CN218960224U - Rotary snack container with lunch box - Google Patents

Abstract

A rotary snack container with cutlery box includes a plurality of discrete storage areas, a lid with an opening, a drive mechanism for rotating the tray, and a removable cutlery box. The lunch box is provided with a concave position for accommodating the tray, the tray is driven by the driving mechanism to rotate, and after each rotation of the tray, the single storage area is in a state available for a user to acquire. The cutlery box is adapted to the rotary tray and provides additional storage space for food.

Description

Rotary snack container with lunch box

Technical Field

The present utility model relates to snack containers, and in particular to a rotating snack container with different storage compartments, with a lunch box.

Background

In the prior art, there are different transmission conversion devices to convert linear motion into twisting or rotational/angular motion, and such transmission conversion devices are also commonly used in the field of food containers and dispensing devices so that snack foods can be selectively provided. However, such containers with a switching device often allow snack foods to be easily spilled from the container while not providing any interest to the user.

Disclosure of Invention

The embodiment of the application discloses a rotary snack container with a lunch box, which comprises a tray, a cover, a driving mechanism and a detachable lunch box; the tray includes one or more storage areas; the cover includes an opening; the driving mechanism comprises a rotating structure; the rotating structure comprises a base and a pipe body; the tube body comprises a longitudinal channel and a transverse channel; the detachable lunch box comprises a concave position; the tray is placed in the concave position; the cover is connected with the tray; the longitudinal channel is connected with the transverse channel, so that the tray can be selectively rotated; the driving mechanism can be used for driving the tray to rotate relative to the cover so that the storage area is correspondingly matched with the opening.

Further, in the above embodiment, the cover includes a fixing piece; the detachable lunch box comprises a retention rim piece; the retention edge piece comprises a clamping groove matched with the fixing piece; the retention rim piece is arranged on the concave position; the retention tabs are folded inwardly and fit into the cap.

Further, in the above embodiments, the removable cutlery box comprises one or more storage compartments for holding food; the storage compartment may be opened or closed.

Further, in the above embodiment, at least one of the storage compartments is adjacent to the recess.

Further, in the above embodiment, one of the storage compartments is located below the recess.

Further, in the above embodiment, the driving mechanism further includes a slide pin; the pipe body comprises a step; the sliding pin extends towards the inner side and can be matched with the longitudinal channel and the transverse channel, so that the tray can rotate relative to the cover, and one storage area is correspondingly matched with the opening; the step is provided where the longitudinal channel meets the transverse channel, thereby preventing the slide pin from sliding down into the longitudinal channel.

Further, in the above embodiment, the driving mechanism includes a spring arm; the sliding pin is arranged on the elastic arm; and when the sliding pin slides upwards along the longitudinal channel and passes through the step, the elastic arm can apply elastic force to the sliding pin towards the inner side direction, so that the sliding pin and the step are dislocated, and the step can block the sliding pin.

Further, in the above embodiment, the detachable lunch box includes two or more storage compartments and a mounting buckle; more than two of the storage compartments are stacked one above the other; and adjacent said storage compartments are removably secured together by said mounting tabs.

Further, in the above embodiment, the driving mechanism is a plunger type key; when the driving mechanism is pressed, the tray rotates so that one of the storage areas moves to a position corresponding to the opening; and during rotation of the tray, different storage areas can be correspondingly matched with the openings in sequence.

Further, in the above embodiment, the cover includes a chute; the driving mechanism comprises a key; the key comprises a sliding clamping piece matched with the chute; the key is elastically connected with the rotating structure; the sliding clamping piece can move up and down along the sliding groove, so that the key can only move linearly.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, a description of implementation of specific embodiments will be made in conjunction with the following drawings. It is to be understood that the scope of protection of the present application is not limited to the specific arrangements disclosed in the drawings.

FIG. 1 is a schematic structural view of one embodiment of a rotating snack container without a cutlery box of an embodiment of the present application.

Figure 2 is an exploded view of one embodiment of a rotating snack container without a cutlery box of an embodiment of the present application.

