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By introducing a pressing mechanism and a dynamic sealing mechanism into the medicine box, the complexity of repeatedly disassembling the inner box of traditional medicine boxes is solved, achieving fast and convenient drug dispensing and sealing, and improving the comfort and convenience of using the medicine box.

CN224336067UActive Publication Date: 2026-06-09SHENZHEN YUNING ENTERPRISE MANAGEMENT CONSULTING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN YUNING ENTERPRISE MANAGEMENT CONSULTING CO LTD
Filing Date
2025-06-05
Publication Date
2026-06-09

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  • Figure CN224336067U_ABST
    Figure CN224336067U_ABST
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Abstract

The utility model discloses a medicine box relates to medicine box technical field, and medicine box includes outer box body, inner box body and pressing mechanism, and inner box body is located at outer box body, and inner box body is equipped with medicine cavity and medicine outlet, and medicine cavity is set up as accommodating medicine, and medicine outlet communicates medicine cavity, and pressing mechanism includes actuator and button, and actuator movably is equipped in inner box body, and is located at medicine outlet, and button movably is equipped in inner box body and is connected in actuator, medicine box has the medicine storage state of actuator plugging medicine outlet and the medicine outlet state of actuator away from medicine outlet, in medicine outlet state, button pushes actuator away from medicine outlet, and medicine is sent from medicine outlet. The utility model aims at improving the use comfort and convenience of medicine box to realize fast medicine taking.
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Description

Technical Field

[0001] This utility model relates to the field of medicine box technology, and in particular to a medicine box. Background Technology

[0002] Medicine boxes are typically used to store and dispense medications. They can be placed according to type, dosage form, and dosage to make it convenient for patients to take their medications at the prescribed times and in the prescribed amounts.

[0003] In traditional multi-chamber pillbox designs, the modular inner box and outer shell are connected by a detachable structure. Users need to physically disassemble and reassemble the inner box and outer shell repeatedly to release the locking constraint between them. This makes it difficult for users to remove the inner box one by one when taking out the medicine, resulting in poor overall comfort and convenience of the pillbox and increasing the complexity of user operation. Utility Model Content

[0004] The main purpose of this utility model is to propose a medicine box that aims to improve the comfort and convenience of using the medicine box, reduce the complexity of the medicine dispensing operation, and achieve rapid medicine dispensing.

[0005] To achieve the above objectives, this utility model proposes a medicine box, the medicine box comprising:

[0006] Outer box;

[0007] An inner box body is disposed within an outer box body. The inner box body has a medicine-containing cavity and a medicine-dispensing outlet. The medicine-containing cavity is configured to contain medicine, and the medicine-dispensing outlet communicates with the medicine-containing cavity.

[0008] The pressing mechanism includes an actuator and a button. The actuator is movably disposed in the inner box and located at the medicine outlet. The button is movably disposed in the inner box and connected to the actuator.

[0009] The medicine box has a medicine storage state in which the actuator blocks the medicine outlet and a medicine dispensing state in which the actuator moves away from the medicine outlet. In the medicine dispensing state, the button pushes the actuator away from the medicine outlet, and the medicine is delivered from the medicine outlet.

[0010] In one embodiment, the inner box body is provided with a rotating hole, which is located around the periphery of the medicine outlet;

[0011] The actuator includes a plate and a rotating shaft. The rotating shaft is disposed on the plate and rotatably disposed in the rotating hole. The rotating shaft is elastically connected to the inner box. The button is connected to the plate. The plate is configured to cover or be away from the medicine outlet.

[0012] In one embodiment, the button includes a button and a lever, the button is connected to the lever, the button is movably disposed in the inner box, and the end of the lever away from the button is connected to the plate.

[0013] And / or, the actuator further includes a torsion spring, which is sleeved on the rotating shaft, with one end of the torsion spring elastically abutting against the inner box and the other end of the torsion spring elastically abutting against the plate.

[0014] In one embodiment, the button is located on the side of the inner box facing away from the medicine-containing cavity and is situated at the periphery of the inner box.

[0015] Alternatively, the button may be located within the medicine-containing cavity;

[0016] Alternatively, the inner box may have a recessed portion that protrudes towards one side of the medicine-containing cavity, and the button may be located on the side of the recessed portion opposite to the medicine-containing cavity.

[0017] In one embodiment, the inner box body forms an installation cavity, and the medicine box further includes a medicine storage box, a differential shaft, and an elastic element. The medicine storage box is located in the installation cavity, the elastic element is connected to the medicine storage box and the cavity wall of the installation cavity, and the differential shaft is connected to the medicine storage box.

[0018] The inner box also includes a push rod, which slides within the mounting cavity, and a limiting tooth is provided at the end of the push rod facing the differential shaft;

[0019] When the medicine storage box is pressed, the differential shaft rotates relative to the push rod. The medicine storage box has a protruding state where the differential shaft abuts against the limiting tooth and a retracted state where the differential shaft moves away from the limiting tooth.

