CN218942838U - Cooking utensil capable of rapidly discharging steam - Google Patents

Abstract

The utility model discloses a cooking utensil capable of rapidly discharging steam, belongs to the technical field of food processing, and aims to overcome the defect of low steam generation efficiency of an existing steamer. The cooking utensil comprises a pot body, wherein the pot body comprises an inner pot; the inner pot is provided with a steam generating part, the steam generating part comprises a separating ring and a heating plate, and the separating ring separates a steam generating cavity in the water containing cavity; a water draining part is arranged in the steam generating cavity to form two steam generating areas with different liquid heights in the steam generating cavity; a low water level steam generating area is arranged between the heating plate and the water draining part, and a high water level steam generating area is formed between the water draining part and the separating ring. The water draining part makes the water level between the heating plate and the water draining part lower, and this can raise the steam producing speed between the heating plate and the water draining part, raise the heating speed of water in the high water level steam producing area and raise steam producing efficiency.

Description

Cooking utensil capable of rapidly discharging steam

Technical Field

The utility model belongs to the technical field of food processing, and relates to a cooking utensil capable of rapidly discharging steam.

Background

Traditional steamer includes steaming rack and interior pot, and steaming rack is arranged in interior pot, and food is placed on steaming rack, holds water in the interior pot, heats the water in the interior pot through the heating plate and produces steam, cooks the food in the steaming rack through steam. The inner pot is provided with a water containing cavity, the heating disc is positioned at the bottom of the water containing cavity, and the heating disc heats large-scale water in the water containing cavity, so that the heating efficiency is lower.

In the prior art, as disclosed in CN201020263419.3, an electric steamer capable of rapidly generating steam, a steam shield has a double-layer structure with an outer side wall and an inner side wall, and a region between the outer side wall and the inner side wall is arranged corresponding to an electric heating tube; but the steam generation speed is still slow in operation, and there is room for further improvement.

Disclosure of Invention

The utility model provides a cooking utensil capable of rapidly discharging steam aiming at the problems in the prior art, and aims to overcome the defect of low steam generation efficiency of the existing steamer.

The utility model is realized in the following way:

the cooking utensil capable of rapidly discharging steam comprises a pot body, wherein the pot body comprises an inner pot with a water containing cavity; the inner pot is provided with a steam generating part, the steam generating part comprises a separation ring and a heating disc arranged in the separation ring, the separation ring at least separates a steam generating cavity in the water containing cavity, and the heating disc is positioned at the bottom of the steam generating cavity;

a water draining part is arranged in the steam generating cavity so as to form two steam generating areas with different liquid heights in the steam generating cavity;

a low water level steam generating area is arranged between the heating plate and the water draining part, and a high water level steam generating area is formed between the water draining part and the separating ring.

When in steam cooking, food is placed on the steaming rack, a proper amount of water is filled in the water containing cavity of the pot body, the heating plate works to heat the water in the water containing cavity to generate steam, and the steam enters the steaming rack to cook the food in the steaming rack.

The separating ring separates the water containing cavity from the steam generating cavity, the heating disc is arranged in the separating ring, namely, the heating disc is arranged corresponding to the steam generating cavity, the heating disc is used for intensively heating water in the steam generating cavity in a targeted manner, so that the water in the steam generating cavity is heated preferentially, the heating disc is prevented from directly heating the water in the whole water containing cavity, the heating disc with the same power is used for heating less water, the heating speed of the water in the steam generating cavity is improved, and the speed of steam generation is improved.

The steam generation cavity is internally provided with the water discharge part, so that the steam generation cavity forms a low water level steam generation area and a high water level steam generation area, the water discharge part can further reduce the volume of the steam generation cavity, thereby reducing the water quantity in the steam generation cavity and further improving the steam generation speed in the steam generation cavity. The water draining part makes the water level between the heating plate and the water draining part lower, so that the steam generating speed between the heating plate and the water draining part can be increased, the heating speed of water in the high water level steam generating area is increased, and the steam generating efficiency is improved.