Fig. 3 is a schematic structural view of an implementation of the tray of the example of the present application.

Fig. 4 is an enlarged partial schematic view of fig. 3.

Fig. 5 is a schematic structural view of one implementation of a storage bowl of an embodiment of the present application.

Fig. 6 is a schematic structural view of an implementation of the cap of the example of the present application.

Fig. 7 is a schematic structural view of one implementation of the storage bowl and lid of the example of the present application.

Fig. 8 is a schematic structural view of an implementation of the driving mechanism of the embodiment of the present application.

Fig. 9 is a schematic structural view of a rotating structure according to an embodiment of the present application.

Fig. 10 is a schematic side view of an implementation of a turning structure of an embodiment of the present application.

Fig. 11 is a schematic bottom structure of a rotating structure according to an embodiment of the present application.

FIG. 12 is a schematic bottom structural view of one implementation of a rotating snack container without a cutlery box of the present embodiment.

FIG. 13 is a schematic side view of one embodiment of a rotating snack container without a cutlery box of the present embodiment.

Figure 14 is a schematic side view of one implementation of a rotating snack container without a cutlery box of an embodiment of the present application.

FIG. 15 is a schematic top structural view of one embodiment of a rotating snack container without a cutlery box of the present examples.

FIG. 16 is a schematic structural view of one embodiment of a rotating snack container with cutlery box of the present examples.

Fig. 17 is a schematic view of the structure of fig. 16 after the lid corresponding to the storage compartment is opened.

Fig. 18 is a schematic view of the entire inner packing compartment with the entire lid of fig. 16 removed.

Fig. 19 is an exploded view of the structure of fig. 16.

FIG. 20 is a schematic structural view of another embodiment of a rotating snack container with cutlery box of an embodiment of the present application.

Fig. 21 is a schematic view of the structure of fig. 20 after the lid corresponding to the packing compartment is opened.

Fig. 22 is a schematic view of the entire inner packing compartment after the entire lid of fig. 20 is removed.

Fig. 23 is an exploded view of the structure of fig. 20.

FIG. 24 is a schematic structural view of another implementation of a rotating snack container with cutlery box of an embodiment of the present application.

Fig. 25 is an enlarged partial schematic view of fig. 24.

Fig. 26 is a schematic view of the structure of fig. 16 with all the covers removed.

Detailed Description

Preferred embodiments of the present application will be described below with reference to the accompanying drawings.

Embodiments of a rotating snack container with a cutlery box made in accordance with the teachings of the present application will be described below. Alternative embodiments will also be described. The specific details are set forth in the following exemplary embodiments in connection with the accompanying drawings. Figures 1-26 specifically depict various components of a rotating snack container with a cutlery box, such as a storage system 10. The storage system 10 can allow only one of the storage compartments of the tray to be in a state of being accessible to a user at a time by selectively rotating the tray such that the storage compartments correspondingly mate with the openings of the lid. The storage system 10 can be combined with two exemplary cutlery boxes disclosed herein that can hold additional food.

The storage system 10 includes a tray 14 for holding snack foods. The tray 14 may be a circular dish-shaped structure. The tray 14 includes a surface 16 and one or more storage compartments are disposed on the surface 16, such as a storage area 18. The different storage areas 18 are separated by partition walls 20. The storage area 18 may take a variety of shape configurations including, but not limited to, oval, rectangular, triangular, square, polygonal, irregular, uniformly shaped, unevenly shaped, asymmetrically shaped, staggered, and/or tapered. As shown in fig. 3, the storage area 18 is circumferentially disposed about the central opening 22. As shown in fig. 3-4, the snack is placed within the storage area 18. The dividing wall 20 divides the snack into different portions. The tray 14 is selectively rotated so that a user can access one of the storage areas 18. The tray 14 includes an outer bottom surface, thereby forming a space.

In some embodiments, the tray 14 is placed in the storage bowl 24. As shown in fig. 5, the storage bowl 24 includes an inner bottom surface and is provided with a projection, such as a shaft 26. The shaft 26 is spatially adapted to the outer bottom surface of the tray 14 to facilitate rotation of the tray 14 relative to the storage bowl 24.

