CN220442526U - Single-double-pot switchable air fryer - Google Patents

Abstract

The utility model relates to a single-double-pot switchable air fryer, which comprises a main body, a plurality of air frying chambers and a plurality of air frying chambers, wherein the main body is provided with a heating chamber with an opening; the heating assembly and the air supply assembly are used for conveying hot air to the heating chamber; a fry basket assembly removably disposed within the heating chamber; the frying basket assembly at least comprises two frying baskets which are sequentially arranged in a layered manner; the frying basket comprises a detachable liner and a heat insulation wall; a locking mechanism is arranged between the inner container and the heat insulation wall, and the inner container and the heat insulation wall are locked in the extraction direction. The utility model has the beneficial effects that: 1. when a user only needs to process one or a few small amount of foods, only one of the frying baskets is needed, the inner containers on the other frying baskets are detached, the heat insulation wall is put back to the opening of the main body to be sealed, and only the used inner containers are required to be cleaned after the foods are processed, so that the unused inner containers are not required to be additionally cleaned, and the cleaning workload is reduced; meanwhile, the disassembled liner is convenient to clean.

Description

Single-double-pot switchable air fryer

Technical Field

The utility model relates to the technical field of air fryers, in particular to a single-pot and double-pot switchable air fryer.

Background

The air fryer uses high-speed air circulation technology and combines the fast circulation of hot air with the unique combination of internal spiral lines to achieve the cooking effect of frying food and mouthfeel. The popular point is that when heating, high-temperature hot air is generated in the pot body to form a crisp surface layer on the surface of food, so that the moisture in the food material is locked, and the taste of the common fried food is fragrant and crisp.

With further emphasis on dietary health, air fryers that do not have oil cooking are becoming popular with consumers and sales are increasing year by year. However, the existing air fryer has a unified structure, so that the heating mode is also a dust-free mode, and the higher-level requirements of consumers cannot be met. Existing air fryers suffer from at least the following drawbacks, for example: 1. only a single heating chamber or frying basket can process one food at a time, the cooking time of various foods is different, and in the case of meat, the time generally needs to be tens of minutes, so that when a plurality of foods or a large amount of foods are needed to be processed, the cooking can not be realized once, and a long time is needed; 2. because the air fryer cannot heat various foods or a large amount of foods at the same time, the air fryer needs to work for a long time, so that the air fryer cannot cook efficiently, saves energy and protects environment, accelerates the aging of various components and parts, and greatly reduces the service life; 3. in the traditional thinking, accomplish that multiple sets of heating element are needed to multi-chamber, the whole volume of air fryer will become very big very heavy so the mode first, and second internal structure becomes very complicated, and third operation is very inconvenient, and the biggest problem simultaneously can lead to the cost to rise greatly, will lose the favor of very big part consumer.

The applicant applied for an upper and lower layered air fryer several days before this month, comprising a main body provided with a heating chamber with an opening; the heating assembly and the air supply assembly are used for conveying hot air to the heating chamber; a fry basket assembly removably disposed within the heating chamber; the frying basket assembly at least comprises a first frying basket and a second frying basket, and is sequentially arranged in a layered manner; the heating assembly comprises at least a first heating element and a second heating element, and the first heating element and the second heating element are arranged on different sides of the heating chamber. The utility model has the beneficial effects that: 1. the plurality of frying baskets are arranged in an up-down layered mode, so that the occupied space of the whole machine is smaller, and meanwhile, the plurality of heating pieces are arranged to heat the heating chamber in multiple directions, so that the heating efficiency is improved, and the processing efficiency of the frying basket below on food is ensured; 2. the cross section of the upper frying basket is smaller than that of the lower frying basket, and hot air can smoothly enter the lower frying basket to ensure the processing efficiency of food in the lower frying basket.

However, the air fryer has the function of processing various foods together, and when a user only needs to process one type of food, only one inner container is needed, and at the moment, other inner containers need to be detached, so that the pollution caused by greasy dirt mixed in flowing air is avoided, and the workload of cleaning the inner containers is reduced.

Disclosure of Invention

In order to solve the problems in the prior art, the utility model provides a single-pot and double-pot switchable air fryer.