Preferably, the water holding cavity is further provided with a cavity to be heated and a heat preservation cavity, the separation ring is provided with an overflow gap to be communicated with the heat preservation cavity and the steam generation cavity, and the separation ring is provided with a water passing channel to be communicated with the steam generation cavity and the cavity to be heated.

The separating ring separates the water containing cavity into the steam generating cavity and the cavity to be heated, water in the steam generating cavity is heated before water in the cavity to be heated, after the water quantity in the steam generating cavity is reduced due to steam generation, water in the cavity to be heated flows to the steam generating cavity through the water passing channel to supplement the water quantity in the steam generating cavity, and the steam generating cavity is ensured to have more sufficient water quantity for cooking.

The heat preservation chamber is located the spacer ring specifically, and the heat in heat preservation chamber can the better separation steam generation chamber passes through the spacer ring and gives to wait the heat chamber, reduces the heat in the steam generation chamber and to wait the heat chamber and scatter and disappear. The hot water in the steam generation cavity can flow into the heat preservation cavity through the overflow gap, so that the temperature difference between the heat preservation cavity and the steam generation cavity is reduced rapidly, the heat conducted from the steam generation cavity to the cavity to be heated is reduced, and the heat dissipation in the steam generation cavity is further reduced. The heating rate of water in the steam generation cavity is further improved, the efficiency of steam generation is accelerated, the steam quantity in the steam rack is increased, and the steam can be enabled to be more fully contacted with each part of food, so that the cooking speed is improved, the waiting time of a user is reduced, the user experience is improved, and the uniformity of heating of the food is also improved.

Preferably, the separation ring comprises a first separation wall positioned between the heat preservation chamber and the steam generation chamber, and the overflow gap is positioned at the upper end of the first separation wall. The higher overflow gap can reduce or avoid the water in the heat preservation cavity from flowing back to the steam generation cavity to reduce the water temperature of the steam generation cavity, thereby being beneficial to improving the steam generation speed.

Preferably, the separation ring comprises a second separation wall positioned between the heat preservation cavity and the cavity to be heated, and the second separation wall is sealed to prevent water in the cavity to be heated from entering the heat preservation cavity; therefore, cold water in the cavity to be heated can be prevented from entering the heat preservation cavity, and the water in the heat preservation cavity is kept in a higher temperature state.

Or a second partition wall is arranged between the heat preservation cavity and the cavity to be heated, a water outlet is arranged at the upper end part of the second partition wall, and the position of the water outlet is lower than the overflow gap. The water outlet is positioned at the upper end part of the second partition wall and is higher, so that the water outlet can be positioned above the water level line of the cavity to be heated, cold water in the cavity to be heated cannot upwelle and enter the heat preservation cavity from the water outlet, and cold water in the cavity to be heated is prevented from entering the heat preservation cavity from the water outlet and entering the heat preservation cavity. The heat preservation chamber is surging into from the overflow clearance to steam generation chamber hot water, because the water in the heat preservation chamber is influenced by waiting the heat chamber, its temperature can be less than the water in steam generation chamber, when the water level in the heat preservation chamber reaches the height of delivery port, the water in the heat preservation chamber just can follow the delivery port and flow to waiting the heat chamber, avoid the water in the heat preservation chamber to flow back to the steam generation chamber from the overflow clearance and reduce the temperature of steam generation intracavity water, also avoid the water blocking in heat preservation chamber to lead to the water in the steam generation chamber to be difficult to get into the heat preservation chamber at the overflow clearance, guarantee that the heat preservation chamber is continuous to have hot water to get into, thereby improve the heat preservation effect.

Preferably, the inner pot is internally provided with an energy gathering piece and a steaming rack, the water draining part is positioned on the energy gathering piece, the separation ring comprises a first separation wall and a heat insulation bottom wall which are integrally connected to the energy gathering piece, and a second separation wall which is integrally connected to the steaming rack, and the lower end of the second separation wall is abutted to the heat insulation bottom wall; the heat preservation chamber is formed by assembling and enclosing the energy gathering piece and the local structure of the steaming rack, so that the processing and production of the separation ring are facilitated, and the processing difficulty is reduced.

