Container assembly and cooking device
By designing a detachable snap-fit structure and clamping arms, the problem of cleaning dead corners in food processing machines is solved, enabling stable fixation of storage containers and convenient cleaning, reducing the risk of burns.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG ROWAN TREE TECHNOLOGY CO LTD
- Filing Date
- 2025-07-15
- Publication Date
- 2026-07-07
AI Technical Summary
The food containers of existing food processors are fixedly connected to the base, creating cleaning dead zones that are difficult for users to clean effectively.
Design a detachable container assembly that achieves a detachable connection between the storage container and the mounting base by setting a rotatable snap-fit structure and clamping arm between the storage container and the mounting base, combined with elastic shock absorbers and adsorption components to ensure stable fixation and convenient cleaning.
It effectively prevents storage containers from slipping, reduces the risk of burns, simplifies the cleaning process, and improves cleaning efficiency.
Smart Images

Figure CN224461558U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of household appliance technology, and in particular to a container assembly and a cooking device. Background Technology
[0002] Food processors are widely used in kitchen appliances. They mainly consist of food containers for collecting food and processing components for handling it. Some modern food processors also have a base installed under the food container to secure it to the table, preventing slippage during operation and improving stability. However, in practice, dirt easily accumulates at the connection between the base and the food container. Because the food container and base are generally fixed and cannot be disassembled, this creates cleaning dead zones that users cannot effectively clean. Utility Model Content
[0003] Therefore, it is necessary to provide a container component and cooking device to address the problem that the food containers and bases of some food processors on the market cannot be disassembled, resulting in cleaning dead spots.
[0004] A container assembly includes: a storage container having a first snap-fit structure formed at its bottom; and a mounting base including a base and two clamping arms. The base has a second snap-fit structure, and the two clamping arms extend upward from opposite ends of the base and cooperate with the base to form a mounting space. The storage container is detachably mounted on the storage container and located in the mounting space. The storage container is rotatable relative to the mounting base under external force and has at least a locked position and an unlocked position. When the storage container rotates to the locked position in a first direction, the first snap-fit structure engages with the second snap-fit structure to fix the storage container relative to the mounting base, and the two clamping arms clamp the storage container. When the storage container rotates to the unlocked position in a second direction, the first snap-fit structure can move away from the second snap-fit structure in a third direction to allow the storage container to leave the mounting space.
[0005] This application provides a container assembly in which the storage container is detachably mounted on a mounting base. On one hand, the storage container can be fixed to the operating position via the mounting base, effectively preventing slippage during operation and reducing operational errors. On the other hand, users can safely operate the mounting base to move and transport the container assembly, thus avoiding direct contact with the storage container and reducing the risk of burns from heating. Specifically, the bottom of the storage container has a first locking structure, and the base of the mounting base has a second locking structure. When the user rotates the storage container relative to the mounting base, the first and second locking structures work together to detach the storage container from the mounting base. This allows for easy separation of the storage container from the mounting base during cleaning, reducing cleaning dead zones and making cleaning the container assembly more convenient and efficient. Furthermore, the base also has two clamping arms. When the storage container is in the locked position relative to the mounting base, the two clamping arms work together to clamp the storage container, further reinforcing its positioning and effectively preventing deflection or loosening.
[0006] Specifically, the second direction is the opposite direction of the first direction.
[0007] In one embodiment, the top recess of the second snap-fit structure forms a positioning groove, and the inner sidewall of the positioning groove forms a circumferentially extending slot. The first end of the slot has an upward-facing opening. The first snap-fit structure includes a boss and a locking block. The boss is rotatably disposed in the positioning groove, and the locking block is disposed on the outer sidewall of the boss for engaging with the slot. When the storage container is in the locked position, the locking block is located at the second end of the slot, and its top wall abuts against the inner wall of the slot. When the storage container is in the unlocked position, the locking block is located at the first end of the slot and can leave the slot through the opening in the third direction. By adopting the above structure, the storage container can be locked and unlocked when rotated relative to the mounting base under the user's operation, which is simple, stable, and reliable. Specifically, when assembling the storage container with the mounting base, the user first aligns the locking block with the opening of the slot and lowers the storage container so that its protrusion fits into the positioning slot. At the same time, the locking block enters the slot, placing the storage container in the unlocked position. Then, the storage container is moved to the locked position along the first direction. At this point, the protrusion rotates, causing the locking block to move relative to the slot to its second end. This causes the top wall of the locking block to abut against the inner wall of the slot, creating a limiting effect. This ensures that the storage container cannot move upward and separate from the mounting base. When the storage container moves to the unlocked position again along the second direction, the locking block can move upward through the opening in the third direction and leave the slot, easily removing the storage container.
