A rotating pop-up candy box
The rotating pop-up candy box design solves the problems of candy's perishability and lack of fun, enabling individual candies to pop out and enhancing interactive fun, while providing a safe and visually impactful user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BONA FOOD (ZHONGSHAN) CO LTD
- Filing Date
- 2025-08-15
- Publication Date
- 2026-06-09
AI Technical Summary
Existing candy boxes are prone to spoilage due to dust and moisture when opened, and lack interactive fun, making it difficult to meet the needs of children.
Design a rotating pop-up candy box, which adopts a rotating body and box structure. The candy is popped out one by one through a stepping damping component and a pop-up component. Combined with a synchronous rotation structure and a sealing design, the candy is isolated from the outside world and the fun is enhanced.
It effectively prevents candy from coming into contact with the outside world, reduces the risk of spoilage, prevents multiple candies from falling at the same time, enhances the fun of use, allows you to judge the rotation range by feel, and provides visual impact.
Smart Images

Figure CN224336140U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a candy box, and more particularly to a rotating pop-out candy box. Background Technology
[0002] In daily life, candy is a widely loved snack, and the design of its packaging not only affects the product's storage safety but also directly relates to the user's experience and enjoyment. Currently, most candy boxes on the market use flip-top, pull-out, or snap-on structures. These designs share a common problem in practical use: when the candy box is opened, the candy is completely exposed, making it easily susceptible to dust and moisture, leading to spoilage. Furthermore, if the candy box is tilted at an improper angle, multiple candies may slip out simultaneously, resulting in waste.
[0003] In addition, existing candy boxes lack interactive fun, and most only have basic storage functions, which makes it difficult to meet the needs of consumers, especially children, for product playability and interactivity.
[0004] Therefore, as the consumer market continues to demand higher levels of product experience, how to overcome the defects in the existing product structure and design a candy box that can make candy easy to take out, ensures airtight storage, and increase the fun of use has become an important issue that needs to be addressed by those skilled in the art. Utility Model Content
[0005] This invention overcomes the shortcomings of the above-mentioned technologies and provides a rotating pop-up candy box.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] A rotating pop-up candy box includes a circular box body 1 with its opening facing upwards and a rotating body installed in the box body 1. The rotating body is rotatable relative to the box body 1. The box body 1 has a first candy outlet 11 located on its side wall. The rotating body has a plurality of circumferentially evenly distributed candy storage compartments 31. The candy storage compartments 31 are used to place candies 4 one-to-one. The outer side of each candy storage compartment 31 has a second candy outlet 32. A stepping damping component 6 is provided between the box body 1 and the rotating body. The stepping damping component 6 is used to generate a stepping sensation when the box body 1 and the rotating body rotate relative to each other. The box body 1 also has a pop-out component 7. The pop-out component 7 is used to pop the candies 4 in the corresponding candy storage compartment 31 out of the box body 1 when any second candy outlet 32 rotates to align with the first candy outlet 11.
[0008] Preferably, the rotating body includes a cover 2 that is also circular at the opening of the box body 1 and a rotating seat 3 that is coaxially disposed inside the box body 1 and can rotate relative to the box body 1. The cover 2 and the rotating seat 3 are connected by a synchronous rotation structure 5 so that the rotating seat 3 can be rotated by rotating the cover 2. The sugar storage compartment 31 is disposed on the rotating seat 3, and the stepping damping component 6 is disposed between the box body 1 and the rotating seat 3.
[0009] Preferably, the stepping damping assembly 6 includes a through groove 61 disposed on the rotating seat 3 and extending vertically. A steel ball 62 that can move up and down along the through groove 61 is placed in the through groove 61. The diameter of the lower opening of the through groove 61 is smaller than the diameter of the steel ball 62 to prevent the steel ball 62 from falling down out of the through groove 61. A sealing block 63 for closing the through groove 61 is fixed above the through groove 61. A first reset spring 64 is provided between the sealing block 63 and the steel ball 62. The first reset spring 64 is used to continuously apply a downward reset force to the steel ball 62. The stepping damping assembly 6 also includes a number of positioning grooves 65 disposed on the bottom surface of the inner box 1 and evenly distributed circumferentially. The number of positioning grooves 65 is the same as the number of sugar storage compartments 31 or twice the number of sugar storage compartments 31. When the through groove 61 rotates with the rotating seat 3 to above any positioning groove 65, the lower part of the steel ball 62 can partially protrude out of the through groove 61 and fall into the corresponding positioning groove 65 to obstruct the rotation of the rotating seat.