The first partition wall and the steam rack are provided with a gap to form the overflow gap, so that the overflow gap is not required to be processed on the first partition wall, the overflow gap is naturally formed by assembling the steam rack and the energy collecting piece, the processing steps are reduced, and the production efficiency is improved. Or the first partition wall is provided with a through hole so as to form the overflow gap.

Preferably, the energy collecting piece comprises a top wall connected with the first partition wall and the water draining part, the top wall is higher than the heat insulation bottom wall, the top wall is provided with a water passing through hole, the water draining part is provided with a convex wall extending upwards relative to the top wall, and the convex wall is abutted to the bottom of the steam rack. Steam in the steam generation cavity can further get into the steaming rack after passing through the water through hole, and when water boiling in the steam generation cavity upwards gushes out, partial water can get into the heat preservation cavity from the overflow clearance, and the convex wall can block water to gush into the drainage cavity, avoids drainage cavity ponding, avoids the waste of water.

Preferably, the heating plate comprises a heating pipe and a heat conducting plate, a low water level steam generation area is arranged between the heat conducting plate and the water draining part, a protruding ring is arranged around the water draining part by the heat conducting plate to form a high water level steam generation area, and the heating pipe is arranged corresponding to the protruding ring. The heating plate is electrified by the heating pipe to generate heat, the heating pipe transfers the heat to the heat conducting plate, the heating pipe is the position where the heating plate directly generates heat and is the position where the temperature of the heating plate is highest, and the heating pipe is arranged corresponding to the protruding ring, so that the temperature of the protruding ring is higher than the temperature of other positions of the heat conducting plate, the protruding ring with the highest temperature of the heating plate is used for further intensively heating the high-water-level steam generation area, the rising speed of the water temperature in the high-water-level steam generation area is further improved, and the steam generation speed is further improved. The convex ring protrudes upwards, and a larger contact surface is formed between the position with higher temperature of the heating disc and the water in the steam generating cavity, so that more heat generated by the heating pipe is transferred to the water in the high-water-level steam generating area, the heating speed of the water in the high-water-level steam generating area is improved, and the steam generating efficiency is improved.

Preferably, the convex ring is provided with a water passing port, and the water passing port supplies water for the low water level steam generation area. The water outlet ensures that water in the cavity to be heated can be supplemented into the low-water-level steam generation area, and the water shortage and dry burning of the low-water-level steam generation area are avoided.

Preferably, the drain portion has a drain bottom wall, and a low water level steam generation region is formed between the drain bottom wall and the heating pan. The drain bottom wall makes the water level between the drain part and the heating plate lower, thereby forming a low water level steam generating area to improve the steam generating speed.

Preferably, the drain portion has a drain chamber, and the drain portion passes through the drain bottom wall to separate the drain chamber from the steam generation chamber. Therefore, water in the steam generation cavity can be prevented from entering the water drainage cavity, the space of the water drainage part, which occupies the steam generation cavity, is increased, the water quantity in the steam generation cavity is further reduced, the water temperature in the steam generation cavity can be increased more rapidly, and the steam generation speed is increased.

According to the cooking utensil capable of rapidly discharging steam, the water level between the heating plate and the water discharging part is lower through the water discharging part, so that the steam generation speed between the heating plate and the water discharging part can be improved, the heating speed of water in a high-water-level steam generation area is improved, and the steam generation efficiency is improved.

Drawings

FIG. 1 is a schematic cross-sectional view of a pan body;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a schematic diagram of an explosion structure of the pan body;

FIG. 4 is a schematic structural view of an energy concentrating member;

FIG. 5 is a schematic view of the structure of a heating plate;

FIG. 6 is a schematic diagram of the configuration of an air fryer.