The technical scheme for solving the technical problems is as follows: comprising the steps of (a) a step of,

a main body provided with a heating chamber with an opening;

the heating assembly and the air supply assembly are used for conveying hot air to the heating chamber;

a fry basket assembly removably disposed within the heating chamber;

the frying basket assembly at least comprises two frying baskets which are sequentially arranged in a layered manner;

the frying basket comprises a detachable liner and a heat insulation wall; a locking mechanism is arranged between the inner container and the heat insulation wall, and the inner container and the heat insulation wall are locked in the extraction direction.

The technical scheme is further provided as follows: the locking mechanism comprises an inserting sheet and an inserting slot which are arranged on the heat insulation wall and the inner container, wherein a lock catch is arranged in the inserting slot and is driven by an activating piece to be opened, and the inserting sheet is released.

The technical scheme is further provided as follows: the inserting piece is arranged on the outer wall of the inner container, the slot is arranged on the heat insulation wall, the inserting piece extends from the inner wall of the heat insulation wall to the upper end face to be arranged in an L-shaped mode, and the activating piece is located at the upper port of the slot.

The technical scheme is further provided as follows: the lock catch is a V-shaped lock catch, two end parts of the V-shaped lock catch are clamping feet, the activating piece moves to separate the two clamping feet, and the inserting piece is released.

The technical scheme is further provided as follows: the side part of the lock catch, which is positioned on the clamping leg, is provided with a clamping plate, the activating piece is provided with a driving part corresponding to the clamping plate in position, the activating piece drives the driving part to move, and the two driving parts push the two clamping plates outwards.

The technical scheme is further provided as follows: the outer end face of the driving part is provided with a first inclined plane, and the inner end face of the clamping plate is provided with a second inclined plane matched with the first inclined plane.

The technical scheme is further provided as follows: an elastic reset piece is arranged between the activating piece and the lock catch.

The technical scheme is further provided as follows: a positioning structure is further arranged between the inner container and the heat insulation wall, and the positioning structure comprises a positioning sheet and a positioning groove;

the positioning groove is internally provided with a first adsorption component.

The technical scheme is further provided as follows: the locking mechanism comprises a connecting groove and a connecting sheet which are spliced in the vertical direction.

The technical scheme is further provided as follows: and a second adsorption component is further arranged on the inner side end surface of the heat insulation wall.

Compared with the prior art, the utility model has the beneficial effects that:

1. when a user only needs to process one or a few small amount of foods, only one of the frying baskets is needed, the inner containers on the other frying baskets are detached, the heat insulation wall is put back to the opening of the main body to be sealed, and only the used inner containers are required to be cleaned after the foods are processed, so that the unused inner containers are not required to be additionally cleaned, and the cleaning workload is reduced; meanwhile, the disassembled liner is convenient to clean;

2. because no other inner container is blocked, hot air is directly blown to the inner container for holding food, and the food processing efficiency is quickened.

Drawings

Fig. 1 is a schematic diagram of an explosive structure according to the present utility model.

FIG. 2 is a schematic exploded view of the fry basket.

FIG. 3 is a schematic view of another orientation of the fry basket exploded.

Fig. 4 is a schematic structural view of the latch.

Fig. 5 is a schematic view of the structure of the activation member.

Fig. 6 is an exploded view of the locking mechanism.

Fig. 7 is a schematic diagram of a connection structure of the locking mechanism.

FIG. 8 is a schematic cross-sectional view of a fry basket.

Fig. 9 is an exploded view of the positioning structure of embodiment 1.

Fig. 10 is a schematic structural diagram of the first adsorption member in the positioning groove in embodiment 1.

Fig. 11 is an exploded structure diagram of embodiment 2.

Fig. 12 is a schematic view showing an exploded structure in another direction in embodiment 2.

The drawings are marked: 100. a main body; 101. a heating chamber;

300. a heating assembly;

400. an air supply assembly;

500. a fry basket; 510. an inner container; 520. a heat insulating wall; 530. a handle; 511. inserting sheets; 521. a slot; 511.1, a convex portion; 512. a positioning sheet; 522. a positioning groove; 513. a connecting sheet; 523. a connecting groove;

610. locking; 620. an activating member; 611. a clamping foot; 612. a clamping plate; 613. a hook part; 621. a driving section; a. a first inclined surface; b. a second inclined surface; 630. an elastic reset piece;

1. a pin shaft; 2. a first adsorption member; 3. and a second adsorption member.