[0008] In one embodiment, the bottom wall of the positioning groove has a heat dissipation vent that connects to the outside. This helps to accelerate the heat dissipation and cooling of the outer wall of the storage container.
[0009] In one embodiment, at least one of the two clamping arms is provided with a stop, and a limiting rib is formed on the outer side wall of the storage container. When the storage container is in the locked position, the limiting rib abuts against the side wall of the stop to restrict the storage container from rotating in the second direction. By providing matching limiting ribs and stops on the storage container and clamping arms respectively, rotation of the storage container in the second direction can be prevented when it is in the locked position. This prevents the storage container from accidentally rotating due to user touch, which could cause it to uncontrollably move closer to the unlocked position and become loose, making the assembly of the storage container and the mounting base more stable and reliable.
[0010] In one embodiment, the stop is disposed on the upper part of the clamping arm, which is configured to elastically deform relative to the base under external force, thereby driving the stop away from the limiting rib. By employing this structure, the clamping arm can elastically deform relative to the base under external force. Thus, when the user places the storage container in the unlocked position by aligning the locking block with the opening, the clamping arm can deform under the pressure of the storage container, preventing any impact on the rotation of the storage container. When the storage container rotates to the locked position, the clamping arm can elastically reset and quickly clamp the storage container to further reinforce its positioning and installation, and allow the stop to engage with the limiting rib on the storage container. When the user needs to disassemble the storage container, by bending the clamping arm to cause elastic deformation, the stop can be moved away from the limiting rib, causing the limiting engagement between the stop and the limiting rib to disappear, allowing the storage container to smoothly rotate in the second direction to the unlocked position and leave the mounting base. Specifically, the stop is located on the upper part of the clamping arm, which allows the stop to be more easily moved outward away from the limiting rib by the clamping arm.
[0011] In one embodiment, the stop includes a stop block and a reinforcing rib. The stop block is disposed on the side of the clamping arm facing the mounting space. The two adjacent sidewalls of the reinforcing rib are respectively connected to the sidewall of the stop block and the clamping arm. When the storage container is in the locked position, the limiting rib abuts against the sidewall of the stop block to restrict the storage container from rotating in the second direction. The reinforcing rib prevents buckling deformation when the stop block and the limiting rib interfere with each other, which helps to enhance the stop block's resistance to bending and torsion, and improves the stop block's compressive stability.
[0012] In one embodiment, the reinforcing rib has a slope on the side away from the clamping arm, and the distance between the slope and the clamping arm gradually decreases in the direction away from the stop. The slope is used for sliding contact with the limiting rib. By adopting the above structure, when the storage container moves towards the locking position in the first direction, the slope on the reinforcing rib can slide and contact with the limiting rib, allowing the clamping arm to be compressed and elastically deformed, driving the stop to move outward. This avoids direct collision between the stop and the reinforcing rib, preventing wear and extending its service life.
[0013] In one embodiment, multiple ribs are formed on the side of the two clamping arms facing the mounting space. These ribs are spaced apart along the width of the clamping arms. When the storage container is in the locked position, the multiple ribs of the two clamping arms cooperate to clamp the storage container. By adopting the above structure, when the storage container rotates relative to the mounting base, the frictional resistance of the clamping arms on the storage container is reduced by the abutting interference between the ribs and the outer wall of the storage container, making the rotation of the storage container smoother. Simultaneously, the gaps formed between the multiple ribs facilitate heat dissipation from the outer wall of the storage container.
[0014] In one embodiment, a plurality of the ribs extend downward to the base. By employing the above structure, the connection between the base and the clamping arm can be further strengthened, and the elastic deformation range of the clamping arm can be further limited to avoid the clamping arm losing its clamping effect due to excessive deformation.
[0015] In one embodiment, an adsorption element is further included. The adsorption element is disposed on the outer bottom wall of the mounting base and is used to adhere to the container assembly at the installation position. The adsorption element allows the mounting base to be easily fixed in the installation position, ensuring that the mounting base does not move when the user rotates the storage container relative to it, thus enabling the storage container to rotate smoothly for installation and removal.