The drawings are marked with the following description: 100. a pot body; 200. an inner pot; 210. a water containing chamber; 211. a steam generation chamber; 212. a cavity to be heated; 213. a low water level steam generation zone; 214. a high water level steam generation zone; 220. a spacer ring; 300. a steaming rack; 310. a second partition wall; 400. a heating plate; 410. heating pipes; 420. a heat conductive plate; 421. a protruding ring; 430. a water passing port; 500. a heat preservation cavity; 510. an overcurrent gap; 600. an energy gathering member; 610. a first partition wall; 620. a heat-preserving bottom wall; 621. a water passing channel; 630. a water draining part; 631. a drainage cavity; 632. a convex wall; 640. a top wall; 641. water passing through holes, 700 and baking components.

Detailed Description

The following detailed description of the embodiments of the present utility model is provided with reference to the accompanying drawings, so that the technical scheme of the present utility model can be understood and mastered more easily. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The embodiment provides a steamer, which is a specific application of the innovative scheme of the utility model on the steamer, and the innovative scheme of the utility model can also be applied to cooking utensils with steaming function, such as stewpans or steaming stewpans and electric cookers.

As shown in fig. 1 to 5, the cooker comprises a cooker body 100, wherein the cooker body 100 comprises an inner cooker 200 with a water containing cavity 210; the inner pot 200 is provided with a steam generating part, the steam generating part comprises a separation ring 220 and a heating plate 400 arranged in the separation ring 220, the separation ring 220 at least separates a steam generating cavity 211 in the water containing cavity 210, and the heating plate 400 is positioned at the bottom of the steam generating cavity 211; a drain 630 is disposed in the steam generating chamber 211 to form two steam generating areas with different liquid heights in the steam generating chamber 211; a low water level steam generation area 213 is provided between the heating tray 400 and the drain 630, and a high water level steam generation area 214 is formed between the drain 630 and the spacer ring 220.

During steam cooking, food is placed on the steaming rack 300, a proper amount of water is filled in the water containing cavity 210 of the pot body 100, the heating plate 400 works to heat the water in the water containing cavity 210 to generate steam, and the steam enters the steaming rack 300 to cook the food in the steaming rack 300.

The separating ring 220 separates the water containing cavity 210 from the steam generating cavity 211, the heating plate 400 is arranged in the separating ring 220, namely, the heating plate 400 is arranged corresponding to the steam generating cavity 211, the heating plate 400 is used for intensively heating water in the steam generating cavity 211 in a targeted manner, so that the water in the steam generating cavity 211 is heated preferentially, the heating plate 400 is prevented from directly heating the water in the whole water containing cavity 210, the heating plate 400 with the same power is used for heating less water, the temperature rising speed of the water in the steam generating cavity 211 is improved, and the steam generating speed is improved.

The steam generating chamber 211 is provided therein with a drain portion 630, so that the steam generating chamber 211 forms a low water level steam generating region 213 and a high water level steam generating region 214, and the drain portion 630 can further reduce the volume of the steam generating chamber 211, thereby reducing the water amount in the steam generating chamber 211 and further improving the steam generating speed in the steam generating chamber 211.

As shown in fig. 1 and 2, the water containing cavity 210 further has a cavity to be heated 212 and a heat preservation cavity 500, the separation ring 220 has an overflow gap 510 to communicate the heat preservation cavity 500 and the steam generation cavity 211, and the separation ring 220 has an overflow channel 621 to communicate the steam generation cavity 211 and the cavity to be heated 212.

The separation ring 220 separates the water containing cavity 210 into a steam generating cavity 211 and a cavity to be heated 212, water in the steam generating cavity 211 is heated before water in the cavity to be heated 212, after the water quantity in the cavity to be heated 211 is reduced due to steam generation, water in the cavity to be heated 212 flows to the steam generating cavity 211 through the water passage 621 to supplement the water quantity of the steam generating cavity 211, and the steam generating cavity 211 is ensured to have more sufficient water quantity for cooking.