Detailed Description

In order to further describe the technical means and effects adopted by the present utility model for achieving the intended purpose, the following detailed description will refer to the specific implementation, structure, characteristics and effects according to the present utility model with reference to the accompanying drawings and preferred embodiments.

It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It will be understood that, although the terms upper, middle, lower, top, end, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another for ease of understanding and are not used to define any directional or sequential limitation.

As shown in fig. 1-12, the following examples disclose a single-pot and double-pot switchable air fryer.

Example 1

Comprising the steps of (a) a step of,

a main body 100 provided with a heating chamber 101 having an opening;

a heating assembly 300 and an air supply assembly 400 provided for supplying hot air to the heating chamber 101;

a fry basket assembly removably disposed within the heating chamber 101;

the frying basket assembly at least comprises two frying baskets 500 which are sequentially arranged in a layered manner;

the fry basket 500 includes a removable liner 510 and a thermally insulating wall 520; a locking mechanism is provided between the liner 510 and the heat insulating wall 520 to lock the liner 510 and the heat insulating wall 520 in the extraction direction.

The above is the basic scheme of the present embodiment. When a user uses the air fryer, the frying basket 500 assemblies are taken out from the heating chamber 101, different foods are respectively placed into different frying baskets 500, then the frying baskets 500 are placed into the heating chamber 101 in sequence, the power supply is turned on, the heating assemblies 300 generate heat, the air supply assemblies 400 and the heating assemblies 300 jointly act to form hot air, and the foods in the two frying baskets 500 are processed.

When a user only needs to process one or a few small amount of foods, the user only needs to put the foods into the inner container 510 of one of the frying baskets 500, then detach the inner container 510 on the other frying baskets 500, put the frying basket 500 with the foods back into the heating chamber 101, put the other heat insulation walls 520 without the inner container 510 back into the opening of the main body 100, seal the heating chamber 101, turn on the power supply, and process the foods of the inner container 510 by the main body 100.

With the structure, the user only needs to clean the used inner container 510 after processing food, and does not need to additionally clean the unused inner container 510, thereby reducing the workload of cleaning; meanwhile, the disassembled liner 510 is convenient to clean.

In contrast, when a user needs to process food using a plurality of the inner containers 510, the user only needs to attach the inner containers 510 to the heat insulating wall 520.

Thanks to the above arrangement, when a user processes food using only one or a few of the inner containers 510, the hot air is directly blown to the inner container 510 containing the food due to no barrier of the other inner containers 510, thereby accelerating the efficiency of food processing.

In this embodiment, the heat insulating wall 520 is provided with a handle 530.

In order to prevent the liner 510 from coming out of the heat insulating wall 520, the locking mechanism in the present embodiment locks the liner 510 and the heat insulating wall 520 in the extraction direction.

Preferably, in this embodiment, the opening of the heating chamber 101 is disposed on the side wall, so that the fry basket 500 is pulled out horizontally with respect to the main body 100, and then the locking assembly locks the inner container 510 and the heat insulation wall 520 horizontally, so that the inner container 510 is prevented from being separated from the heat insulation wall 520 when the fry basket 500 is pulled by a user, resulting in a safety hazard.

The locking mechanism capable of being rapidly operated and manually operated is adopted in the embodiment, and the specific implementation mode is as follows: the locking mechanism comprises an inserting sheet 511 and an inserting slot 521 which are arranged on the heat insulation wall 520 and the inner container 510, wherein a lock catch 610 is arranged in the inserting slot 521, and the lock catch 610 is driven to be opened by an activating piece 620 to release the inserting sheet 511.

When the liner 510 is mounted on the heat insulation wall 520, the lock catch 610 can lock the insert 511 only by inserting the insert 511 into the slot 521, so as to complete the connection between the liner 510 and the heat insulation wall 520.

When the liner 510 needs to be disassembled, the user operates the activating member 620, and the activating member 620 drives the lock catch 610 to open, so that the insert 511 is released, and the liner 510 can be removed from the heat insulation wall 520.