[0016] In one embodiment, an elastic damping element is also included, disposed between the storage container and the mounting base. The opposite sides of the elastic damping element can respectively abut against the storage container and the mounting base, and undergo elastic deformation under the compression of the storage container to dampen vibrations in the storage container. By utilizing the elastic damping element's elasticity, it acts as a "soft connection" in the vibration transmission path, not only absorbing some high-frequency vibration energy but also reducing the transmission of vibrations to external structures, thus lowering the noise level of the cooking device during operation. Furthermore, the elastic damping element is disposed on the first or second snap-fit structure, so that when the user assembles the storage container and the mounting base using the first or second snap-fit structure, the elastic damping element provides a buffer, preventing the user's view from being obstructed by the storage container, thus avoiding excessive force that could cause wear to the storage container or mounting base.
[0017] Preferably, the elastic damping element is made of silicone.
[0018] In one embodiment, the storage container includes a container body and a first snap-fit structure. The first snap-fit structure is disposed on the outer bottom wall of the container body. The base protrudes to the side facing the installation space to form an annular second snap-fit structure. The elastic damping member is annular and has an annular groove formed at its bottom. The top of the second snap-fit structure is adapted to the annular groove for installation. The side of the elastic damping member away from the second snap-fit structure can abut against the outer bottom wall of the container body.
[0019] In one embodiment, the sidewall of the annular groove is provided with a through hole opposite to the opening facing upwards in the slot.
[0020] In one embodiment, the two clamping arms are respectively formed into handle portions on the side away from the mounting space.
[0021] In one embodiment, at least a portion of the mounting base is made of an insulating material.
[0022] In one embodiment, the mounting base further includes a support leg assembly disposed on the side of the base away from the mounting space. This raises the base, allowing the positioning slot to better connect with the outside environment through the heat dissipation vents, accelerating heat exchange and cooling between the outer wall of the storage container and the air.
[0023] In one embodiment, the suction element includes a suction cup disposed on the side of the foot assembly away from the base.
[0024] A second aspect of this application provides a cooking apparatus.
[0025] A cooking apparatus includes the aforementioned container assembly. The cooking apparatus provided in the second aspect of this application, by employing any of the aforementioned container assemblies, allows the user to safely operate the mounting base to move or transport the cooking apparatus or container assembly after the container assembly absorbs heat generated by the heating element and its temperature rises during cooking. This avoids direct contact with the hot storage container, reducing the risk of burns. Simultaneously, the bottom of the storage container is provided with a first snap-fit structure, and the base of the mounting base has a second snap-fit structure. When the user rotates the storage container relative to the mounting base, the first and second snap-fit structures cooperate to achieve a detachable connection between the storage container and the mounting base. This allows for easy separation of the storage container from the mounting base during cleaning, reducing cleaning dead zones and making the cleaning of the cooking apparatus more convenient and efficient. Attached Figure Description
[0026] Figure 1 A first exploded view of a container assembly according to one embodiment;
[0027] Figure 2 A second exploded view of a container assembly according to one embodiment;
[0028] Figure 3 This is a first installation diagram of a storage container and mounting base according to one embodiment (when the storage container is in the unlocked position).
[0029] Figure 4 for Figure 3 Enlarged view of region A;
[0030] Figure 5 This is a second installation diagram of a storage container and mounting base according to one embodiment (when the storage container is in the locked position).
[0031] Figure 6 for Figure 5 Enlarged view of region B;
[0032] Figure 7 This is a cross-sectional view of a container assembly according to one embodiment (with the storage container in the locked position).
[0033] The correspondence between the reference numerals and the component names is as follows:
[0034] 1 Storage container, 11 First snap-fit structure, 111 Boss, 112 Snap-fit block, 12 Limiting rib, 13 Container body 13;
[0035] 2 Mounting base, 201 Positioning groove, 202 Slot, 2021 First end, 2022 Second end, 203 Heat dissipation vent, 21 Base, 211 Second snap-fit structure, 22 Clamping arm, 221 Protruding rib, 222 Handle part, 23 Stop part, 231 Stop block, 232 Reinforcing rib, 2321 Sloping surface, 24 Support foot;
[0036] 3. Elastic damping components, 301 annular groove, 302 through hole. Detailed Implementation
[0037] To better understand the above-mentioned objectives, features, and advantages of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.