The heat preservation chamber 500 is specifically located on the spacer ring 220, and the heat preservation chamber 500 can better block heat of the steam generation chamber 211 from being transferred to the chamber 212 to be heated through the spacer ring 220, so that heat dissipation of the steam generation chamber 211 to the chamber 212 to be heated is reduced. The hot water of the steam generation cavity 211 can flow into the heat preservation cavity 500 through the overflow gap 510, so that the temperature difference between the heat preservation cavity 500 and the steam generation cavity 211 is quickly reduced, the heat conducted from the steam generation cavity 211 to the cavity to be heated 212 is reduced, and the heat dissipation in the steam generation cavity 211 is further reduced. The heat dissipation of the steam generation cavity 211 is reduced while the steam generation cavity 211 is intensively heated, the heating speed of water in the steam generation cavity 211 is further improved, the steam generation efficiency is accelerated, the steam quantity in the steam rack 300 is increased, and the steam can be enabled to be more fully contacted with each part of food, so that the cooking speed is improved, the waiting time of a user is reduced, the user experience is improved, and the uniformity of heating of the food is also improved.

In other alternatives, the spacer ring 220 may be a solid retainer ring structure, where the retainer ring structure may be made of a material identical to that of the steaming rack 300 and integrally formed with the steaming rack 300, and the retainer ring structure may be made of a material different from that of the steaming rack 300 and detachably fixed to the steaming rack 300 by a clamping connection or the like, for example, the retainer ring structure is made of a thermal insulation material such as silica gel. In other alternatives, the insulating chamber 500 may be a closed structure without the overflow gap 510, for example, the insulating chamber 500 is filled with conventional air, or the insulating chamber 500 is filled with insulating material, or the insulating chamber 500 is a vacuum layer.

The heating plate 400 includes a heating pipe and a heat conducting plate 420, a low water level steam generating area 213 is disposed between the heat conducting plate 420 and the drain portion 630, the heat conducting plate 420 is provided with a protruding ring 421 around the drain portion 630 to form a high water level steam generating area 214, and the heating pipe is disposed corresponding to the protruding ring 421.

The heating plate 400 is powered on by the heating pipe 410 to generate heat, the heating pipe 410 transfers the heat to the heat conducting plate 420, the heating pipe 410 is the position where the heating plate 400 directly generates heat, and is the position where the temperature of the heating plate 400 is highest, and the heating pipe is arranged corresponding to the protruding ring 421, so that the temperature of the protruding ring 421 is higher than the temperature of other positions of the heat conducting plate 420, the protruding ring 421 with the highest temperature of the heating plate 400 is used for further intensively heating the high water level steam generation area 214, the rising speed of the water temperature in the high water level steam generation area 214 is further improved, and the steam generation speed is further improved. The protruding ring 421 protrudes upward, and a larger contact surface is formed between the water in the steam generating chamber 211 and the position where the temperature of the heating plate 400 is higher, which is advantageous for transferring more heat generated by the heating pipe 410 to the water in the high water level steam generating region 214, improving the heating speed of the water in the high water level steam generating region 214, and improving the efficiency of generating steam.

As shown in fig. 5, the protruding ring 421 is provided with a water passing port 430, and the water passing port 430 supplies water to the low water level steam generating region 213. The water passing port 430 ensures that water in the cavity 212 to be heated can be supplemented to the low water level steam generation area 213, and the low water level steam generation area 213 is prevented from being dry-burned due to water shortage.

As shown in fig. 1 and 2, the separation ring 220 includes a first separation wall 610 between the heat-insulating chamber 500 and the steam generating chamber 211, and the flow-through gap 510 is located at an upper end of the first separation wall 610. The higher flow gap 510 can reduce or prevent water in the heat preservation chamber 500 from flowing back to the steam generation chamber 211 to reduce the water temperature of the steam generation chamber 211, which is beneficial to improving the steam generation speed.

As shown in fig. 1 and 2, the spacer ring 220 includes a second partition wall 310 between the insulating cavity 500 and the cavity to be heated 212, and the second partition wall 310 is sealed to block water in the cavity to be heated 212 from entering the insulating cavity 500; this ensures that cold water in the heat-retaining chamber 212 does not enter the heat-retaining chamber 500, which is advantageous in maintaining the water in the heat-retaining chamber 500 at a higher temperature.

