 31 that sets up on the pan 100, the cooperation of assembly box 21 and adaptation portion 31 makes pan 100 realize the location on electromagnetism stove 30, wherein, in this embodiment, the quantity of adaptation portion 31 can be two, assembly box 21 corresponds to set up two this moment, when pan 100 was placed on electromagnetism stove 30 and was heated like this, only when assembly box 21 was corresponding with adaptation portion 31, pan 100 could be placed on electromagnetism stove 30 accurately, pot body 20 has realized better positioning effect with electromagnetism stove 30 through two assembly boxes 21 and adaptation portion 31, and prevent that pot body 20 from rotating on electromagnetism stove 30, in this embodiment, assembly box 21 specifically fixes a position through the grafting cooperation mode with adaptation portion 31.

Wherein, in this embodiment, because the connection electrode 22 is established on the assembly box 21, in order to realize the contact of connection electrode 22 and induction electrode 32, in this embodiment, induction electrode 32 sets up on adaptation portion 31, specifically, induction electrode 32 sets up in adaptation portion 31 towards the one side of assembly box 21 and just to with connection electrode 22, like this, when pan 100 was placed on electromagnetism stove 30, assembly box 21 and adaptation portion 31 grafting cooperation, connection electrode 22 contacted with induction electrode 32 simultaneously, anti-overflow probe 23 and temperature measurement component 24 on pan 100 carried out signal transmission through induction electrode 32 and connection electrode 22 contact and the control panel in the electromagnetism stove 30.

In the present embodiment, the sensing electrodes 32 are specifically metal sheets, wherein when the number of the connecting electrodes 22 is three, the number of the sensing electrodes 32 is also three, that is, three metal sheets are disposed on one surface of the adapting portion 31 facing the assembling box 21, and the metal sheets are electrically connected to the control board in the induction cooker 30.

In this embodiment, the induction cooker 30 is specifically a square oven, or the induction cooker 30 is a round oven, wherein when the induction cooker 30 is a square oven or a round oven, the two adapting portions 31 are symmetrically disposed on the side wall of the induction cooker 30.

In this embodiment, the adapting portion 31 is specifically a protruding block protruding outward from the sidewall of the induction cooker 30, and two ends of the protruding block extend to the bottom surface of the bottom casing and the panel of the induction cooker 30, and when the induction cooker 30 is a circular cooker, the radian of the outer side surface of the adapting portion 31 is consistent with the radian of the circular sidewall of the induction cooker 30.

Wherein, in this embodiment, when the adapting portion 31 adapted to the assembling box 21 is disposed on the electromagnetic oven 30, the adapting portion 31 not only can position the assembling box 21 of the pot body 20, but also in this embodiment, the adapting portion 31 can be used as a handle of the electromagnetic oven 30, so that when a user carries or moves the electromagnetic oven 30, the user can directly hold the adapting portion 31 to move the electromagnetic oven 30, especially when the number of the adapting portions 31 is two, at this time, the adapting portions 31 are symmetrically disposed on the side wall of the electromagnetic oven 30, and the two adapting portions 31 can be used as two handles for the user to carry the electromagnetic oven 30, meanwhile, in this embodiment, when the adapting portions 31 are disposed on the side wall of the electromagnetic oven 30 in an extending manner, compared with the electromagnetic oven 30 without the adapting portions 31, the area of the electromagnetic oven 30 contacting with the working table is increased, so that the position of the electromagnetic oven 30 is more stable during the cooking process, is not easy to move. In addition, when the adapting portion 31 is arranged on the side wall of the electromagnetic oven 30, at this time, the area of the whole outer side wall of the electromagnetic oven 30 is increased, at this time, an operation area can be arranged on the outer side surface of the adapting portion 31, and an operation key or a display screen can be arranged on the operation area, wherein, in the embodiment, when the operation key or the display area is arranged on the adapting portion 31, the electromagnetic oven 30 avoids the operation area arranged on the panel of the electromagnetic oven 30, and only a heating area needs to be arranged on the panel of the electromagnetic oven 30, so that the size of the electromagnetic oven 30 is reduced, the weight is reduced, and the electromagnetic oven 30 tends to be light and thin.

In this embodiment, when the adapting portion 31 is disposed on the induction cooker 30, the adapting portion 31 and the sidewall of the induction cooker 30 may be fixed by welding, clamping, or fastening with a fastener, or in this embodiment, the adapting portion 31 may be integrally formed with a bottom case of the induction cooker 30.