[0038] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and therefore the scope of protection of the invention is not limited to the specific embodiments disclosed below.
[0039] The container components of some embodiments of the present invention are described below with reference to the accompanying drawings.
[0040] like Figures 1 to 6 As shown, this embodiment discloses a container assembly, including: a storage container 1, the bottom of which has a first snap-fit structure 11; and a mounting base 2, which includes a base 21 and two clamping arms 22. The base 21 has a second snap-fit structure 211, and the two clamping arms 22 extend upward from opposite ends of the base 21 and cooperate with the base 21 to form an installation space. The storage container 1 is detachably mounted on the storage container 1 and located in the installation space. The storage container 1 can rotate relative to the mounting base 2 under the action of an external force and has at least a locked position and an unlocked position. When the storage container 1 rotates to the locked position in a first direction, the first snap-fit structure 11 and the second snap-fit structure 211 engage to fix the storage container 1 relative to the mounting base 2, and the two clamping arms 22 cooperate to clamp the storage container 1. When the storage container 1 rotates to the unlocked position in a second direction, the first snap-fit structure 11 can move away from the second snap-fit structure 211 in a third direction to allow the storage container 1 to leave the installation space.
[0041] This application provides a container assembly in which a storage container 1 is detachably mounted on a mounting base 2. On one hand, the storage container 1 can be fixed to the operating position via the mounting base 2, effectively preventing it from sliding during operation and reducing operational errors. On the other hand, users can safely operate the mounting base 2 to move and transport the container assembly, thus avoiding direct contact with the storage container 1 and reducing the risk of burns from heating it at high temperatures. Specifically, the bottom of the storage container 1 is provided with a first snap-fit structure 11, and the base 21 of the mounting base 2 has a second snap-fit structure 211. When the user rotates the storage container 1 relative to the mounting base 2, the first snap-fit structure 11 and the second snap-fit structure 211 cooperate to achieve a detachable connection between the storage container 1 and the mounting base 2. During cleaning, the storage container 1 can be easily separated from the mounting base 2, reducing cleaning dead zones and making the cleaning of the container assembly more convenient and efficient. Furthermore, the base 21 is also provided with two clamping arms 22. When the storage container 1 is in the locked position and fixed relative to the mounting base 2, the two clamping arms 22 can cooperate to clamp the storage container 1 to further reinforce the positioning and installation of the storage container 1 and effectively prevent the storage container 1 from deflecting or loosening.
[0042] Specifically, the second direction is the opposite of the first direction.
[0043] like Figures 1 to 2As shown, in addition to the features of the above embodiments, this embodiment further defines: the top of the second snap-fit structure 211 is recessed to form a positioning groove 201, the inner sidewall of the positioning groove 201 is formed with a slot 202 extending circumferentially therein, the first end 2021 of the slot 202 has an upward opening, the first snap-fit structure 11 includes a boss 111 and a snap block 112, the boss 111 is rotatably disposed in the positioning groove 201, and the snap block 112 is disposed on the outer sidewall of the boss 111 for snap-fit engagement with the slot 202. When the storage container 1 is in the locked position, the snap block 112 is located at the second end 2022 of the slot 202 and its top wall abuts against the inner wall of the slot 202. When the storage container 1 is in the unlocked position, the snap block 112 is located at the first end 2021 of the slot 202 and can leave the slot 202 through the opening in a third direction. By adopting the above structure, the storage container 1 can be locked and unlocked when rotated relative to the mounting base 2 under the user's operation, which is simple, stable and reliable. Specifically, when the user assembles the storage container 1 with the mounting base 2, firstly, the locking block 112 is aligned with the opening of the slot 202, and the storage container 1 is moved down so that its protrusion 111 is fitted into the positioning slot 201. At the same time, the locking block 112 is moved into the slot 202, so that the storage container 1 is in the unlocked position. Then, the storage container 1 is moved further along the first direction to the locked position. At this time, the protrusion 111 rotates and drives the locking block 112 to move relative to the slot 202 to its second end 2022, so that the top wall of the locking block 112 abuts against the inner wall of the slot 202 to form a limiting effect, thereby ensuring that the storage container 1 cannot move upward and separate from the mounting base 2. When the storage container 1 moves again along the second direction to the unlocked position, the locking block 112 can leave the slot 202 upward through the opening in the third direction, easily realizing the removal of the storage container 1.