[0010] Preferably, the synchronous rotation structure 5 includes a plurality of slots 51 disposed on the upper surface of the rotating base 3, and a plurality of pins 52 extending downward corresponding to the positions of the slots 51 on the lower surface of the cover 2. The pins 52 are used to insert into the slots 51 when the cover 2 is placed on the box 1.
[0011] Preferably, the sugar storage compartment 31 is provided with an open candy inlet 34 to facilitate the placement of candy 4 into the sugar storage compartment 31. The lower surface of the cover 2 is also provided with a plurality of sealing protrusions 21 that correspond one-to-one with the candy inlets 34 and have the same shape and outline. The sealing protrusions 21 are used to be embedded in the candy inlets 34 when the cover 2 is placed on the box body 1.
[0012] Preferably, the pop-out assembly 7 includes a pop-out groove 71 extending outward from the first sugar outlet 11 within the housing 1. A pop-out top block 72, movable along the pop-out groove 71, is positioned within the pop-out groove 71. A second return spring 73 is positioned between the end of the pop-out top block 72 away from the opening of the pop-out groove 71 and the pop-out groove 71. The second return spring 73 continuously applies a spring force to the pop-out top block 72 to move it towards the first sugar outlet 11. The sugar storage compartment 31 has its inner end... A rear opening 35 is provided. When any second candy outlet 32 is aligned with the first candy outlet 11, the corresponding candy storage cell 31 and the pop-out groove 71 are on the same straight line so that the pop-out top block 72 can be popped into the candy storage cell 31 through the rear opening 35 to pop out the candy 4. The outer end of the pop-out top block 72 is provided with a guide slope 721 so that when the rotating seat 3 rotates, the wall between adjacent candy storage cells 31 can press the pop-out top block 72 back into the pop-out groove 71 along the guide slope 721 to prepare for the next pop-out of candy 4.
[0013] Preferably, the pop-out groove 71 is further provided with an upwardly extending limiting protrusion 74, and the pop-out top block 72 is provided with a vertically penetrating limiting hollow groove 75. The limiting protrusion 74 is inserted into the limiting hollow groove 75, and the length of the limiting protrusion 74 extending along the pop-out groove 71 is shorter than the length of the limiting hollow groove 75 extending along the pop-out groove 71.
[0014] Preferably, the box body 1 has an upwardly extending circular wall surface 12 inside, the rotating seat 3 is fitted on the circular wall surface 12 and rotates, the box body 1 also has an upwardly protruding hollow rotating shaft 13 in the center, the lower surface of the cover body 2 has a shaft core 22 that extends downward and is inserted into the hollow rotating shaft 13, the lower outer wall surface of the shaft core 22 has a buckling protrusion 23, the lower inner wall surface of the hollow rotating shaft 13 has a step portion 131 for the buckling protrusion 23 to be engaged thereon, the upper outer wall surface of the hollow rotating shaft 13 also has an annular groove 132, and the rotating seat 3 also has a circular opening 36 that can be engaged into the annular groove 132.
[0015] Preferably, the rotating body is provided with a sealing wall 33 between adjacent second sugar outlets 32 for sealing the first sugar outlet 11.
[0016] Compared with the prior art, the beneficial effects of this utility model are:
[0017] This candy box allows users to align any second candy outlet with the first outlet by rotating the rotating body, then ejecting a single candy via a pop-out component. This effectively prevents other candies in the box from coming into contact with dust and moisture, reducing the risk of spoilage. Furthermore, ejecting only one candy at a time avoids waste caused by multiple candies falling out simultaneously. The visual effect of ejecting candies by rotating the body is also visually appealing, enhancing the fun of using the candy box. In addition, the candy box incorporates a stepped damping component to add a tactile feedback to the relative rotation of the box and the rotating body. This allows users to clearly judge the rotation range by feel and prevents candies from being accidentally ejected due to free rotation of the rotating body. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the candy box in this case.