In other alternative embodiments, the heat-preserving chamber 500 may also be in communication with the chamber 212 to be heated, specifically, a second partition wall 310 is provided between the heat-preserving chamber 500 and the chamber 212 to be heated, and an upper end portion of the second partition wall 310 is provided with a water outlet, where the water outlet is located below the flow gap 510. The water outlet is positioned at the upper end part of the second partition wall 310 and is higher, so that the water outlet can be positioned above the water level line of the cavity 212 to be heated, and cold water in the cavity 212 to be heated cannot upwelle to enter the heat preservation cavity 500 from the water outlet, so that cold water in the cavity 212 to be heated is prevented from entering the heat preservation cavity 500 from the water outlet, and cold water is prevented from entering the heat preservation cavity 500. The hot water in the heat preservation cavity 211 flows into the heat preservation cavity 500 from the overflow gap 510, because the temperature of the water in the heat preservation cavity 500 is lower than that of the water in the steam generation cavity 211 due to the influence of the heat preservation cavity 212, when the water level in the heat preservation cavity 500 reaches the height of the water outlet, the water in the heat preservation cavity 500 can flow out from the water outlet to the heat preservation cavity 212, the water in the heat preservation cavity 500 is prevented from flowing back to the steam generation cavity 211 from the overflow gap 510 to reduce the temperature of the water in the steam generation cavity 211, and the water blockage of the heat preservation cavity 500 in the overflow gap 510 is prevented from causing the water in the steam generation cavity 211 to be difficult to enter the heat preservation cavity 500, so that the heat preservation cavity 500 is ensured to continuously have the hot water entering, and the heat preservation effect is improved.

In other alternative embodiments, the spacer ring 220 may be provided with a flow passage that communicates the heat preservation chamber 500 and the chamber to be heated 212, where the flow passage corresponds to the lower end of the heat preservation chamber 500, and in the process that the steam generating chamber 211 forms steam, the steam can enter the heat preservation chamber 500 through the flow passage gap 510, so as to generate a certain pressure on the cold water in the heat preservation chamber 500, so that the cold water is discharged from the flow passage into the chamber to be heated 212, thereby maintaining the heat preservation chamber 500 in a hotter state and improving the heat preservation effect.

As shown in fig. 1-4, the inner pot 200 is provided with an energy collecting member 600 and a steaming rack 300, the water draining part 630 is located on the energy collecting member 600, the separation ring 220 comprises a first separation wall 610 and a heat insulation bottom wall 620 integrally connected to the energy collecting member 600, and a second separation wall 310 integrally connected to the steaming rack 300, and the lower end of the second separation wall 310 is abutted against the heat insulation bottom wall 620; the heat preservation chamber 500 is formed by assembling and enclosing the energy gathering piece 600 and the local structure of the steaming rack 300, is convenient for the processing and production of the separation ring 220, and reduces the processing difficulty. In alternative embodiments, the spacer ring 220 may be integrally fixed to the steaming frame 300, specifically, the first partition 610, the insulating bottom wall 620 and the second partition 310 are welded together to form the insulating cavity 500. In embodiments having an excess flow channel, a gap may also be provided between the second partition wall 310 and the insulated bottom wall 620, which may act as an excess flow channel. The through-flow passage may be a through-hole formed in the second partition 310.

As shown in fig. 2, the first partition 610 and the steam rack 300 have a gap therebetween to form the overflow gap 510, so that the overflow gap 510 is naturally formed by assembling the steam rack 300 and the energy collecting member 600 without processing the overflow gap 510 on the first partition 610, thereby reducing the processing steps and improving the production efficiency. In other alternative embodiments, a through hole is provided in the first partition wall 610 to form the through-flow gap 510.

The drain portion 630 has a drain bottom wall, and a low water level steam generating area is formed between the drain bottom wall and the heating pan 400. The drain portion 630 has a drain bottom wall, and a low water level steam generation area is formed between the drain bottom wall and the heating pan, thereby improving a steam generation speed.