[0044] like Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bottom wall of the positioning groove 201 is provided with a heat dissipation port 203 communicating with the outside. This is beneficial to accelerate the heat dissipation and cooling of the outer wall of the storage container 1.
[0045] like Figures 1 to 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: at least one of the two clamping arms 22 is provided with a stop portion 23, and a limiting rib 12 is formed on the outer side wall of the storage container 1. When the storage container 1 is in the locked position, the limiting rib 12 abuts against the side wall of the stop portion 23 to restrict the storage container 1 from rotating in the second direction. By providing matching limiting ribs 12 and stop portions 23 on the storage container 1 and clamping arms 22 respectively, the storage container 1 can be prevented from rotating in the second direction when locked, so that the storage container 1 will not be accidentally rotated due to user touch, causing the storage container 1 to uncontrollably approach the unlocked position and become loose, making the assembly of the storage container 1 and the mounting base 2 more stable and reliable.
[0046] like Figure 2 , Figure 3 and Figure 4 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the stop portion 23 is provided on the upper part of the clamping arm 22, and the clamping arm 22 is configured to undergo elastic deformation relative to the base 21 under the action of external force, so as to drive the stop portion 23 away from the limiting rib 12. By adopting the above structure, the clamping arm 22 can undergo elastic deformation relative to the base 21 under the action of external force. Thus, when the user places the storage container 1 in the unlocked position by aligning the storage container 1 with the opening through the locking block 112, the clamping arm 22 can deform to a certain extent under the pressure of the storage container 1 to avoid affecting the rotation of the storage container 1. When the storage container 1 rotates to the locked position, the clamping arm 22 can elastically reset and quickly clamp the storage container 1 to further reinforce the positioning and installation of the storage container 1, and allow the stop part 23 to engage with the limiting rib 12 on the storage container 1. When the user needs to disassemble the storage container 1, by bending the clamping arm 22 to cause it to elastically deform, the stop part 23 can be moved away from the limiting rib 12, so that the limiting engagement between the stop part 23 and the limiting rib 12 disappears, and the storage container 1 can smoothly rotate in the second direction to the unlocked position and leave the mounting base 2. Specifically, the stop part 23 is located on the upper part of the clamping arm 22, which makes it easier for the stop part 23 to be driven outward away from the limiting rib 12 by the clamping arm 22.
[0047] like Figures 3 to 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the stop portion 23 includes a stop block 231 and a reinforcing rib 232. The stop block 231 is disposed on the side of the clamping arm 22 facing the installation space. The two adjacent sidewalls of the reinforcing rib 232 are respectively connected to the sidewall of the stop block 231 and the clamping arm 22. When the storage container 1 is in the locked position, the limiting rib 12 abuts against the sidewall of the stop block 231 to restrict the storage container 1 from rotating in the second direction. The setting of the reinforcing rib 232 can avoid buckling deformation when the stop block 231 contacts and interferes with the limiting rib 12, which can help enhance the bending and torsional resistance of the stop block 231 and improve the compressive stability of the stop block 231.
[0048] like Figures 3 to 6 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: a slope 2321 is formed on the side of the reinforcing rib 232 away from the clamping arm 22, and the distance between the slope 2321 and the clamping arm 22 gradually decreases in the direction away from the stop block 231. The slope 2321 is used for sliding contact with the limiting rib 12. By adopting the above structure, when the storage container 1 moves towards the locking position in the first direction, the slope 2321 on the reinforcing rib 232 can slide and contact with the limiting rib 12, so that the clamping arm 22 can be squeezed and deformed elastically, driving the stop block 231 to move outward, avoiding direct collision between the stop block 231 and the reinforcing rib 232 and causing wear, which is beneficial to extending its service life.
[0049] like Figure 1 and Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: multiple ribs 221 are formed on the side of the two clamping arms 22 facing the installation space, and the multiple ribs 221 are spaced apart along the width direction of the clamping arms 22. When the storage container 1 is in the locked position, the multiple ribs 221 of the two clamping arms 22 cooperate to clamp the storage container 1. By adopting the above structure, when the storage container 1 rotates relative to the mounting base 2, the frictional resistance of the clamping arms 22 on the storage container 1 can be reduced by the abutment interference between the ribs 221 and the outer wall of the storage container 1, so that the rotation of the storage container 1 can be smoother. At the same time, the gaps formed by the spaced arrangement between the multiple ribs 221 can facilitate heat dissipation from the outer wall of the storage container 1.