[0019] Figure 2 This is one of the cross-sectional schematic diagrams of the candy box in this case.
[0020] Figure 3 This is the second cross-sectional schematic diagram of the candy box in this case.
[0021] Figure 4 This is a partial cross-sectional view of the step damping component in this case.
[0022] Figure 5 This is a diagram illustrating the explosion of the candy box in this case.
[0023] Figure 6 This is a schematic diagram of the box in this case.
[0024] Figure 7 This is a schematic diagram of the rotating base in this case.
[0025] Figure 8 This is a schematic diagram of the cover in this case. Detailed Implementation
[0026] The following examples provide a more detailed description of the features and other related characteristics of this utility model, to facilitate understanding by those skilled in the art:
[0027] like Figures 1 to 8As shown, a rotating pop-up candy box includes a circular box body 1 with its opening facing upwards and a rotating body installed in the box body 1. The rotating body can rotate relative to the box body 1. The box body 1 has a first candy outlet 11 located on its side wall. The rotating body has a plurality of circumferentially evenly distributed candy storage compartments 31. The candy storage compartments 31 are used to place candies 4 one-to-one. The outer side of the candy storage compartment 31 has a second candy outlet 32. A stepping damping component 6 is provided between the box body 1 and the rotating body. The stepping damping component 6 is used to generate a stepping sensation when the box body 1 and the rotating body rotate relative to each other. The box body 1 also has a pop-up component 7. The pop-up component 7 is used to pop the candies 4 in the corresponding candy storage compartment 31 out of the box body 1 when any second candy outlet 32 rotates to align with the first candy outlet 11.
[0028] The candy box in this case includes a box body 1, a rotating body, a stepping damping component 6, and a pop-out component 7. The rotating body is installed inside the box body 1 and the two can rotate relative to each other. The rotating body has several candy storage compartments 31 for placing candies 4, and a second candy outlet 32 is provided on the outer side of each candy storage compartment 31. When the rotating body rotates to the point where any second candy outlet 32 aligns with a first candy outlet 11, the pop-out component 7 is triggered to pop the candy 4 in the corresponding candy storage compartment 31 outward through the first candy outlet 11 and the second candy outlet 32. In addition, a stepping damping component 6 is provided between the box body 1 and the rotating body. The stepping damping component 6 can create a tactile feedback when the box body 1 and the rotating body rotate relative to each other, so that the user can control the rotation angle of the rotating body by feel. This makes it easier for the user to align the first candy outlet 11 with the second candy outlet 32 to trigger the pop-out component 7. At the same time, the rotational resistance between the box body 1 and the rotating body caused by the tactile feedback of the stepping damping component 6 can effectively prevent the rotating body from rotating freely and causing the candy 4 to be accidentally popped out.
[0029] As described above, the candy box of this invention can align any second candy outlet 32 with the first candy outlet 11 by rotating the rotating body, thereby ejecting a candy 4 via the ejection component 7. This effectively prevents other candies 4 in the candy box from coming into contact with external dust and moisture, reducing the risk of spoilage. Furthermore, ejecting only one candy 4 at a time avoids multiple candies 4 falling out simultaneously and causing waste. The visual effect of ejecting the candy 4 by rotating the rotating body also creates a strong visual impact on the user, enhancing the fun of using the candy box. In addition, the candy box of this invention uses a step damping component 6 to add a tactile feedback to the relative rotation of the box body 1 and the rotating body. This allows the user to clearly judge the rotation range of the rotating body by feel and also prevents the candy 4 from being accidentally ejected due to free rotation of the rotating body.
[0030] like Figure 3 , Figure 4 , Figure 6 and Figure 7As shown, preferably, the rotating body includes a cover 2 that is also circular at the opening of the box body 1 and a rotating seat 3 that is coaxially disposed inside the box body 1 and can rotate relative to the box body 1. The cover 2 and the rotating seat 3 are connected by a synchronous rotation structure 5 so that the rotating seat 3 can be rotated by rotating the cover 2. The sugar storage compartment 31 is disposed on the rotating seat 3, and the stepping damping component 6 is disposed between the box body 1 and the rotating seat 3.
