CN116817327B - Heating device, energy storage power supply, induction cooker and energy storage electric appliance - Google Patents

Abstract

This application discloses a heating device, an energy storage power supply, an induction cooker, and an energy storage appliance. The energy storage appliance includes a heating device and an energy storage power supply capable of charging and discharging. The heating device is equipped with mounting parts and electrical connectors, and is used for cooking food. The heating device is combined with the energy storage power supply, which is equipped with mounting parts and connecting parts. The mounting parts and mounting parts are magnetically attached to restrict relative movement between the heating device and the energy storage power supply along the mating surface. The electrical connectors are used to electrically connect with the connecting parts, allowing the energy storage power supply to power the heating device. When cooking is required, the heating device can be stably placed on the energy storage power supply, and the heating device and the energy storage power supply will not move relative to each other along the mating surface. Simultaneously, the energy storage power supply provides power to the heating device through the electrical connectors and connecting parts. Compared to existing energy storage appliances, the heating device and energy storage power supply in this application can be used in better coordination.

Description

Heating device, energy storage power supply, induction cooker and energy storage electric appliance

Technical Field

The application relates to the technical field of portable energy storage, in particular to a heating device, an energy storage power supply, an electromagnetic oven and an energy storage electric appliance.

Background

Outdoor camping is a life style which is emerging at present, and people usually take an outdoor energy storage power supply to supply power to electric appliances such as a heating device and the like when camping outdoors so as to cook and perform other activities. However, the current heating device cannot be well matched with an energy storage power supply.

Disclosure of Invention

The embodiment of the application provides a heating device, an energy storage power supply, an electromagnetic oven and an energy storage electric appliance, which are at least used for solving the problem that the heating device cannot be matched with the energy storage power supply well.

The energy storage electric appliance of the embodiment of the application comprises a heating device and an energy storage power supply capable of charging and discharging. The heating device is provided with an assembly part and an electric connecting piece and is used for cooking food. The heating device is combined with the energy storage power supply, the energy storage power supply is provided with a mounting part and an electric connection part, the mounting part is matched with the mounting part through magnetic attraction so as to limit the relative movement of the heating device and the energy storage power supply along a combining surface, and the electric connection part is used for being electrically connected with the electric connection part so that the energy storage power supply supplies power to the heating device.

In some embodiments, the fitting and the mounting removably connect the heating device to the stored energy power source by a magnetic attraction fit.

In certain embodiments, the heating device comprises first and second sides that are opposite, the energy storage power source comprises first and second sides that are opposite, the second side of the heating device is opposite to the second side of the energy storage power source, the fitting is disposed on the second side of the heating device, the fitting does not exceed the second side of the heating device, the mounting is disposed on the second side of the energy storage power source, and the mounting does not exceed the second side of the energy storage power source.

In certain embodiments, one of the fitting and the mount is a magnetic member and the other is a metal capable of being magnetized.

In certain embodiments, the fitting and the mounting are both magnetic.

In some embodiments, the fitting and the mounting are each block-shaped to form a point-fit magnetic attraction, and the energy storage appliance includes at least two magnetic attraction sites.

In some embodiments, at least one of the fitting and the mount is sheet-like to form a face-engaging magnetic attraction site.

In some embodiments, the heating device comprises a first side and a second side which are opposite, the energy storage power supply comprises a first side and a second side which are opposite, the second side of the heating device is opposite to the second side of the energy storage power supply, a positioning piece is arranged on the second side of the heating device, a limiting piece is arranged on the second side of the energy storage power supply, and the positioning piece is matched with the limiting piece to limit the assembly position of the heating device and the energy storage power supply.

In some embodiments, the positioning element is a protrusion and the limiting element is a groove.

In some embodiments, the positioning element is a groove and the limiting element is a protrusion.

In some embodiments, one of the positioning member and the spacing member is a magnetic member, and the other is a metal capable of being magnetized.

In certain embodiments, the positioning member and the spacing member are both magnetic members.

In some embodiments, one of the electrical connector and the electrical connector is a plug, and the other is an interface, and the plug is plugged into the interface to electrically connect the heating device and the energy storage power source.

In some embodiments, the electrical connection is a receiving coil, the electrical connection is a transmitting coil, and the transmitting coil and the receiving coil cooperate to cause the stored energy power source to power the heating device.

In some embodiments, the electrical connector is an electrical connection terminal and the electrical connector is an electrical connection terminal that contacts the electrical connection terminal to electrically connect the heating device with the stored energy power source.