A housing 30 is provided at the opening 22. The housing 30 includes a bottom surface 32 and side walls 34. The housing 30 may be used to house a drive mechanism 80. The housing 30 is located in a central region of the tray 14 such that the storage area 18 can be circumferentially distributed about the housing 30. The bottom surface 32 of the housing 30 includes an upwardly extending extension shaft 36 and bosses 38 circumferentially equally spaced about the extension shaft 36. Adjacent bosses 38 are separated by a gap 37. Each boss 38 includes a first ramp 40 and a second ramp 42. The first inclined surface 40 and the second inclined surface 42 intersect at a tip 44. In actual installation, the drive mechanism 80 may move across the end 44 of the boss 38, along the first ramp 40 of the boss 38 and the second ramp 42 of an adjacent boss 38, into the gap 37 of two adjacent bosses 38. The provision of the inclined first and second inclined surfaces 40, 42 allows the drive mechanism 80 to more easily snap into the gap 37 between adjacent bosses 38 during installation. When a portion of the drive mechanism 80 is located in the gap 37, the drive mechanism 80 is releasably secured to the tray 14, thereby preventing rotation of the tray 14. In some embodiments, the bosses 38 are equally spaced. In some embodiments, the number of bosses 38 is consistent with the number of storage regions 18, thereby facilitating a corresponding mating of the storage regions 18 with the openings 52.

To preserve the freshness of the snack and to avoid spilling the snack from the tray 14 during transport, the tray 14 includes a lid 50 as shown. The user can see the treat through the cover 50. The cover 50 may be configured to conform to the shape of the tray 14, such as a circle.

In some embodiments, the shaft 26 of the storage bowl 24 mates with the protruding shaft 36 of the tray 14. Specifically, when the tray 14 is placed within the storage bowl 24, the hollow extension shaft 36 is nested about the shaft body 26 such that the tray 14 is rotatably coupled within the storage bowl 24. As the tray 14 rotates, the extension shaft 36 rotates about the shaft body 26.

In some embodiments, the housing 30 of the tray 14 has a through hole in a central location, and the shaft 26 of the storage bowl 24 extends through the through hole of the tray 14 when installed, thereby allowing the tray 14 to be rotatably coupled within the storage bowl 24.

The lid 50 includes an opening 52 sized to fit within the storage area 18 to facilitate access to the snack by a user. The lid 50 also includes a hinged lid 54 disposed in the opening 52. Hinged lid 54 is adapted to fit within storage area 18 to allow a user to obtain a snack. The hinged lid 54 is rotatable about a hinge 56 to effect switching of the hinged lid 54 between the closed and open positions. The hinged lid 54 also includes a latch 58, the latch 58 and the tray 14 being coupled together in a variety of ways including, but not limited to, an integral connection, a friction fit, a snap fit, an interlocking connection, a mesh, a joggle, a clip, a hook, a scarf, a threaded connection, a magnetic connection, and a keyway connection.

The cover 50 includes a surface 60 provided with an opening 62. The opening 62 is adapted to the housing 30 for receiving the drive mechanism 80. The cover 50 is secured to a portion of the drive mechanism 80 such that the tray can be rotated relative to the cover 50 to expose a single storage area 18 upon actuation of the drive mechanism 80. In some embodiments, the drive mechanism 80 includes a resilient tab 82 that mates with the cap 50 to allow the cap 50 to be releasably secured to the drive mechanism 80 to prevent rotation of the drive mechanism 80 relative to the cap 50. In some embodiments, the cap 50 and the drive mechanism 80 may be coupled together in different ways, including, but not limited to, an integral connection, a friction fit, a snap fit, an interlocking connection, a mesh, a dovetail, a clip, a hook, an scarf, a threaded connection, a magnetic connection, and a keyway connection.

The drive mechanism 80 includes a key 90, a collar 92, a rotating structure 94, and a housing. The key 90 may be of circular configuration and can be depressed to bring about the drive mechanism 80. In some embodiments, the drive mechanism is a plunger key.