[0031] As described above, the rotating body in this case includes a cover 2 and a rotating seat 3. By splitting the rotating body into two parts, the design and manufacturing difficulty of the rotating body can be effectively reduced, thereby reducing costs. Furthermore, by setting a synchronous rotation structure 5, it can be ensured that the cover 2 and the rotating seat 3 can maintain synchronous rotation, making it convenient for users to rotate the exposed cover 2 to drive the rotating seat 3 to rotate.
[0032] like Figures 4 to 7 As shown, preferably, the stepping damping assembly 6 includes a through groove 61 disposed on the rotating seat 3 and extending vertically. A steel ball 62 that can move up and down along the through groove 61 is placed in the through groove 61. The diameter of the lower opening of the through groove 61 is smaller than the diameter of the steel ball 62 to prevent the steel ball 62 from falling down out of the through groove 61. A sealing block 63 for closing the through groove 61 is fixed above the through groove 61. A first reset spring 64 is provided between the sealing block 63 and the steel ball 62. The first reset spring 64 is used to continuously apply a downward reset force to the steel ball 62. The stepping damping assembly 6 also includes a number of positioning grooves 65 disposed on the bottom surface of the inner box 1 and evenly distributed circumferentially. The number of positioning grooves 65 is the same as the number of sugar storage compartments 31 or twice the number of sugar storage compartments 31. When the through groove 61 rotates with the rotating seat 3 to above any positioning groove 65, the lower part of the steel ball 62 can partially protrude out of the through groove 61 and fall into the corresponding positioning groove 65 to obstruct the rotation of the rotating seat.
[0033] As described above, the step damping assembly 6 in this case includes a through groove 61, a steel ball 62, a sealing block 63, a first reset spring 64, and a positioning groove 65. By cooperating with the sealing block 63 and the first reset spring 64, the steel ball 62 can be pressed tightly against the bottom of the through groove 61. When no positioning groove 65 is aligned with the through groove 61, the bottom of the steel ball 62 makes smooth contact with the inner bottom surface of the box 1, resulting in less resistance to the relative rotation of the box 1 and the rotating seat 3. When any positioning groove 65 is aligned with the through groove 61, the steel ball 62 is also aligned with the corresponding positioning groove 65. At this time, the lower part of the steel ball 62 will move further down into the positioning groove 65 under the elastic force of the first reset spring 64. Thus, if the box 1 and the rotating seat 3 want to continue to rotate relative to each other, they need to overcome the obstruction of the positioning groove 65 on the steel ball 62. This allows the box 1 and the rotating seat 3 to experience intermittent resistance during relative rotation, thereby creating a sense of tactile feedback. Users can then clearly judge the rotation range of the rotating seat 3 by touch.
[0034] Specifically, the diameter of the steel ball 62 is D, the main body diameter of the through groove 61 is E, and the diameter of the lower opening of the through groove 61 is F, and D < E < 1.15D, 0.8D < F < 0.9D.
[0035] like Figure 1 , Figure 5 , Figure 7 and Figure 8 As shown, preferably, the synchronous rotation structure 5 includes a plurality of slots 51 disposed on the upper surface of the rotating base 3, and a plurality of pins 52 extending downward corresponding to the positions of the slots 51 on the lower surface of the cover 2. The pins 52 are used to insert into the slots 51 when the cover 2 is placed on the box 1. Thus, when the pins 52 on the cover 2 are inserted into the slots 51 on the rotating base 3, the cover 2 and the rotating base 3 can rotate synchronously through the cooperation of the slots 51 and the pins 52.
[0036] like Figure 1 , Figure 5 , Figure 7 and Figure 8 As shown, preferably, the sugar storage compartment 31 is provided with an open candy inlet 34 on the top to facilitate the placement of candy 4 into the sugar storage compartment 31, and the lower surface of the cover 2 is also provided with a plurality of sealing protrusions 21 that correspond one-to-one with the candy inlet 34 and have the same shape and outline. The sealing protrusions 21 are used to be embedded in the candy inlet 34 when the cover 2 is placed on the box body 1.