In certain embodiments, at least one of the heating device and the stored energy power source is provided with a handle for a user to hold.

In some embodiments, at least one of the heating device and the energy storage power supply is provided with a heat dissipation member and/or a heat dissipation through hole communicated with the outside, the heat dissipation member is used for dissipating heat of the heating device and/or the energy storage power supply, and the heat dissipation through hole is used for transmitting heat to the outside.

In certain embodiments, the heating device comprises any one of an induction cooker, an electric rice cooker, an electric oven, an electric bakeware, and an electric fryer.

The heating device is used for cooking food and comprises an assembly part and an electric connecting piece. The assembly part is used for being in magnetic attraction fit with a mounting part of the energy storage power supply so as to limit the relative movement of the heating device and the energy storage power supply along the joint surface. The electric connecting piece is used for being electrically connected with the electric receiving piece of the energy storage power supply so that the energy storage power supply supplies power to the heating device.

The energy storage power supply of the embodiment of the application is used for charging and discharging and comprises a mounting piece and a power receiving piece. The mounting piece is used for being in magnetic attraction fit with the assembly part of the heating device so as to limit the relative movement of the heating device and the energy storage power supply along the joint surface. The power receiving piece is used for being electrically connected with the electric connecting piece of the heating device so that the energy storage power supply supplies power to the heating device.

The induction cooker of the embodiment of the application comprises an assembly part and an electric connecting piece. The assembly part is used for being matched with the installation part of the energy storage power supply in a clamping mode so as to limit the relative movement of the induction cooker and the energy storage power supply along the joint surface. The electric connecting piece is used for being electrically connected with the electric connecting piece of the energy storage power supply so that the energy storage power supply supplies power to the induction cooker.

In the heating device, the energy storage power supply, the electromagnetic oven and the energy storage electric appliance, the assembly part of the heating device is magnetically matched with the mounting part of the energy storage power supply, so that the heating device can be stably placed on the energy storage power supply under the condition that the heating device needs to cook, and the heating device and the energy storage power supply cannot move relatively along the joint surface. Meanwhile, under the condition that the heating device is placed on the energy storage power supply, the energy storage power supply is electrically connected with the electric connecting piece to supply power to the heating device. Compared with the existing energy storage electric appliance, the heating device and the energy storage power supply in the energy storage electric appliance can be matched with each other well.

Additional aspects and advantages of the application will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a schematic diagram of an energy storage appliance according to certain embodiments of the present application;

FIG. 2 is an exploded schematic view of the energy storage appliance of FIG. 1;

FIG. 3 is a schematic diagram of the connection of a heating device and an energy storage power source according to certain embodiments of the present application;

FIG. 4 is a schematic view of the heating device of FIG. 3;

Fig. 5 is a schematic view of a heating device and an energy storage power supply according to some embodiments of the present application, where a positioning member and a limiting member are provided.

Description of main reference numerals:

1000. an energy storage electrical appliance;

100. heating device, 10, first side of heating device, 20, second side of heating device, 30, assembly piece, 31, magnetic piece, 40, positioning piece, 50, electric connector, 60, handle, 70, heat dissipation piece, 80, heat dissipation through hole;

300. The device comprises an energy storage power supply 301, a first side of the energy storage power supply 302, a second side of the energy storage power supply 305, a mounting piece 307, a limiting piece 309 and an electric connection piece.

Detailed Description

Embodiments of the present application are described in detail below, and are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present application and are not to be construed as limiting the present application.

In the description of embodiments of the present application, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more of the described features. In the description of the embodiments of the present application, the meaning of "plurality" is two or more, unless explicitly defined otherwise.

Outdoor camping is a life style which is emerging at present, and people usually take an outdoor energy storage power supply to supply power to electric appliances such as a heating device and the like when camping outdoors so as to cook and perform other activities. However, the current heating device cannot be well matched with an energy storage power supply. To solve this problem, the present application provides a heating device 100, an energy storage power supply 300, an induction cooker and an energy storage electrical apparatus 1000 (shown in fig. 1).