The collar 92 is placed in the space of the key 90. The collar 92 includes resilient arms 100. The arm 100 includes an inwardly projecting slide pin 104. The slide pin 104 is adapted to engage a portion of the rotational structure 94 to effect selective rotation. The key 90 is switchable between a released state and a locked state. In the released state, the key 90 is biased upwardly and can be axially compressed by the user to drive the rotational structure 94 for rotation. In the locked state, the key 90 is fixed in a pressed state to prevent rotation.

As shown in fig. 9-11, the rotating structure 94 includes a base 106 and a tubular body 108. The base 106 includes a cavity 110 that mates with the extension shaft 36 for rotating the tray 14. The base 106 includes protruding ends 112 that are equally spaced circumferentially around the cavity 110. The protruding end 112 extends distally and fits into the gap 37 of the housing 30. Between adjacent ones of the projecting ends 112 is a drive region 114 for receiving the boss 38. When installed, the protruding end 112 of the base 106 of the rotating structure 94 is captured in the gap 37 between the bosses 38 of the tray 14, i.e., the rotating structure 94 is relatively fixed to the tray 14. So that the rotating structure 94 can drive the tray 14 to rotate synchronously when the rotating structure 94 is driven to rotate.

The tube 108 includes an inner surface 120 and a cavity 122 defined by the inner surface 120. The cavity 122 is compatible with a resilient structure, such as a spring 95. The elastic structure is elastically connected with the key 90. The provision of the resilient structure allows the key 90 to return to the released state each time the tray 14 is rotated.

In some embodiments, the tube 108 has an upwardly extending spring mounting post in the cavity 122 thereof over which the spring 95 is mounted. The key 90 is mounted on the tube 108 and is resiliently coupled to the spring 95. After the key 90 is pressed to rotate the tray 14, the spring 95 may apply an upward restoring force to the key 90, so that the key 90 returns to its original position to wait for the next pressing.

The tube 108 includes an outer surface 130 with a plurality of longitudinal channels 132 connected to transverse channels 134. The at least one longitudinal channel 132 includes a ramp that slopes from the distal end to the proximal end. The at least one transverse channel 132 includes a ramp that slopes from the proximal end to the distal end. The proximal portion 150 of the transverse channel 132 is provided with a sidewall 154 for avoiding unnecessary rotation of the drive mechanism 80. For example, during actuation, when key 90 is depressed in direction A of FIG. 8, slide pin 104 moves along side wall 154 and transverse channel 134, and rotational structure 94 rotates in direction B of FIG. 8 (counterclockwise) to simultaneously rotate tray 14. When the key 90 is released in the direction C of FIG. 8, the slide pin 104 will move along the longitudinal channel 132 and into the proximal portion 150 of the adjacent transverse channel 132 and will mate with the side wall 154 thereof.

In some embodiments, as shown in FIG. 9, a step 138 is provided at the junction of the longitudinal channel 132 and the transverse channel 134, the step being configured such that the slide pin cannot enter the longitudinal channel 132 downwardly and thus only enter the transverse channel 134 to rotate the rotating structure 94. Specifically, during actuation, when key 90 is depressed in direction A of FIG. 8, slide pin 104 slides downwardly until it encounters a step and is then blocked by step 138 and enters transverse channel 134, and rotational structure 94 then rotates in direction B of FIG. 8 (counterclockwise) to simultaneously rotate tray 14. When the key 90 is released in the direction C of fig. 8, the sliding pin 104 provided on the elastic arm 100 slides upward along the longitudinal channel 132, and after the sliding pin 104 slides over the step 138, the elastic arm 100 continues to exert an inward force on the sliding pin 104, so that the sliding pin 104 moves inward, and the sliding pin 104 is dislocated from the step 138. When the key 90 is next pressed, the step 138 blocks the slide pin 104 that has moved inward from continuing to move downward, thereby entering the transverse channel 134 along the step 138.