[0050] like Figure 1 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: a plurality of ribs 221 extend downward to the base 21. By adopting the above structure, the connection between the base 21 and the clamping arm 22 can be further strengthened, and the elastic deformation range of the clamping arm 22 can be further limited to avoid the clamping arm 22 from losing its clamping effect after excessive deformation.
[0051] In addition to the features of the above embodiments, this embodiment further includes an adsorption element disposed on the outer bottom wall of the mounting base 2. The adsorption element is used to adsorb onto the installation position of the container assembly. By providing the adsorption element, the mounting base 2 can be easily fixed in the installation position, ensuring that the mounting base 2 does not move when the user rotates the storage container 1 relative to the mounting base 2, allowing the storage container 1 to rotate smoothly for installation and removal.
[0052] like Figure 1 , Figure 2 and Figure 7 As shown, it also includes an elastic damping component 3, which is disposed between the storage container 1 and the mounting base 2. The opposite sides of the elastic damping component 3 can respectively abut against the storage container 1 and the mounting base 2, and undergo elastic deformation under the pressure of the storage container 1 to dampen vibrations in the storage container 1. By utilizing the elasticity of the elastic damping component 3, it acts as a "soft connection" in the vibration transmission path, not only absorbing some high-frequency vibration energy but also reducing the transmission of vibration to external structures, thus lowering the noise level of the cooking device during operation. Furthermore, the elastic damping component 3 is disposed on the first snap-fit structure 11 or the second snap-fit structure 211. Therefore, when the user assembles the storage container 1 and the mounting base 2 using the first snap-fit structure 11 or the second snap-fit structure 211, the elastic damping component 3 can form a buffer, preventing the user's view from being obstructed by the storage container 1 and thus avoiding excessive force that could cause wear to the storage container 1 or the mounting base 2.
[0053] Preferably, the elastic damping element 3 is made of silicone.
[0054] like Figure 1 and Figure 7 As shown, the storage container 1 includes a container body 1313 and a first snap-fit structure 11. The first snap-fit structure 11 is disposed on the outer bottom wall of the container body 1313. The base 21 protrudes to the side facing the installation space to form an annular second snap-fit structure 211. The elastic damping member 3 is annular and has an annular groove 301 formed at the bottom. The top of the second snap-fit structure 211 is adapted to the annular groove 301 and installed. The side of the elastic damping member 3 away from the second snap-fit structure 211 can abut against the outer bottom wall of the container body 1313.
[0055] like Figure 1 and Figure 7 As shown, the side wall of the annular groove 301 is provided with a through hole 302 opposite to the upward opening of the slot 202.
[0056] like Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the two clamping arms 22 are respectively formed on the side away from the installation space.
[0057] In addition to the features of the above embodiments, this embodiment further specifies that at least a portion of the mounting base 2 is made of heat-insulating material.
[0058] like Figure 1 and Figure 2 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the mounting base 2 also includes a support leg 24 assembly, which is disposed on the side of the base 21 away from the mounting space. This raises the base 21, allowing the positioning groove 201 to better connect with the outside through the heat dissipation vent 203, accelerating heat exchange and cooling between the outer wall of the storage container 1 and the air.
[0059] In addition to the features of the above embodiments, this embodiment further specifies that: the adsorption member includes a suction cup, which is disposed on the side of the support leg 24 assembly away from the base 21.
[0060] A second aspect of this application provides a cooking apparatus.
[0061] This embodiment discloses a cooking device including the aforementioned container assembly. The cooking device provided in the second aspect of this application, by employing any of the aforementioned container assemblies, allows the user to safely operate the mounting base 2 to move or transport the cooking device or container assembly after the container assembly absorbs heat generated by the heating element during cooking. This avoids direct contact with the high-temperature storage container 1, reducing the risk of burns. Simultaneously, the bottom of the storage container 1 is provided with a first snap-fit structure 11, and the base 21 of the mounting base 2 has a second snap-fit structure 211. When the user rotates the storage container 1 relative to the mounting base 2, the first snap-fit structure 11 and the second snap-fit structure 211 cooperate to achieve a detachable connection between the storage container 1 and the mounting base 2. During cleaning, the storage container 1 and the mounting base 2 can be easily separated, reducing cleaning dead zones and making the cleaning of the cooking device more convenient and efficient.
[0062] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.