[0037] As described above, a candy inlet 34 is also provided above the candy storage compartment 31, so that candy 4 can be conveniently and quickly added to each candy storage compartment 31 through the candy inlet 34 after the cover 2 is opened. At the same time, the cover 2 is also provided with a sealing protrusion 21 that can be embedded in the candy inlet 34. So, after the cover 2 is closed, the sealing protrusion 21 can reduce the movement space of the candy 4 in the candy storage compartment 31, preventing the candy 4 from tilting and affecting the ejection component 7 to eject the candy 4. At the same time, the concave and convex cooperation between the candy inlet 34 and the sealing protrusion 21 can further ensure that the cover 2 and the rotating seat 3 can rotate synchronously.
[0038] like Figure 2 , Figure 5 , Figure 6 and Figure 7As shown, preferably, the pop-out component 7 includes a pop-out groove 71 extending outward from the first sugar outlet 11 within the box body 1. A pop-out top block 72, movable along the pop-out groove 71, is positioned within the pop-out groove 71. A second return spring 73 is positioned between the end of the pop-out top block 72 away from the opening of the pop-out groove 71 and the pop-out groove 71. The second return spring 73 continuously applies a spring force to the pop-out top block 72 to move it towards the first sugar outlet 11. The sugar storage compartment 31 is located further inward. Each end is provided with a rear opening 35. When any second sugar outlet 32 is aligned with the first sugar outlet 11, its corresponding sugar storage cell 31 and pop-out groove 71 are on the same straight line so that the pop-out top block 72 can be popped into the sugar storage cell 31 through the rear opening 35 to pop out the candy 4. The outer end of the pop-out top block 72 is provided with a guide slope 721 so that when the rotating seat 3 rotates, the wall between adjacent sugar storage cells 31 can press the pop-out top block 72 back into the pop-out groove 71 along the guide slope 721 to prepare for the next pop-out of candy 4.
[0039] As described above, the ejector assembly 7 in this case includes an ejector groove 71, an ejector top block 72, and a second return spring 73. When neither the second candy outlet 32 nor the first candy outlet 11 is aligned, the ejector top block 72 is pressed by the wall of the rotating seat 3 between adjacent candy storage compartments 31, thereby overcoming the elastic force of the second return spring 73 and retracting into the ejector groove 71. When either the second candy outlet 32 is aligned with the first candy outlet 11, since the inner end of the candy storage compartment 31 is also provided with a rear opening 35, the ejector top block 72, which was originally pressed into the ejector groove 71, will be driven by the second return spring 73 to spring back into the corresponding candy storage compartment 31 through the rear opening 35, thereby ejecting the candy 4 in the candy storage compartment 31 outward, completing the candy dispensing. After the sugar is dispensed, as the box 1 and the rotating seat 3 continue to rotate relative to each other, the wall of the rotating seat 3 between adjacent sugar storage compartments 31 will push the pop-out top block 72 back into the pop-out slot 71 by abutting the guide slope 721, while simultaneously compressing the second reset spring 73 to prepare for the next pop-out of the candy 4.
[0040] like Figure 2 and Figure 6As shown, preferably, the pop-out groove 71 is further provided with an upwardly extending limiting protrusion 74, and the pop-out top block 72 is provided with a vertically penetrating limiting slot 75. The limiting protrusion 74 is inserted into the limiting slot 75. The length of the limiting protrusion 74 extending along the pop-out groove 71 is shorter than the length of the limiting slot 75 extending along the pop-out groove 71. In this way, by inserting the limiting protrusion 74 on the pop-out groove 71 into the limiting slot 75 of the pop-out top block 72, the cooperation of the limiting protrusion 74 and the limiting slot 75 can effectively limit the range of movement of the pop-out top block 72 along the pop-out groove 71, preventing the second return spring 73 from directly popping the pop-out top block 72 out of the pop-out groove 71. At the same time, it can further limit the movement trajectory of the pop-out top block 72 to ensure that the pop-out top block 72 can accurately contact the candy 4 and pop the candy 4 out.