Referring to fig. 1,3 and 4, an energy storage apparatus 1000 according to an embodiment of the application includes a heating device 100 and an energy storage power source 300 capable of charging and discharging. The heating device 100 is provided with a fitting 30 and an electrical connection 50, and the heating device 100 is used for cooking food. The heating device 100 is combined with the energy storage power supply 300, the energy storage power supply 300 is provided with a mounting piece 305 and an electric connection piece 309, the mounting piece 30 and the mounting piece 305 are matched through magnetic attraction so as to limit the relative movement of the heating device 100 and the energy storage power supply 300 along the combination surface, and the electric connection piece 50 is used for being electrically connected with the electric connection piece 309 so that the energy storage power supply 300 supplies power to the heating device 100. Wherein, the heating device 100 comprises any one of an induction cooker, an electric oven, an electric baking tray and an electric frying pan. The heating device 100 according to the embodiment of the present application is an induction cooker.

When the heating device 100 is connected to the energy storage power supply 300, the fitting 30 and the mount 305 magnetically attract each other. In the case where the heating device 100 and the energy storage power supply 300 need to be separated, an external force greater than the attractive magnetic force is applied to the heating device 100 and the energy storage power supply 300 to separate the heating device 100 and the energy storage power supply 300.

In the energy storage electrical apparatus 1000 of the present application, the assembly part 30 of the heating device 100 is magnetically matched with the mounting part 305 of the energy storage power supply 300, so that the heating device 100 can be stably placed on the energy storage power supply 300 under the condition that the heating device 100 needs to cook, and the heating device 100 and the energy storage power supply 300 cannot relatively move along the joint surface. Meanwhile, in case the heating device 100 is placed on the energy storage power source 300, the energy storage power source 300 is electrically connected to the power receiving member 309 through the electrical connection member 50 to supply power to the heating device 100. Compared with the existing energy storage electric appliance, the heating device 100 and the energy storage power supply 300 in the energy storage electric appliance 1000 of the application can be better matched with each other.

The energy storage device 1000 is further described below with reference to the accompanying drawings.

Referring to fig. 3, the assembly 30 and the mounting member 305 detachably connect the heating device 100 to the stored energy power source 300 through a magnetic attraction fit.

Referring to fig. 2, in some embodiments, the heating device 100 includes a first side 10 and a second side 20 opposite each other, the stored energy power source 300 includes a first side 301 and a second side 302 opposite each other, and the second side 20 of the heating device 100 is opposite the second side 302 of the stored energy power source 300. In the case where the heating device 100 is combined with the energy storage power supply 300, the combining surface is an abutting surface of the second side 20 of the heating device 100 and the second side 302 of the energy storage power supply 300.

Referring to fig. 3, in some embodiments, the assembly 30 is disposed on the second side 20 of the heating device 100, the assembly 30 does not extend beyond the second side 20 of the heating device 100, the mounting member 305 is disposed on the second side 302 of the stored energy power source 300, and the mounting member 305 does not extend beyond the second side 302 of the stored energy power source 300.

Specifically, the second side 20 of the heating device 100 may be provided with a loading slot for loading the fitting 30 therein, the loading slot having a depth greater than or equal to the thickness of the fitting 30 such that the fitting 30 does not protrude beyond the second side 20 of the heating device 100 after installation. The second side 302 of the energy storage power source 300 may be provided with a mounting groove, in which the mounting member 305 is mounted, and the depth of the mounting groove is greater than or equal to the thickness of the mounting member 305, so that the mounting member 305 does not exceed the second side 302 of the energy storage power source 300 after being mounted, and the second side 20 of the heating device 100 and the second side 302 of the energy storage power source 300 are attached under the condition that the heating device 100 and the energy storage power source 300 are connected, so that the connection between the heating device 100 and the energy storage power source 300 is more stable.

The fitting 30 may be mounted in the loading slot by dispensing, welding or interference fit, and the cross-sectional shape of the fitting 30 may be, but is not limited to, circular, oval, rectangular or other polygonal, etc., and the opening shape of the loading slot may or may not correspond to the cross-sectional shape of the fitting 30, so long as the fitting 30 is capable of being fixedly mounted in the loading slot.

The mounting member 305 may be mounted in the mounting groove by dispensing, welding or interference fit, and the cross-sectional shape of the mounting member 305 may be, but is not limited to, circular, elliptical, rectangular, or other polygonal shape, and the mounting groove may be formed in a shape corresponding to or not corresponding to the cross-sectional shape of the mounting member 305, so long as the mounting member 305 can be fixedly mounted in the mounting groove.

The assembly 30 may also be disposed on a side wall of the heating device 100, and the assembly 30 may be mounted on a side wall of the heating device 100 adjacent to the second side 20 by dispensing or welding. The mounting member 305 is also disposed on a side wall of the energy storage power source 300, and the mounting member 305 is mounted on a side wall of the energy storage power source 300, which is close to the second side 20, by dispensing or welding, so that the assembly member 30 and the mounting member 305 can magnetically attract each other when the heating device 100 is connected to the energy storage power source 300.