As shown in fig. 1 to 4, the drain portion 630 has a drain chamber 631, and the drain portion 630 is formed by a drain bottom wall to separate the drain chamber 631 from the steam generation chamber 211. This can prevent water in the steam generating chamber 211 from entering the drain chamber 631, increase the space of the drain portion 630 occupying the steam generating chamber 211, further reduce the water amount in the steam generating chamber 211, and enable the water temperature in the steam generating chamber 211 to be more rapidly increased, and increase the steam generating speed.

As shown in fig. 2 and 4, the energy collector 600 includes a top wall 640 connecting the first partition wall 610 and the water drain portion 630, the top wall 640 is higher than the heat-insulation bottom wall 620, the top wall 640 has a water through hole 641, the water drain portion 630 has a convex wall 632 extending upward relative to the top wall 640, and the convex wall 632 abuts against the bottom of the steam shelf 300. Steam in the steam generation cavity 211 can further enter the steam rack 300 after passing through the water passing through hole 641, when water in the steam generation cavity 211 boils upwards and surges, part of water can enter the heat preservation cavity 500 from the overflow gap 510, and the convex wall 632 can prevent water from rushing into the drainage cavity 631, so that the water accumulation in the drainage cavity 631 is avoided, and the water waste is avoided.

In this embodiment, the heat-preserving bottom wall 620 is abutted against the bottom of the inner pan 200, the steaming rack 300 is abutted against the heat-preserving Wen Debi 620 and the convex wall 632, and the energy collecting member 600 and the steaming rack 300 can be placed into the inner pan 200 first and then when mounted.

In other optional embodiments, a detachable fixing structure is provided between the steaming rack 300 and the energy collecting member 600, for example, the steaming rack 300 and the energy collecting member 600 may be detachably connected by a clamping manner, when the steaming rack 300 and the energy collecting member 600 are installed, the steaming rack 300 and the energy collecting member 600 may be fixed together, and then are integrally placed in the inner pot 200, when the overflow gap 510 is higher than the water level in the water containing cavity 210, cold water in the inner pot 200 is prevented from entering the heat preservation cavity 500 after the steaming rack 300 and the energy collecting member 600 are placed in the inner pot 200, so that the initial cooking stage is ensured, and air rather than cold water is filled in the heat preservation cavity 500, so that the heat preservation cavity 500 has better heat preservation and heat insulation effects. After part of the hot water of the steam generating cavity 211 flows into the heat preserving cavity 500 from the flowing gap 510, the heat preserving water in the heat preserving cavity 500 can be at a higher temperature and not cooled by cold water, which is beneficial to the heat preserving cavity 500 to reach the optimal heat preserving state quickly and quicken the steam generating speed of the steam generating cavity 211.

As shown in fig. 2, the lower end of the separation ring 220 and the lower end of the drain 630 are lower than the upper end of the heating pipe. The separation ring 220 and the water draining part 630 are positioned at two sides of the heating pipe 410, when the heating plate is installed, the protruding position of the heating plate 400 at the heating pipe 410 can play a role in guiding and positioning the energy collecting piece 600, so that the situation that the steam rack 300 is difficult to install due to severe deviation of the position of the energy collecting piece 600 is avoided, the assembly alignment difficulty of the energy collecting piece 600 and the steam rack 300 is reduced, and the assembly efficiency is improved.

As shown in FIG. 6, in another embodiment of the present application, the cooking apparatus is an air fryer, and an inner pot 200 is disposed in a pot body 100 of the air fryer, and the steam generating part is placed in the inner pot 200, so that steam can be quickly discharged. The steaming function of the air fryer can be matched with the top baking assembly 700 to cook food in the inner pot together or in a time-sharing manner, and the steam generating part can be used for independently cooking food materials in the inner pot, so that the multifunctional air fryer is realized.