For operational safety, in this embodiment, the insert 511 is disposed on the outer wall of the inner container 510, and the slot 521 is disposed on the heat insulation wall 520. When the frying basket 500 is required to be disassembled and cleaned just after use, if the activating member 620 is arranged on the inner container 510, a user is easy to scald during operation, and the risk of scalding is avoided when the activating member is arranged on the heat insulation wall 520, and meanwhile, the user can conveniently operate the frying basket with one hand.

Meanwhile, in this embodiment, the slot 521 extends from the inner wall of the heat insulation wall 520 to the upper end surface to form an L-shape, and the activating element 620 is located at the upper end of the slot 521.

Specifically, the opening of the slot 521 on the inner wall side of the heat insulating wall 520 is used for connecting the insert 511, the opening on the upper end surface of the heat insulating wall 520 is used for installing the activating member 620, and the two openings are communicated inside the heat insulating wall 520, and the latch 610 is located in the area of the slot 521 inside the partition wall.

In this manner, the user can detach the liner 510 from the inner wall of the heat insulating wall 520 by operating the activating member 620 at the upper end of the heat insulating wall 520.

The specific implementation manner of the lock catch 610 in this embodiment is: the lock catch 610 is a V-shaped buckle, two ends of the V-shaped buckle are clamping feet 611, the activating piece 620 moves to separate the two clamping feet 611, and the inserting piece 511 is released.

Specifically, in order to lock the insert 511 horizontally, in this embodiment, the latch 610 is laid down in the slot 521, that is, the two clamping legs 611 are located horizontally, the activating member 620 moves above the latch 610 to separate or close the two clamping legs 611 to two sides, so as to lock and release the insert 511.

In this embodiment, the heads of the two clamping legs 611 are respectively provided with an inward hook portion 613, the head of the insert 511 has a protrusion 511.1 that can be clamped by the hook portion 613, and when the two clamping legs 611 are in the closed position, the protrusion 511.1 is clamped by the hook portion 613, so that the head of the insert 511 is locked between the two clamping legs 611, and the insert 511 cannot be separated from the lock catch 610; when the two locking legs 611 are separated under the action of the activating element 620, the two hook portions 613 respectively move outwards, and the protrusion 511.1 can be separated from the hook portion 613, so that the insert 511 can be separated from the lock catch 610.

In this embodiment, the activating member 620 drives the latch 610 mechanically, which is specifically described as follows: the lock catch 610 is provided with a clamping plate 612 at the side of the clamping leg 611, the activating element 620 is provided with a driving part 621 corresponding to the clamping plate 612, the activating element 620 drives the driving part 621 to move, and the two driving parts 621 push the two clamping plates 612 outwards.

Specifically, in order to minimize the movement space of the activating member 620, so as to simplify the operation, in this embodiment, the movement direction of the activating member 620 is a vertical direction, and to implement that the movement of the activating member 620 in the vertical direction is converted into the movement of the clamping leg 611 in the horizontal direction, a specific test method for solving the problem in this embodiment is as follows: the outer end surface of the driving part 621 is provided with a first inclined surface a, and the inner end surface of the clamping plate 612 is provided with a second inclined surface b matched with the first inclined surface a.

Meanwhile, the activating member 620 is a button, and the driving part 621 is located on the lower end surface of the activating member 620.

When the activating member 620 moves downward under the user's operation, the driving part 621 also moves downward, generating pressure to the clamping plate 612, and the direction of the pressure is downward perpendicular to the second inclined plane b due to the action of the first inclined plane a, so that the component force of the pressure in the horizontal direction is horizontally outward, and thus the two clamping legs 611 perform a movement of separating from each other.

In order to enable the activation member 620 to automatically reset and reduce the operation of the user, in this embodiment, an elastic reset member 630 is disposed between the activation member 620 and the latch 610.

When the user removes the pressing force to the activating element 620, the elastic restoring element 630 pushes up the activating element 620, so that the driving part 621 is separated from the clamping plate 612, and the two clamping legs 611 are restored to be close to each other under the action of the restoring force.

When the user installs the inner container 510 on the heat insulation wall 520, the insert 511 is inserted into the slot 521, the head is clamped between the two clamping legs 611, the two protrusions 511.1 on the head of the insert 511 push the two hook portions 613 apart, so that the two clamping legs 611 are separated from each other, the insert 510 is pushed continuously until the protrusion 511.1 passes over the hook portions 613, at this time, the clamping legs 611 are reset without external force, and the two hook portions 613 lock the protrusion 511.1 between the two clamping legs 611.