In some embodiments, the housing 30 of the cover 50 is provided with a sliding slot, and the key 90 is provided with a sliding clip fitting with the sliding slot. The sliding clip can move up and down along the chute, so that the key 90 can only perform up and down linear motion, but cannot perform circumferential motion. Such an arrangement can avoid the tray 14 not being able to reach a predetermined rotation angle because the keys 90 do not perform an unnecessary circumferential movement. The sliding clamping member can be integrally formed with the elastic piece 82 and also be separately arranged on the key 90. The mating slide slots and slide tabs also allow the opening in the lid 50 to correspond to the storage area 18 of the tray 14 after the entire rotating snack container is installed.

In some embodiments, the tray 14 is provided with five storage areas 18, and one fifth of each rotation 360 ° may be selected, i.e., 72 ° each rotation. Such a selective 72 ° rotation may be achieved by a collar 92 with five slide pins 104. The rotary structure 94 is correspondingly provided with five longitudinal channels 132 and transverse channels 134 equally spaced circumferentially around the rotary structure 94.

The storage system 10 is removable to facilitate cleaning and storage of snack foods. For example, the drive mechanism 80 is rotatably mounted in the cover 50, and the housing 30 and the drive mechanism 80 are mounted with the cover 50 by means of the elastic piece 82. The tray 14 is placed in the storage bowl 24 and the tray 14 is free to rotate therein. The base 106 is placed inside the housing 30 such that the drive region 114 is in driving connection with the boss 38 and the lid 52 is connected with the storage bowl 24.

When the entire storage system 10 is installed, the drive mechanism 80 is activated, which in turn causes the tray 14 to rotate a predetermined or selected angle, thereby placing the desired storage area 18 in contact with the user while the other storage compartments remain closed. When the storage compartment contains snacks, a certain interest can be experienced by the user, in particular a child, by autonomously selecting to obtain different snacks for tasting. It should be noted that if the storage compartment contains snack foods, even if the entire device is inverted, there is a risk that only the open storage compartment will spill.

The snack rotator of embodiments of the present application can secure additional food bowls/containers/trays/cutlery boxes thereto in a variety of ways. In the embodiment of fig. 16-19 and 24, the cutlery box includes a recess integrally connected and adapted to receive a rotating snack tray. In the embodiment of fig. 20-23, the rotating tray may be provided on a stacked storage compartment for storing food. In the above embodiments, the rotary tray is easy to install and disassemble.

The container of the embodiments can be used as a lunch box for storing food, and is particularly suitable for preschool children or older children. However, the container of the embodiments may be used by adults. The container in the embodiment is simple in installation mode, and even a preschool child can easily operate the container. The container may also include a rubber or silicone gasket to provide a gas-tight seal between the container and the lid. The container may be made of different materials including, but not limited to, plastic, wood, metal, glass, and other hard, food-accessible materials. The container may take on different shapes including, but not limited to, a cylindrical shape, a bowl shape, or a rectangular shape. The container may be transparent or opaque. The container may be attached to the lunchbox in a variety of ways including, but not limited to, hinges, magnetic attachment, clamps, snap fit, flexible structure, elastic band, or other structure that ensures secure attachment of the lid to the snack rotator.

As in the embodiment of fig. 16-19, the rotating tray is placed on a recess 200 of an attached container 202, the attached container 202 being able to hold more food or snack items. The handle 204 is attached to the container 202 to make the entire device more portable. Near the well 200 is a container 202. The container 202 is provided with a container lid 206 openable by a hinge member 208 so that an inner space containing food or snack can be exposed. A rim 210 is provided on a rim 212 of the container 202 so that the container lid 206 can be easily opened by the hinge member 208.

In some embodiments, as shown in fig. 24, in order to make the cutlery box suitable for different people, the cutlery box further comprises a containing tray 203 with different storage compartments, and the containing tray 203 is detachably mounted in the container 202. Such a design allows the user to choose different containment trays 203 according to different needs. And the detachable containing plate 203 is easy to detach, which is beneficial to cleaning. When installed, the hinge member 208 may detachably secure the container cover 206, the receiving tray 203, and the container 202 together when the container cover 206 is covered on the receiving tray 203. In still other embodiments, a sealing gasket 205 is also provided between the containment disk 203 and the container lid 206.