With continued reference to fig. 3, in one embodiment, one of the fitting 30 and the mounting member 305 is a magnetic member 31, and the other is a metal capable of being magnetized. The magnetic member 31 may be a magnet or other magnetic object, and the metal capable of being magnetized may be iron, cobalt, nickel, or the like. In one example, the fitting 30 is a magnetic member 31 and the mounting member 305 is a metal capable of being magnetized. In another example, the fitting 30 is a metal capable of being magnetized and the mounting member 305 is a magnetic member 31.

In another embodiment, both the fitting 30 and the mounting 305 are magnetic members 31. In one example, the S-pole of the fitting 30 faces the second side 302 of the stored energy power source 300 and the N-pole of the mount 305 faces the second side 20 of the heating device 100. When the heating device 100 is connected to the energy storage power supply 300, the S pole of the fitting 30 and the N pole of the mount 305 attract each other. In another example, the N-pole of the fitting 30 faces the second side 302 of the stored energy power source 300 and the S-pole of the mount 305 faces the second side 20 of the heating device 100. When the heating device 100 is connected to the energy storage power supply 300, the N pole of the fitting 30 and the S pole of the mount 305 attract each other.

In one embodiment, the fitting 30 and the mounting 305 are each block-shaped to form a point-fit magnetic attraction, and the energy storage appliance 1000 includes at least two magnetic attraction sites. The number of fittings 30 may be, but is not limited to, two, three, four or more, with the number of mounts 305 being the same as the number of fittings 30. The cross-sectional shapes of the plurality of fittings 30 may be the same or different, and the cross-sectional shape of the fitting 30 is the same as the cross-sectional shape of the corresponding mount 305. In one example, the number of fittings 30 is two and the number of mounts 305 is two. Preferably, the two mounting members 30 are respectively located at two opposite sides of the second side 20 of the heating device 100, or the two mounting members 30 are respectively located at two opposite corners of the second side 20 of the heating device 100, and the positions of the mounting members 305 correspond to the positions of the mounting members 30, so that the heating device 100 is more stressed when being connected to the energy storage power supply 300. In another example, the number of fittings 30 is three and the number of mounts 305 is three. The three fitting parts 30 are uniformly or non-uniformly distributed on the second side 20 of the heating device 100, preferably, the three fitting parts 30 are uniformly distributed on the second side 20 of the heating device 100, so that the stress is more uniform when the heating device 100 is connected to the energy storage power supply 300.

Referring to fig. 4, in another embodiment, at least one of the fitting 30 and the mounting member 305 is sheet-like to form a face-engaging magnetic attraction site. In one example, the fitting 30 is sheet-like and the mounting 305 is block-like. The sheet-like fitting 30 covers at least one half of the area of the second side 20 of the heating device 100. In the case where the fitting 30 is sheet-shaped, the fitting 30 may be a magnetic member 31 or a metal that can be magnetized. In the case where the mount 30 is a sheet-like magnetic member 31, the mount 305 may be a block-like magnetic member 31 or a block-like magnetizable metal. In the case where the mount 30 is a sheet-like magnetizable metal, the mount 305 is a block-like magnetic member 31. In this case, the number of the mounting members 305 may be one or more, and in the case that the number of the mounting members 305 is more than one, the connection between the heating device 100 and the energy storage power source 300 is more stable.

In another example, the fitting 30 is block-shaped and the mounting member 305 is sheet-shaped. The sheet-like mounting member 305 covers at least one half of the area of the second side 302 of the stored energy power source 300. In the case where the mount 305 is sheet-shaped, the mount 305 may be the magnetic member 31 or may be a metal capable of being magnetized. In the case where the mounting member 305 is a sheet-like magnetic member 31, the mount member 30 may be a block-like magnetic member 31 or a block-like magnetizable metal. In the case where the mount 305 is a sheet-like magnetizable metal, the mount 30 is a block-like magnetic member 31. In this case, the number of the assemblies 30 may be one or more, and in the case that the number of the assemblies 30 is plural, the connection between the heating device 100 and the energy storage power source 300 is more stable.