[0041] like Figure 2 , Figure 3 , Figure 5 , Figure 6 , Figure 7 and Figure 8 As shown, preferably, the box body 1 has an upwardly extending circular wall surface 12 inside, the rotating seat 3 is fitted on the circular wall surface 12 and rotates, the box body 1 also has an upwardly protruding hollow rotating shaft 13 in the center, the lower surface of the cover body 2 has a shaft core 22 that extends downward and is inserted into the hollow rotating shaft 13, the lower outer wall surface of the shaft core 22 has a buckle protrusion 23, the lower inner wall surface of the hollow rotating shaft 13 has a step portion 131 for the buckle protrusion 23 to be engaged thereon, the upper outer wall surface of the hollow rotating shaft 13 also has an annular groove 132, and the rotating seat 3 also has a circular opening 36 that can be engaged into the annular groove 132.
[0042] As described above, the cooperation of the circular wall 12, the hollow rotating shaft 13 and the shaft core 22 enables the box body 1, the lid 2 and the rotating seat 3 to rotate coaxially and smoothly relative to each other. The cooperation of the snap-fit protrusion 23 and the step portion 131 ensures that the connection between the box body 1 and the lid 2 remains tight during rotation, preventing the lid 2 from easily detaching from the box body 1. Similarly, the cooperation of the annular groove 132 and the circular opening 36 can also fix the box body 1 and the rotating seat 3 together coaxially, preventing the rotating seat 3 from easily detaching from the box body 1 after the lid 2 is intentionally or unintentionally removed.
[0043] Specifically, the pop-out groove 71 is recessed on the circular wall surface 12.
[0044] like Figure 1 , Figure 2 , Figure 5 and Figure 7As shown, preferably, the rotating body is provided with a sealing wall 33 between adjacent second sugar outlets 32 for sealing the first sugar outlet 11. In this way, when sugar dispensing is completed or when sugar dispensing is not needed, the rotating body can be rotated until any sealing wall 33 is aligned with the second sugar outlet 32, thereby sealing the second sugar outlet 32 through the sealing wall 33 to prevent foreign objects from entering the box 1 and contaminating the candy 4.
[0045] Specifically, the sealing wall 33 is also mounted on the rotating seat 3.
[0046] As stated above, this case protects a rotating pop-up candy box, and all technical solutions that are the same as or similar to this case should be considered to fall within the scope of protection of this case.
Claims
1. A spin-and-pop candy box characterized in that The device includes a circular box (1) with its opening facing upwards and a rotating body installed in the box (1). The rotating body can rotate relative to the box (1). The box (1) has a first candy outlet (11) located on the side wall. The rotating body has several sugar storage compartments (31) evenly distributed around its circumference. The sugar storage compartments (31) are used to place candies (4) one by one. The sugar storage compartments (31) have a second candy outlet (32) on their outer side. A stepping damping component (6) is provided between the box (1) and the rotating body. The stepping damping component (6) is used to generate a stepping sensation when the box (1) and the rotating body rotate relative to each other. The box (1) also has a pop-out component (7). The pop-out component (7) is used to pop the candies (4) in the corresponding sugar storage compartment (31) out of the box (1) when any second candy outlet (32) rotates to align with the first candy outlet (11).
2. A rotating pop-up candy box according to claim 1, wherein The rotating body includes a cover (2) that is also circular at the opening of the box (1) and a rotating seat (3) that is coaxially arranged inside the box (1) and can rotate relative to the box (1). The cover (2) and the rotating seat (3) are connected by a synchronous rotation structure (5) so that the rotating seat (3) can be rotated by rotating the cover (2). The sugar storage compartment (31) is arranged on the rotating seat (3). The stepping damping assembly (6) is arranged between the box (1) and the rotating seat (3).