Preferably, the elastic restoring member 630 in this embodiment is a spring.

Preferably, the head of the latch 610 in this embodiment is fixed inside the slot 521 by the pin 1. And the upper end of the elastic restoring member 630 abuts against the activating member 620, and the lower end thereof abuts against the latch 610 or the inside part of the heat insulation wall 520, so that the activating member 620 can be supported in a direction away from the latch 610.

In the above structure, the liner 510 is connected with the heat insulation wall 520 only by the insertion sheet 511, so that the liner 510 is easy to shake, in this embodiment, a positioning structure is further provided between the liner 510 and the heat insulation wall 520, the positioning structure includes a positioning sheet 512 and a positioning slot 522, and in order to ensure that the positioning structure is not easy to loose in the horizontal direction, a first adsorption component 2 is provided in the positioning slot 522.

Specifically, in this embodiment, the positioning plate 512 is made of a metal material, the magnet lamp adsorption member 2 is disposed in the positioning groove 522, and an insertion gap is reserved between the adsorption member 2 and any one of the groove walls of the positioning groove 522, and the direction of the positioning plate 512 is consistent with the position of the insertion gap. When the liner 510 is installed, the positioning piece 512 is aligned with the insertion gap, and the insertion piece 511 and the insertion slot 521 are aligned and inserted.

With this structure, the positioning piece 512 is inserted into the slot, and the side portion is absorbed by the absorbing member 2, so that the connection strength is greatly improved.

Example 2

Comprising the steps of (a) a step of,

a main body 100 provided with a heating chamber 101 having an opening;

a heating assembly 300 and an air supply assembly 400 provided for supplying hot air to the heating chamber 101;

a fry basket assembly removably disposed within the heating chamber 101;

the frying basket assembly at least comprises two frying baskets 500 which are sequentially arranged in a layered manner;

the fry basket 500 includes a removable liner 510 and a thermally insulating wall 520; a locking mechanism is provided between the liner 510 and the heat insulating wall 520 to lock the liner 510 and the heat insulating wall 520 in the extraction direction.

The above is the basic scheme of the present embodiment. When a user uses the air fryer, the frying basket 500 assemblies are taken out from the heating chamber 101, different foods are respectively placed into different frying baskets 500, then the frying baskets 500 are placed into the heating chamber 101 in sequence, the power supply is turned on, the heating assemblies 300 generate heat, the air supply assemblies 400 and the heating assemblies 300 jointly act to form hot air, and the foods in the two frying baskets 500 are processed.

When a user only needs to process one or a few small amount of foods, the user only needs to put the foods into the inner container 510 of one of the frying baskets 500, then detach the inner container 510 on the other frying baskets 500, put the frying basket 500 with the foods back into the heating chamber 101, put the other heat insulation walls 520 without the inner container 510 back into the opening of the main body 100, seal the heating chamber 101, turn on the power supply, and process the foods of the inner container 510 by the main body 100.

With the structure, the user only needs to clean the used inner container 510 after processing food, and does not need to additionally clean the unused inner container 510, thereby reducing the workload of cleaning; meanwhile, the disassembled liner 510 is convenient to clean.

In contrast, when a user needs to process food using a plurality of the inner containers 510, the user only needs to attach the inner containers 510 to the heat insulating wall 520.

Thanks to the above arrangement, when a user processes food using only one or a few of the inner containers 510, the hot air is directly blown to the inner container 510 containing the food due to no barrier of the other inner containers 510, thereby accelerating the efficiency of food processing.

In this embodiment, the heat insulating wall 520 is provided with a handle 530.

In order to prevent the liner 510 from coming out of the heat insulating wall 520, the locking mechanism in the present embodiment locks the liner 510 and the heat insulating wall 520 in the extraction direction.

Preferably, in this embodiment, the opening of the heating chamber 101 is disposed on the side wall, so that the fry basket 500 is pulled out horizontally with respect to the main body 100, and then the locking assembly locks the inner container 510 and the heat insulation wall 520 horizontally, so that the inner container 510 is prevented from being separated from the heat insulation wall 520 when the fry basket 500 is pulled by a user, resulting in a safety hazard.