In some embodiments, as shown in fig. 24, the recess 200 of the attached container 202 is provided with a retention tab 201 that fits into and curves inwardly of the cap 50. In actual use, the entire rotary zero hamper is snapped into the recess 200 and the retention tabs 201 contact the lid 50, thereby limiting the rotary zero hamper so that the rotary zero hamper does not fall out of the recess 200.

In some embodiments, as shown in fig. 24, the cover 50 is provided with a first fixing piece 51, and the storage bowl 24 is provided with a second fixing piece 241, and the recess 200 of the container 202 is provided with a clamping groove 207 adapted to the first fixing piece 51 and the second fixing piece 241. In actual use, the lid is mounted on the storage bowl 24 and the first fixing piece 51 and the second fixing piece 241 are adapted to snap into the card slot 201 together. The arrangement of the first fixing piece 51, the second fixing piece 241 and the clamping groove 207 allows the whole rotary snack box to be more firmly mounted on the container 202. In addition, the first fixing piece 51 and the second fixing piece 241 protruding from the fixing edge piece 201 enable a user to easily remove the rotary snack box from the concave position 200, and when the rotary snack box is detached, the user only needs to apply a pushing force to the first fixing piece 51 and the second fixing piece 241 of the rotary snack box along the clamping groove 207, so that the rotary snack box can be pushed out from the concave position 200. In some embodiments, the first fixing piece 51 may be provided only on the cover 50 or the second fixing piece 241 may be provided only on the storage bowl 24.

In some embodiments, as shown in fig. 25, a fixing clip 2071 is further disposed on the slot 207, specifically, after the first fixing piece 51 and the second fixing piece 241 are snapped into the slot 207, a user applies a circumferential force to the first fixing piece 51 and the second fixing piece 241, so that the first fixing piece 51 and the second fixing piece 241 can be snapped into the fixing clip 2071. The provision of the fixed catch 2071 further increases the strength of the connection of the rotary zero-food case to the female position 200. When the rotary zero-food box needs to be disassembled, a reverse circumferential force is applied to the first fixing piece 51 and the second fixing piece 241 to separate from the fixing clamping position 2071, and then an upward pushing force along the clamping groove 207 is applied to the rotary zero-food box, so that the rotary zero-food box is pushed out of the concave position 200.

Figures 20-23 illustrate an alternative embodiment in which the rotating tray is placed on a barrel lunch box 214. The cutlery box 214 may be cylindrical and have a top edge 216. A handle 218 is provided on the top edge 216 to enhance portability of the entire barrel lunch box. The barrel lunch box has one or more storage compartments 220 stacked together, adjacent storage compartments 220 being separated by a mounting structure 222. The top edge 216 forms a surrounding space 224 that securely receives the tray.

In some embodiments, the mounting structure 222 is a mounting clasp. The mounting buckles are hinged on the storage compartments, and when adjacent storage compartments are stacked, the mounting buckles of the storage compartments positioned below can be clamped into the clamping positions of the storage compartments positioned above, so that the upper and lower adjacent storage compartments are fixed. When the adjacent storage compartments are required to be disassembled, the installation buckles of the storage compartments positioned above are only required to be manually pulled outwards, so that the installation buckles are released from the clamping positions of the storage compartments positioned above, and the adjacent storage compartments can be separated.

The technical solutions of the present application may be implemented in combination with other features not disclosed in the embodiments of the present application.

In this application, the embodiments discussed are presented as a mere summary. The reader should appreciate that this disclosure does not show all possible embodiments, and that related alternative embodiments are implicitly included in this disclosure. Furthermore, this disclosure does not fully describe all of the common properties to which this application pertains nor does it explicitly indicate that each technical feature is a representative feature or equivalent feature. Again, these are implicitly included in this disclosure. When the term pointing device is discussed in this application, it is also implicitly meant that each feature of this device plays a corresponding role. It should also be understood that variations or substitutions within the technical scope of the disclosure of the present application are intended to be covered by the scope of the present application without departing from the inventive concept of the present application.