In yet another example, the fitting 30 is sheet-like and the mounting member 305 is sheet-like. The sheet-like fitting 30 covers at least one half of the area of the second side 20 of the heating device 100. The sheet-like mounting member 305 covers at least one half of the area of the second side 302 of the stored energy power source 300. In the case where the mount 30 is the magnetic member 31, the mount 305 may be the magnetic member 31 or may be a metal capable of being magnetized. In the case where the mount 30 is a metal capable of being magnetized, the mount 305 is the magnetic member 31.

Preferably, the fitting 30 is a plurality of block-shaped magnetic members 31, and the mounting member 305 is a sheet-shaped metal capable of being magnetized. At this time, the cost of the magnetic member 31 is low. And in case the mounting member 305 of the second side 302 of the stored energy power source 300 is a sheet-like magnetizable metal, the second side 20 of the heating device 100 is provided with a block-like fitting 30 which can be adapted to a plurality of stored energy power sources 300 of different dimensions.

Referring to fig. 5, in some embodiments, the second side 20 of the heating device 100 is provided with a positioning member 40, the second side 302 of the energy storage power source 300 is provided with a limiting member 307, and the positioning member 40 cooperates with the limiting member 307 to define the assembly position of the heating device 100 and the energy storage power source 300.

The positioning members 40 and the fitting 30 may be disposed at intervals, and the number of the positioning members 40 may be one or more. The limiting members 307 and the mounting members 305 may be disposed at intervals, and the number of the limiting members 307 is the same as the number of the positioning members 40. In one embodiment, the number of positioning members 40 is one, and the positioning members 40 may be disposed at any location on the second side 20 of the heating device 100 other than the fitting 30. The number of the stoppers 307 is also one, and the position of the stopper 307 corresponds to the position of the positioning member 40. At this time, the number of the positioning members 40 and the limiting members 307 is small, the cost can be saved, and the overall weight of the structure is light. In another embodiment, the number of positioning members 40 is plural, and the plurality of positioning members 40 may be uniformly or non-uniformly distributed at any location on the second side 20 of the heating device 100 other than the fitting 30. The number of the stoppers 307 is also plural, and the positions of the stoppers 307 correspond to the positions of the positioning members 40. At this time, the heating device 100 and the energy storage power source 300 are positioned more accurately and connected more firmly.

In one embodiment, the positioning member 40 is a protrusion and the limiting member 307 is a recess. The cross-sectional shape of the positioning member 40 may be, but is not limited to, circular, elliptical, rectangular, or other polygonal shape, etc., and the cross-sectional shape of the stopper 307 corresponds to the cross-sectional shape of the positioning member 40 so that the positioning member 40 and the stopper 307 can be stably engaged. The positioning member 40 and the heating device 100 may be integrally or separately configured. In the case where the positioning member 40 and the heating device 100 are of unitary construction, the positioning member 40 extends from the second side 20 of the heating device 100. In the case where the positioning member 40 and the heating device 100 are of a separate structure, the positioning member 40 may be detachably or non-detachably connected to the second side 20 of the heating device 100. Wherein the detachable mounting mode comprises, but is not limited to, threaded connection, screw connection or buckle connection. Non-removable mounting means include, but are not limited to, welding, glue connection, interference fit, or the like.

In another embodiment, the positioning member 40 is a groove and the limiting member 307 is a protrusion. The cross-sectional shape of the stopper 307 may be, but is not limited to, circular, elliptical, rectangular, or other polygonal shape, etc., and the cross-sectional shape of the positioning member 40 corresponds to the cross-sectional shape of the positioning member 40 so that the positioning member 40 and the stopper 307 can be stably engaged. The limiting member 307 and the energy storage power supply 300 may be in an integral structure or a split structure. In the case where the stopper 307 and the stored energy power supply 300 are integrally formed, the stopper 307 extends from the second side 302 of the stored energy power supply 300. In the case that the stopper 307 and the stored power supply 300 are of a separate structure, the stopper 307 may be detachably or non-detachably connected to the second side 302 of the stored power supply 300. Wherein the detachable mounting mode comprises, but is not limited to, threaded connection, screw connection or buckle connection. Non-removable mounting means include, but are not limited to, welding, glue connection, interference fit, or the like.

In yet another embodiment, one of the positioning member 40 and the stopper 307 is a magnetic member, and the other is a metal capable of being magnetized. The cross-sectional shape of the positioning member 40 may be, but is not limited to, circular, elliptical, rectangular, or other polygonal, etc., and the cross-sectional shape of the stopper 307 corresponds to the cross-sectional shape of the positioning member 40. In one example, the positioning member 40 is a magnetic member, and the stopper 307 is a metal that can be magnetized. The metal capable of being magnetized can be iron, cobalt, nickel and other metals. In another example, the positioning member 40 is a metal that can be magnetized, and the stopper 307 is a magnetic member.