In this embodiment, in order to control the heating state of the induction cooker, specifically, the electromagnetic cooker further includes a control board, the control board may be disposed in the induction cooker 30, and the control board is connected to the induction electrode 32, such that the anti-overflow probe 23 and the temperature measuring component 24 are in contact with the induction electrode 32 through the connection electrode 22 to be electrically connected to the control board in the induction cooker 30, or in this embodiment, the control board may be disposed on both the cooker body 20 and the induction cooker 30, specifically, the electromagnetic cooker further includes a first control board and a second control board, wherein the first control board is disposed in the assembly box 21 and connected to the connection electrode 22, the anti-overflow probe 23, the temperature measuring component 24 and the cooker body 20 are electrically connected to the first control board, that is, the anti-overflow probe 23 and the temperature measuring component 24 are not directly connected to the connection electrode 22 but connected to the first control board, the second control board is disposed in the induction cooker 30 and, the first control board and the second control board are electrically connected through the contact of the connecting electrode 22 and the induction electrode 32, or the first control board and the second control board transmit signals in a wireless mode, for example, a wireless transmission module is arranged on the first control board, correspondingly, a wireless receiving module is arranged on the second control board, and thus, the wireless transmission of signals is carried out between the pot body 20 and the induction cooker 30 through the wireless transmission module and the wireless receiving module.

In the description of the present invention, it is to be noted that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly and may include, for example, a fixed connection, an indirect connection via an intermediary, a connection between two elements, or an interaction between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. In the description of the present invention, "a plurality" means two or more unless specifically stated otherwise.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (14)

1. A pot, includes pot body (20) and pot cover (10), its characterized in that:

the anti-overflow pot is characterized in that an anti-overflow probe (23) which is insulated from the pot body (20) and electrically connected with the control board is arranged on the pot body (20), one end of the anti-overflow probe (23) extends into the pot body (20), the pot body (20) is electrically connected with the control board, and when soup overflowing from the pot body (20) contacts the anti-overflow probe (23), the pot body (20) is communicated with the anti-overflow probe (23) so that the control board controls the heating state of the induction cooker according to a communication signal;

and the distance between one end of the spill-proof probe (23) in the pot body (20) and the inner wall of the pot body (20) is 1-5 mm.

2. The pot as claimed in claim 1, wherein a metal region (11) insulated from the pot body (20) is provided on the pot cover (10), when the pot cover (10) is covered on the pot body (20), the metal region (11) is in contact with the overflow prevention probe (23), and when the soup overflowing in the pot body (20) contacts the metal region (11) or the overflow prevention probe (23), the pot body (20) is conducted with the overflow prevention probe (23).

3. The cookware according to claim 2, characterized in that the metal area (11) is an annular metal rim arranged along the outer edge of the lid (10).

4. The pot as claimed in any of claims 1 to 3, characterised in that the end of the spill-proof probe (23) inside the pot (20) is telescopic.

5. The pot as claimed in any of claims 1 to 3, characterized in that the distance between the spill-proof probe (23) and the rim of the pot (20) is 5-50 mm.

6. The pot as claimed in any one of claims 1 to 3, wherein the pot body (20) is provided with a hole (26) for the spill-proof probe (23) to extend into the pot body (20), and a sealing member is arranged between the spill-proof probe (23) and the hole (26).

7. The pot as claimed in any one of claims 1 to 3, further comprising: and the temperature measuring component (24) is electrically connected with the control board, and the temperature measuring component (24) is attached to the outer side wall of the pot body (20).

8. The cooker according to claim 7, characterized in that the outer side wall of the cooker body (20) is provided with an assembly box (21) which can cover the temperature measuring component (24) and can be provided with the anti-overflow probe (23).

9. The pot as claimed in claim 8, wherein the assembly box (21) is provided with a connection electrode (22) connected with the overflow prevention probe (23) and the temperature measurement component (24), and the connection electrode (22) is used for electrically connecting the overflow prevention probe (23), the temperature measurement component (24) and the pot body (20) with the control board arranged in the electromagnetic oven.

10. The pot according to claim 9, characterized in that the connection electrode (22) is telescopically arranged on the bottom end face of the assembly box (21), the overflow prevention probe (23) is telescopically arranged on the top end of the assembly box (21), and one end of the connection electrode (22) and one end of the overflow prevention probe (23) are both positioned in the assembly box (21).

11. The cooker according to claim 8, characterized in that a wireless transmission module is arranged in the assembly box (21), and the wireless transmission module is used for transmitting a conduction signal between the spill-proof probe (23) and the cooker body (20) and a temperature signal detected by the temperature measurement component (24) to the induction cooker, so that the induction cooker controls the heating state according to the conduction signal and the temperature signal.

12. An induction cooking appliance, characterized in that it comprises an induction cooking appliance (30) and a cookware according to any of the previous claims from 1 to 11.

13. The induction cooker according to claim 12, wherein the induction cooker is provided with an induction electrode (32) corresponding to the connection electrode (22) on the pot (100), and the spill-proof probe (23) and the temperature measurement component (24) on the pot (100) are electrically connected with the induction cooker through the contact between the induction electrode (32) and the connection electrode (22).

14. The induction cooker according to claim 13, wherein the induction cooker is provided with an adapter (31) which is engaged with a fitting box (21) of the pot (100) to position the pot (100) on the induction cooker, and the induction electrode (32) is provided on the adapter (31).

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