[0063] The embodiments described above are merely illustrative of several implementations of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
Claims
1. A container component, characterized in that, include: Storage container (1), the bottom of which is formed with a first snap-fit structure (11); Mounting base (2), the mounting base (2) includes a base (21) and two clamping arms (22), the base (21) forms a second snap-fit structure (211), the two clamping arms (22) extend upward from opposite ends of the base (21) and cooperate with the base (21) to form an installation space, the storage container (1) is detachably mounted on the storage container (1) and located in the installation space, the storage container (1) can rotate relative to the mounting base (2) under the action of external force and has at least a locked position and an unlocked position, in the... When the storage container (1) is rotated to the locked position in the first direction, the first snap-fit structure (11) and the second snap-fit structure (211) engage to fix the storage container (1) relative to the mounting base (2), and the two clamping arms (22) clamp the storage container (1). When the storage container (1) is rotated to the unlocked position in the second direction, the first snap-fit structure (11) can move away from the second snap-fit structure (211) in a third direction to allow the storage container (1) to leave the mounting space.
2. The container assembly according to claim 1, characterized in that, The second snap-fit structure (211) has a recessed top forming a positioning groove (201). The inner wall of the positioning groove (201) has a circumferentially extending slot (202). The first end (2021) of the slot (202) has an upward-facing opening. The first snap-fit structure (11) includes a boss (111) and a locking block (112). The boss (111) is rotatably disposed in the positioning groove (201), and the locking block (112) is disposed on the boss (111). The outer wall is used to engage with the slot (202). When the storage container (1) is in the locked position, the card block (112) is located at the second end (2022) of the slot (202) and its top wall abuts against the inner wall of the slot (202). When the storage container (1) is in the unlocked position, the card block (112) is located at the first end (2021) of the slot (202) and can leave the slot (202) through the opening in the third direction.
3. The container assembly according to claim 1, characterized in that, At least one of the two clamping arms (22) is provided with a stop (23), and a limiting rib (12) is formed on the outer side wall of the storage container (1). When the storage container (1) is in the locked position, the limiting rib (12) abuts against the side wall of the stop (23) to restrict the storage container (1) from rotating in the second direction.
4. The container assembly according to claim 3, characterized in that, The stop (23) is disposed on the upper part of the clamping arm (22), and the clamping arm (22) is configured to undergo elastic deformation relative to the base (21) under the action of external force, so as to drive the stop (23) away from the limiting rib (12).
5. The container assembly according to claim 3, characterized in that, The stop (23) includes a stop (231) and a reinforcing rib (232). The stop (231) is disposed on the side of the clamping arm (22) facing the installation space. The two adjacent side walls of the reinforcing rib (232) are respectively connected to the side wall of the stop (231) and the clamping arm (22). When the storage container (1) is in the locked position, the limiting rib (12) abuts against the side wall of the stop (231) to restrict the storage container (1) from rotating in the second direction.
6. The container assembly according to claim 5, characterized in that, The reinforcing rib (232) has an inclined surface (2321) on the side away from the clamping arm (22). The distance between the inclined surface (2321) and the clamping arm (22) gradually decreases in the direction away from the stop block (231). The inclined surface (2321) is used for sliding contact with the limiting rib (12).
7. The container assembly according to claim 1, characterized in that, The two clamping arms (22) have multiple ribs (221) on one side facing the installation space. The multiple ribs (221) are distributed at intervals along the width direction of the clamping arms (22). When the storage container (1) is in the locked position, the multiple ribs (221) of the two clamping arms (22) cooperate to clamp the storage container (1).
8. The container assembly according to claim 7, characterized in that, Multiple of the ribs (221) extend downward to the base (21).
9. The container assembly according to any one of claims 1 to 8, characterized in that, It also includes an adsorption element disposed on the outer bottom wall of the mounting base (2), the adsorption element being used to adsorb onto the installation position of the container assembly; and / or It also includes an elastic damping element (3), which is disposed between the storage container (1) and the mounting base (2). The opposite sides of the elastic damping element (3) can respectively abut against the storage container (1) and the mounting base (2), and undergo elastic deformation under the compression of the storage container (1) to dampen the storage container (1); and / or The two clamping arms (22) each form a handle portion (222) on the side away from the mounting space; and / or At least a portion of the mounting base (2) is made of heat-insulating material.
10. A cooking apparatus, characterized in that, Includes the container component as described in any one of claims 1 to 9.