In yet another embodiment, the positioning member 40 and the limiting member 307 are both magnetic members. In one example, the S pole of the positioning member 40 faces the second side 302 of the energy storage power source 300, and the N pole of the limiting member 307 faces the second side of the heating device 100. When the heating device 100 is connected to the energy storage power supply 300, the S pole of the positioning member 40 and the N pole of the stopper 307 attract each other. In another example, the N pole of the positioning member 40 faces the second side 302 of the energy storage power source 300, and the S pole of the limiting member 307 faces the second side of the heating device 100. When the heating device 100 is connected to the energy storage power supply 300, the N pole of the positioning member 40 and the S pole of the stopper 307 attract each other.

Referring to fig. 2 and 4, in one embodiment, one of the electrical connector 50 and the electrical connector 309 is a plug, and the other is an interface, and the plug and the interface are plugged to electrically connect the heating device 100 and the energy storage power source 300. In one example, electrical connector 50 is a plug with wires and electrical connector 309 is an interface. The heating device 100 may be provided with a receiving groove for receiving the plug and the wire, so that the heating device 100 is tidy and has a higher integration level. When the heating device 100 is not in operation, the plug is accommodated in the accommodation groove. In the case that the heating device 100 is connected with the energy storage power supply 300 and the heating device 100 needs to work, the plug extends out of the accommodating groove to be spliced with the interface. In another example, electrical connector 50 is an interface and electrical connector 309 is a plug with wires. The energy storage power supply 300 may be provided with a receiving groove for receiving the plug and the wire, so that the energy storage power supply 300 is tidy. When the heating device 100 is not in operation, the plug is accommodated in the accommodation groove. In the case that the heating device 100 is connected with the energy storage power supply 300 and the heating device 100 needs to work, the plug extends out of the accommodating groove to be spliced with the interface.

In another embodiment, the electrical connection 50 is a receiving coil, the electrical connection 309 is a transmitting coil, and the transmitting coil and the receiving coil cooperate to enable the stored energy power source 300 to power the heating device 100. The electrical connector 50 may be disposed on the second side 20 of the heating device 100 and the electrical connector 309 may be disposed on the second side 302 of the stored energy power source 300. In the case where the heating device 100 is not connected to the energy storage power supply 300, the transmitting coil fails to detect the receiving coil, and the energy storage power supply 300 does not supply power to the heating device 100 at this time. In the case where the heating device 100 is connected to the energy storage power supply 300, the transmitting coil can detect the receiving coil, so that the energy storage power supply 300 supplies power to the heating device 100.

In yet another embodiment, the electrical connector 50 is an electrical connection terminal and the electrical connector 309 is an electrical connection terminal, the electrical connection terminal being in contact with the electrical connection terminal to electrically connect the heating device 100 with the stored energy power source 300. In one example, the electrical connector 50 is disposed on the second side 20 of the heating device 100, and the electrical connector 309 is also disposed on the second side 302 of the energy storage power source 300, where the electrical connector 50 corresponds to the position of the electrical connector 309. In another example, the electrical connector 50 is disposed on the sidewall 304 of the heating device 100, and the electrical connector 309 is also disposed on the sidewall 304 of the energy storage power source 300, where the electrical connector 50 corresponds to the position of the electrical connector 309. In the case where the heating device 100 is not connected to the energy storage power supply 300, the electrical connection terminal is not in contact with the electrical connection terminal, and the energy storage power supply 300 does not supply power to the heating device 100 at this time. In the case where the heating device 100 is connected to the energy storage power supply 300, the electrical connection terminal is in contact with the electrical connection terminal, so that the energy storage power supply 300 supplies power to the heating device 100.

Referring to fig. 4, in some embodiments, at least one of the heating device 100 and the stored energy power source 300 is provided with a handle 60, the handle 60 being for a user to hold. In one embodiment, the heating device 100 is provided with a handle 60, the handle 60 being provided at a side wall 304 of the heating device 100. The number of handles 60 may be one or two, and in the case where the number of handles 60 is one, the handles 60 are provided on any one of the side walls 304 of the heating device 100. In the case where there are two handles 60, the two handles 60 are provided on the opposite side walls 304 of the heating device 100, respectively. In another embodiment, the stored energy power source 300 is provided with a handle 60, the handle 60 being provided at a side wall 304 of the stored energy power source 300. The number of handles 60 may be one or two, and in the case where the number of handles 60 is one, the handles 60 are provided on any one side wall 304 of the stored energy power source 300. In the case where there are two handles 60, the two handles 60 are provided on the opposite side walls 304 of the stored energy power supply 300, respectively. In yet another embodiment, the heating device 100 and the stored energy power source 300 are each provided with a handle 60 to facilitate the handling of the heating device 100 and the stored energy power source 300.