Furthermore, the various features of the application may be modified or replaced accordingly, and the scope of protection of the application should be understood to encompass each such modification or replacement. This disclosure is to be understood to include each such alternative, either structural or methodological embodiments, or only the variations or alternatives of each component involved in such embodiments. In particular, it is to be understood that, for the technical features disclosed in the present application, the related structural terms may be replaced by equivalent structural terms that can perform the same function. Such equivalent, broader, and even more generic terms should be considered to be encompassed in the description of each structure or function. These terms may be substituted as needed to indicate the broader scope of protection implied by the present application. It is to be understood that all functions mentioned may be represented as a means for implementing the functions or a structure for implementing the functions. Similarly, each feature disclosed encompasses the disclosure of functionality enabled by the structure. Such variations and alternative terms are to be understood to be expressly included in the description of this application.

Claims (10)

1. A rotating snack container with cutlery box, characterized in that: comprises a tray, a cover, a driving mechanism and a detachable lunch box; the tray includes one or more storage areas; the cover includes an opening; the driving mechanism comprises a rotating structure; the rotating structure comprises a base and a pipe body; the tube body comprises a longitudinal channel and a transverse channel; the detachable lunch box comprises a concave position;

the tray is placed in the concave position;

the cover is connected with the tray;

the longitudinal channel is connected with the transverse channel, so that the tray can be selectively rotated;

the driving mechanism can be used for driving the tray to rotate relative to the cover so that the storage area is correspondingly matched with the opening.

2. The rotating snack container with cutlery box of claim 1 wherein: the cover comprises a fixing piece; the detachable lunch box comprises a retention rim piece; the retention edge piece comprises a clamping groove matched with the fixing piece;

the retention rim piece is arranged on the concave position;

the retention tabs are folded inwardly and fit into the cap.

3. The rotating snack container with cutlery box of claim 1 wherein: the removable cutlery box comprises one or more storage compartments for holding food;

the storage compartment may be opened or closed.

4. The rotating snack container with cutlery box of claim 3 wherein:

at least one of the storage compartments is located adjacent to the recess.

5. The rotating snack container with cutlery box of claim 3 wherein:

at least one of the storage compartments is located below the recess.

6. The rotating snack container with cutlery box of claim 1 wherein: the driving mechanism further comprises a sliding pin; the pipe body comprises a step;

the sliding pin extends towards the inner side and can be matched with the longitudinal channel and the transverse channel, so that the tray can rotate relative to the cover, and one storage area is correspondingly matched with the opening;

the step is provided where the longitudinal channel meets the transverse channel, thereby preventing the slide pin from sliding down into the longitudinal channel.

7. The rotating snack container with cutlery box of claim 6 wherein: the driving mechanism further comprises a spring arm;

the sliding pin is arranged on the elastic arm; and

when the sliding pin slides upwards along the longitudinal channel and passes through the step, the elastic arm can apply elastic force to the sliding pin towards the inner side direction, so that the sliding pin and the step are dislocated, and the step can block the sliding pin to prevent the sliding pin from sliding downwards into the longitudinal channel.

8. The rotating snack container with cutlery box of claim 1 wherein: the detachable lunch box comprises more than two storage compartments and mounting buckles;

more than two of the storage compartments are stacked one above the other; and

adjacent ones of the storage compartments are detachably secured together by the mounting clasp.

9. The rotating snack container with cutlery box of any of claims 1-8 wherein:

the driving mechanism is a plunger type key;

when the driving mechanism is pressed, the tray rotates so that one of the storage areas moves to a position corresponding to the opening; and

during rotation of the tray, different storage areas can be matched with the openings in sequence.

10. The rotating snack container with cutlery box of claim 9 wherein: the cover comprises a chute; the driving mechanism comprises a key; the key comprises a sliding clamping piece matched with the chute;

the key is elastically connected with the rotating structure;

the sliding clamping piece can move up and down along the sliding groove, so that the key can only move linearly.

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