The locking mechanism capable of being rapidly operated and manually operated is adopted in the embodiment, and the specific implementation mode is as follows: the locking mechanism comprises a connecting groove 523 and a connecting piece 513 which are spliced in the vertical direction.

Specifically, the connection piece 513 is bent downward and disposed on the outer wall of the inner container 510, the connection groove 523 is disposed on the inner wall of the heat insulation wall 520 in a protruding manner, and the opening is upward.

When the user installs the inner container 510, the two connecting pieces 513 can be first inserted into the connecting slot 523 from top to bottom, so that positioning can be completed, and the inner container 510 cannot be separated from the heat insulation wall 520 in the horizontal direction because the inserting direction is vertical.

Meanwhile, in order to improve strength, a second adsorption component (3) is further arranged on the inner side end face of the heat insulation wall.

After the liner 510 is installed on the heat insulation wall 520 downwards, the second adsorption component 3 adsorbs the outer wall of the liner 510, and adsorption fixation is completed.

Preferably, a metal adsorption sheet may be disposed on the outer wall of the inner container 510 to be in adsorption connection with the second adsorption member 3.

The present utility model is not limited to the above embodiments, but is capable of modification and variation in detail, and other modifications and variations can be made by those skilled in the art without departing from the scope of the present utility model.

Claims (10)

1. A single-double-pot switchable air fryer comprises,

a main body (100) provided with a heating chamber (101) having an opening;

a heating assembly (300) and an air supply assembly (400) arranged to supply hot air to the heating chamber (101);

a fry basket assembly that is withdrawn within the heating chamber (101);

the method is characterized in that: the frying basket assembly at least comprises two frying baskets (500) which are sequentially arranged in a layered manner;

the frying basket (500) comprises a detachable inner container (510) and a heat insulation wall (520); a locking mechanism is arranged between the inner container (510) and the heat insulation wall (520), and the inner container (510) and the heat insulation wall (520) are locked in the extraction direction.

2. The single-double pot switchable air fryer according to claim 1, wherein: the locking mechanism comprises an inserting sheet (511) and an inserting groove (521) which are arranged on the heat insulation wall (520) and the inner container (510), a lock catch (610) is arranged in the inserting groove (521), and the lock catch (610) is driven to be opened by an activating piece (620) to release the inserting sheet (511).

3. The single-double pot switchable air fryer according to claim 2, wherein: the inserting piece (511) is arranged on the outer wall of the inner container (510), the inserting groove (521) is arranged on the heat insulation wall (520), the inserting piece extends from the inner wall of the heat insulation wall (520) to the upper end face to form an L-shaped arrangement, and the activating piece (620) is positioned at the upper port of the inserting groove (521).

4. A single-double pot switchable air fryer according to claim 2 or 3, wherein: the lock catch (610) is a V-shaped buckle, two ends of the V-shaped buckle are clamping feet (611), the activating piece (620) moves to separate the two clamping feet (611) and release the inserting piece (511).

5. The single-double pot switchable air fryer according to claim 4, wherein: the side part of the lock catch (610) positioned on the clamping leg (611) is provided with a clamping plate (612), the activating piece (620) is provided with a driving part (621) corresponding to the clamping plate (612), the activating piece (620) drives the driving part (621) to move, and the two clamping plates (612) are pushed outwards by the two driving parts (621).

6. The single-double pot switchable air fryer according to claim 5, wherein: the outer end face of the driving part (621) is provided with a first inclined plane (a), and the inner end face of the clamping plate (612) is provided with a second inclined plane (b) matched with the first inclined plane (a).

7. The single-double pot switchable air fryer according to claim 2, wherein: an elastic reset piece (630) is arranged between the activating piece (620) and the lock catch (610).

8. The single-double pot switchable air fryer according to claim 1, wherein: a positioning structure is further arranged between the inner container (510) and the heat insulation wall (520), and the positioning structure comprises a positioning sheet (512) and a positioning groove (522);

a first adsorption component (2) is arranged in the positioning groove (522).

9. The single-double pot switchable air fryer according to claim 1, wherein: the locking mechanism comprises a connecting groove (523) and a connecting sheet (513) which are spliced in the vertical direction.

10. The single-double pot switchable air fryer according to claim 9, wherein: the inner side end surface of the heat insulation wall (520) is also provided with a second adsorption component (3).