Referring to fig. 2 and 4, in some embodiments, at least one of the heating device 100 and the energy storage power supply 300 is provided with a heat dissipation member 70 and/or a heat dissipation through hole 80 in communication with the outside, the heat dissipation member 70 is used for dissipating heat from the heating device 100 and/or the energy storage power supply 300, and the heat dissipation through hole 80 is used for transmitting heat to the outside.

In one embodiment, the heating device 100 is provided with a heat sink 70. The heat sink 70 may be, but is not limited to, a fan, a blower, a heat conducting member, a heat sink, etc. In another embodiment, the heating device 100 is provided with a heat sink 70 and a heat dissipation through hole 80. The heat dissipation through holes 80 are formed in the side wall 304 of the heating device 100, and the heat dissipation through holes 80 may be formed in a circular shape, an elliptical shape, a rectangular shape, or other polygonal shapes, and the number of the heat dissipation through holes 80 may be one or more. In yet another embodiment, the stored energy power source 300 is provided with a heat sink 70. In yet another embodiment, the energy storage power supply 300 is provided with a heat sink 70 and a heat dissipation through hole 80. The heat dissipation through holes 80 are formed in the side wall 304 of the energy storage power supply 300, and the heat dissipation through holes 80 may be formed in a circular shape, an elliptical shape, a rectangular shape, or other polygonal shapes, and the number of the heat dissipation through holes 80 may be one or more. In yet another embodiment, both the heating device 100 and the stored energy power source 300 are provided with a heat sink 70. The heat sink 70 of the heating device 100 and the heat sink 70 of the energy storage power supply 300 may be the same or different. In still another embodiment, the heating device 100 and the energy storage power supply 300 are provided with the heat sink 70 and the heat dissipation through hole 80. The opening shape of the heat dissipation through hole 80 of the heating device 100 may be the same or different from the opening shape of the heat dissipation through hole 80 of the energy storage power supply 300.

In the energy storage electrical apparatus 1000 of the present application, the assembly part 30 of the heating device 100 is magnetically matched with the mounting part 305 of the energy storage power supply 300, so that the heating device 100 can be stably placed on the energy storage power supply 300 under the condition that the heating device 100 needs to cook, and the heating device 100 and the energy storage power supply 300 cannot relatively move along the joint surface. Meanwhile, in case the heating device 100 is placed on the energy storage power source 300, the energy storage power source 300 is electrically connected to the power receiving member 309 through the electrical connection member 50 to supply power to the heating device 100. Compared with the existing energy storage electric appliance, the heating device 100 and the energy storage power supply 300 in the energy storage electric appliance 1000 of the application can be better matched with each other.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description. Also, other implementations may be derived from the above-described embodiments, such that structural and logical substitutions and changes may be made without departing from the scope of this disclosure.

The above examples merely represent a few embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the patent. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (12)