In the description of the present utility model, it should be understood that the terms "center," "lateral," "thickness," "upper," "lower," "vertical," "horizontal," "top," "bottom," "inner," "outer," "radial," "circumferential," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the utility model and simplify description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a 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 such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise. In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

It should be understood by those skilled in the art that, although the embodiments of the present utility model are disclosed above, the embodiments are merely adopted for the purpose of facilitating understanding of the embodiments of the present utility model, and are not intended to limit the embodiments of the present utility model. Any person skilled in the art can make any modification and variation in form and detail without departing from the spirit and scope of the embodiments of the utility model, but the scope of the embodiments of the utility model is defined by the appended claims.

Claims (10)

1. The cooking utensil capable of rapidly discharging steam comprises a pot body, wherein the pot body comprises an inner pot with a water containing cavity; the inner pot is provided with a steam generating part, the steam generating part comprises a separation ring and a heating disc arranged in the separation ring, the separation ring at least separates a steam generating cavity in the water containing cavity, and the heating disc is positioned at the bottom of the steam generating cavity;

the device is characterized in that a drainage part is arranged in the steam generation cavity so as to form two steam generation areas with different liquid heights in the steam generation cavity;

a low water level steam generating area is arranged between the heating plate and the water draining part, and a high water level steam generating area is formed between the water draining part and the separating ring.

2. The rapid steam-out cooking appliance of claim 1, wherein the water holding chamber further has a heat-to-be-heated chamber and a heat-retaining chamber, the spacer ring having an excess flow gap to communicate the heat-retaining chamber with the steam-generating chamber, the spacer ring having an excess flow channel to communicate the steam-generating chamber with the heat-to-be-heated chamber.

3. The rapid steam-generating cooking appliance of claim 2, wherein the spacer ring includes a first spacer wall between the insulating chamber and the steam-generating chamber, the overflow gap being located at an upper end of the first spacer wall.

4. The rapid steam-out cooking appliance of claim 2, wherein the spacer ring comprises a second spacer wall between the insulating cavity and the cavity to be heated, the second spacer wall being sealed to block water from the cavity to be heated from entering the insulating cavity;

or a second partition wall is arranged between the heat preservation cavity and the cavity to be heated, a water outlet is arranged at the upper end part of the second partition wall, and the position of the water outlet is lower than the overflow gap.

5. The cooking appliance for quickly discharging steam according to any one of claims 2, wherein an energy collecting member and a steam rack are arranged in the inner pot, the water discharging part is positioned on the energy collecting member, the separating ring comprises a first separating wall and a heat-preserving bottom wall which are integrally connected with the energy collecting member, and a second separating wall which is integrally connected with the steam rack, and the lower end of the second separating wall is abutted against the heat-preserving bottom wall;

and a gap is formed between the first partition wall and the steaming rack so as to form the overflow gap, or a through hole is formed in the first partition wall so as to form the overflow gap.

6. The rapid steam-exit cooking appliance of claim 5 wherein the energy gathering member includes a top wall connecting the first partition wall and the drain portion, the top wall being higher than the insulating bottom wall, the top wall having a water passage opening therein, the drain portion having a raised wall extending upwardly relative to the top wall, the raised wall abutting the bottom of the steam shelf.

7. The rapid steam-discharging cooking appliance according to claim 1, wherein the heating plate comprises a heating pipe and a heat conducting plate, a low water level steam generation area is arranged between the heat conducting plate and the water discharge part, a protruding ring is arranged around the water discharge part on the heat conducting plate to form a high water level steam generation area, and the heating pipe is arranged corresponding to the protruding ring.

8. The rapid steam-generating cooking appliance of claim 7, wherein the raised ring is provided with a water passing port that supplies water to the low water level steam generating zone.

9. The rapid steam-out cooking appliance of claim 1, wherein the drain has a drain bottom wall, and a low water level steam generating zone is formed between the drain bottom wall and the heating pan.

10. The rapid steam-out cooking appliance of claim 9, wherein the drain has a drain cavity, the drain passing through the drain bottom wall to separate the drain cavity from the steam-generating cavity.

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