3. A rotating pop-up candy box according to claim 2, wherein The stepping damping assembly (6) includes a through groove (61) disposed on the rotating seat (3) and extending vertically. A steel ball (62) that can move vertically along the through groove (61) is placed inside the through groove (61). The diameter of the lower opening of the through groove (61) is smaller than the diameter of the steel ball (62) to prevent the steel ball (62) from falling out of the through groove (61). A sealing block (63) for closing the through groove (61) is fixed above the through groove (61). A first return spring (64) is provided between the sealing block (63) and the steel ball (62). The positioning spring (64) is used to continuously apply a downward reset force to the steel ball (62). The stepping damping assembly (6) also includes a number of positioning grooves (65) evenly distributed circumferentially on the bottom surface of the inner box (1). The number of positioning grooves (65) is the same as or twice the number of sugar storage compartments (31). When the through groove (61) rotates with the rotating seat (3) to above any positioning groove (65), the lower part of the steel ball (62) can partially protrude out of the through groove (61) and fall into the corresponding positioning groove (65) to prevent the rotating seat from rotating.
4. A rotating pop-up candy box according to claim 2, wherein The synchronous rotation structure (5) includes several slots (51) on the upper surface of the rotating seat (3), and several pins (52) extending downwards corresponding to the positions of the slots (51) on the lower surface of the cover (2). The pins (52) are used to insert into the slots (51) when the cover (2) is placed on the box (1).
5. A rotating pop-up lolly box according to either of claims 2 or 4, wherein The sugar storage compartment (31) is provided with an open candy inlet (34) on the top so that candy (4) can be placed into the sugar storage compartment (31). The lower surface of the cover (2) is also provided with a number of sealing protrusions (21) that correspond one-to-one with the candy inlet (34) and have the same shape and outline. The sealing protrusions (21) are used to be embedded in the candy inlet (34) when the cover (2) is placed on the box (1).
6. A rotating pop-up candy box according to claim 1, wherein The pop-out assembly (7) includes a pop-out groove (71) extending outward from the first sugar outlet (11) within the box body (1). A pop-out top block (72) movable along the pop-out groove (71) is provided within the pop-out groove (71). A second return spring (73) is provided between the end of the pop-out top block (72) away from the opening of the pop-out groove (71) and the pop-out groove (71). The second return spring (73) is used to continuously apply a spring force to the pop-out top block (72) to move towards the first sugar outlet (11). The sugar storage compartment (31) is provided with a rear opening at its inner end. When any second sugar outlet (32) is aligned with the first sugar outlet (11), its corresponding sugar storage cell (31) and pop-out groove (71) are on the same straight line so that the pop-out top block (72) can be popped into the sugar storage cell (31) through the rear opening (35) to pop out the candy (4). The pop-out top block (72) is provided with a guide slope (721) at one end so that when the rotating seat (3) rotates, the wall between adjacent sugar storage cells (31) can press the pop-out top block (72) back into the pop-out groove (71) along the guide slope (721) to prepare for the next pop-out of candy (4).
7. A rotating pop-up candy box according to claim 6, wherein The pop-out groove (71) is also provided with an upwardly extending limiting protrusion (74), and the pop-out top block (72) is provided with a vertically penetrating limiting hollow groove (75). The limiting protrusion (74) is inserted into the limiting hollow groove (75), and the length of the limiting protrusion (74) extending along the pop-out groove (71) is shorter than the length of the limiting hollow groove (75) extending along the pop-out groove (71).
8. A rotating pop-up candy box according to claim 2, characterized in that... The box body (1) has an upwardly extending circular wall surface (12) inside. The rotating seat (3) is fitted on the circular wall surface (12) and rotates. The box body (1) also has an upwardly protruding hollow rotating shaft (13) in the center. The lower surface of the cover (2) has a shaft core (22) that extends downward and is inserted into the hollow rotating shaft (13). The lower outer wall surface of the shaft core (22) has a buckle protrusion (23). The lower inner wall surface of the hollow rotating shaft (13) has a step portion (131) for the buckle protrusion (23) to be engaged thereon. The upper outer wall surface of the hollow rotating shaft (13) also has an annular groove (132). The rotating seat (3) also has a circular opening (36) that can be engaged into the annular groove (132).
9. A rotating pop-up candy box according to any one of claims 1 or 2, characterized in that... The rotating body has a sealing wall (33) between adjacent second sugar outlets (32) for sealing the first sugar outlet (11).