1. An energy storage electrical appliance, characterized in that it comprises: A heating device, comprising fittings and electrical connections, for cooking food, comprising a first side and a second side opposite to each other; and A charging and discharging energy storage power supply is provided. A heating device is integrated with the energy storage power supply. The energy storage power supply has a mounting component and a connecting component. The mounting component and the mounting component are magnetically engaged to restrict relative movement between the heating device and the energy storage power supply along their mating surfaces. An electrical connector is used to electrically connect with the connecting component to allow the energy storage power supply to power the heating device. The energy storage power supply includes a first side and a second side facing away from each other. The second side of the energy storage power supply and the second side of the heating device are opposite each other. Both the mounting component and the mounting component are sheet-like to form a magnetically engaged surface. The sheet-like mounting component covers at least half the area of the second side of the heating device, and the sheet-like mounting component covers at least half the area of the second side of the energy storage power supply. The periphery of the mounting component and the periphery of the first side of the heating device form an annular region. The electrical connector is a receiving coil, and the connecting component is a transmitting coil. The transmitting coil and the receiving coil cooperate to allow the energy storage power supply to power the heating device. 2. The energy storage appliance according to claim 1, wherein the assembly and the mounting component are magnetically connected to the heating device and the energy storage power supply in a detachable manner. 3. The energy storage appliance according to claim 1, wherein the assembly is disposed on the second side of the heating device and does not extend beyond the second side of the heating device, and the mounting component is disposed on the second side of the energy storage power supply and does not extend beyond the second side of the energy storage power supply. 4. The energy storage device according to claim 1, characterized in that one of the assembly and the mounting component is a magnetic component, and the other is a metal capable of being magnetized; or Both the mounting accessories and the mounting components are magnetic. 5. The energy storage electrical appliance according to any one of claims 1-4, characterized in that, The heating device is provided with a positioning member on its second side, and the energy storage power supply is provided with a limiting member on its second side. The positioning member and the limiting member cooperate to limit the assembly position of the heating device and the energy storage power supply. 6. The energy storage device according to claim 5, characterized in that, The positioning element is a protrusion, and the limiting element is a groove; or The positioning element is a groove, and the limiting element is a protrusion; or One of the positioning element and the limiting element is a magnetic element, and the other is a metal that can be magnetized; or Both the positioning element and the limiting element are magnetic. 7. The energy storage appliance according to any one of claims 1-4, characterized in that at least one of the heating device and the energy storage power supply is provided with a handle, the handle being for a user to hold. 8. The energy storage device according to any one of claims 1-4, characterized in that at least one of the heating device and the energy storage power supply is provided with a heat dissipation component and/or a heat dissipation through hole communicating with the outside, the heat dissipation component is used to dissipate heat from the heating device and/or the energy storage power supply, and the heat dissipation through hole is used to transfer heat to the outside. 9. The energy storage appliance according to claim 1, wherein the heating device comprises any one of an induction cooker, a rice cooker, an electric oven, an electric baking pan, and an electric fryer. 10. A heating device for cooking food, characterized in that the heating device comprises: The first and second sides are opposite to each other. The second side of the heating device and the second side of the energy storage power supply are opposite to each other. The energy storage power supply is provided with a mounting component and a power connection component. The mounting component is plate-shaped and the plate-shaped mounting component covers at least half of the area of the second side of the energy storage power supply. An assembly, wherein the assembly is used to magnetically engage with the mounting component of the energy storage power source to restrict relative movement between the heating device and the energy storage power source along the mating surface, the assembly being sheet-shaped and covering at least half of the area of the second side of the heating device; and An electrical connector is provided for electrical connection with a power supply component of the energy storage power source, so that the energy storage power source supplies power to the heating device. The electrical connector is a receiving coil, and the power supply component is a transmitting coil. The transmitting coil and the receiving coil cooperate to enable the energy storage power source to supply power to the heating device. 11. An energy storage power source for charging and discharging, characterized in that the energy storage power source comprises: The first and second sides are opposite to each other, the second side of the energy storage power supply and the second side of the heating device are opposite to each other, and the heating device is provided with mounting parts and electrical connectors; The mounting component is used to magnetically engage with the mounting part of the heating device to restrict relative movement between the heating device and the energy storage power source along the mating surface. The mounting part is sheet-shaped, and the sheet-shaped mounting part covers at least half of the area of the second side of the heating device. An electrical connector is provided, which is used to electrically connect with the electrical connector of the heating device so that the energy storage power supply supplies power to the heating device. The electrical connector is a receiving coil, and the electrical connector is a transmitting coil. The transmitting coil and the receiving coil cooperate to enable the energy storage power supply to supply power to the heating device. 12. An induction cooker, characterized in that the induction cooker comprises: The first and second sides are opposite to each other. The second side of the induction cooker and the second side of the energy storage power supply are opposite to each other. The energy storage power supply is provided with a mounting component and a power connection component. The mounting component is plate-shaped and the plate-shaped mounting component covers at least half of the area of the second side of the energy storage power supply. An assembly, wherein the assembly is used to engage with the mounting component of the energy storage power supply to restrict relative movement between the induction cooker and the energy storage power supply along the mating surface, the assembly being sheet-shaped and covering at least half of the area of the second side of the induction cooker; and An electrical connector is provided, which is used to electrically connect with the power supply of the energy storage power source so that the energy storage power source supplies power to the induction cooker. The electrical connector is a receiving coil, and the power supply is a transmitting coil. The transmitting coil and the receiving coil cooperate to enable the energy storage power source to supply power to the induction cooker.