[0020] In one embodiment, the button includes a button and a first inclined block, the button being elastically connected to the inner box, and the first inclined block having a first inclined surface;

[0021] The inner box body has a second inclined block on the side facing the first inclined block, and the second inclined block has a second inclined surface, with the first inclined surface and the second inclined surface abutting each other;

[0022] When the button is pressed, the first and second inclined blocks slide relative to each other, and the inner box moves in the opposite direction to the button.

[0023] In one embodiment, the inner box body is provided with guide grooves, which are arranged in parallel on both sides of the opposite periphery of the medicine outlet. The actuator is slidably disposed in the guide grooves and elastically connected to the inner box body.

[0024] The button includes a button and an electromagnetic switch, the button and the electromagnetic switch are electrically connected, the button is movably disposed in the inner box, and the electromagnetic switch is connected to the actuator;

[0025] The electromagnetic switch moves to drive the actuator to slide along the guide groove.

[0026] In one embodiment, the actuator is a flexible plate, the side of which is slidably disposed in the guide groove, and the flexible plate is connected to the output end of the electromagnetic switch;

[0027] The electromagnetic switch drives the flexible plate to move along the guide groove to cover or move away from the drug outlet.

[0028] In one embodiment, the actuator includes the flexible plate and a compression spring, the compression spring extending along the direction of the guide groove, one end of the compression spring being connected to the inner housing, and the other end of the compression spring being connected to the end of the flexible plate away from the electromagnetic switch;

[0029] And / or, the actuator further includes a guide wheel connected to the end of the flexible plate away from the electromagnetic switch, the guide wheel being rotatably disposed in the guide groove.

[0030] In one embodiment, the guide channel includes a straight section and a pressing section connected to each other. The pressing section and the electromagnetic switch are located at both ends of the straight section in the extending direction. The end of the pressing section away from the straight section extends toward the drug-containing cavity in the direction away from the drug outlet.

[0031] And / or, the flexible plate is provided with a sealing strip around its periphery, the flexible plate is slidably disposed in the guide groove, and the sealing strip seals against the groove wall of the guide groove.

[0032] In one embodiment, the electromagnetic switch is located on the side of the inner box facing away from the drug-containing cavity, and at the end of the actuator relative to the direction of movement of the guide groove;

[0033] Alternatively, the electromagnetic switch may be located on the side of the inner box facing away from the drug-containing cavity, and on the side of the actuator relative to the direction of movement of the guide groove.

[0034] In one embodiment, the pressing mechanism further includes a mounting shell disposed in the inner box and located at the medicine outlet;

[0035] The mounting shell forms a drug leakage cavity. The mounting shell is provided with a drug inlet and a drug leakage outlet that communicate with the drug leakage cavity. The drug inlet is connected to the drug outlet. The drug leakage outlet is located at the end of the mounting shell away from the drug inlet.

[0036] The actuator is rotatably disposed in the drug leakage chamber, and the button is configured to push the actuator to rotate so as to move the drug from the drug inlet to the drug leakage outlet.

[0037] In one embodiment, the actuator includes a rolling body and a plurality of protrusions, the rolling body being rotatably disposed in the drug leakage cavity, and the plurality of protrusions being arranged in a ring array around the periphery of the rolling body;

[0038] Two adjacent protrusions enclose and form a groove, and a plurality of grooves are arranged in a ring array at intervals around the periphery of the rolling body;

[0039] In the dispensing state, the groove is configured to hold the drug and transfer the drug from the inlet to the outlet.

[0040] In one embodiment, the button includes:

[0041] A button, which is elastically connected to the inner box;

[0042] A gear, the gear being connected to the rolling body, the gear rotating coaxially with the rolling body; and

[0043] A rack, one end of which is connected to the button, and the other end of which is engaged with the gear.

[0044] In one embodiment, the outer box includes a support and a tray, the support being connected to the tray, and the inner box being disposed on the support;

[0045] The support and the tray are spaced apart and enclosed to form a medicine dispensing trough. In the medicine dispensing state, the medicine outlet is connected to the medicine receiving cavity and the medicine dispensing trough.

[0046] In one embodiment, the support is an annular structure, the support encloses an inner cavity, the tray is disposed in the inner cavity, and the tray and the support enclose an annular dispensing groove;

[0047] The medicine box includes multiple inner boxes and multiple pressing mechanisms. The multiple inner boxes are arranged in a ring around the side of the support facing away from the tray. Each button is movably located in one of the inner boxes, and each actuator is rotatably located in one of the medicine outlets.

[0048] In one embodiment, a plurality of inner box bodies are arranged in a ring to form a single-layer box body. The medicine box includes a plurality of single-layer box bodies, the circumferential axes of the plurality of single-layer box bodies coincide, and the plurality of single-layer box bodies are stacked and abutted together in sequence.

[0049] The inner cavities of the multiple single-layer boxes are interconnected.

[0050] In one embodiment, the outer box further includes a top cover and a sealing element, the top cover being rotatably connected to the bracket, and the sealing element being disposed on the side of the top cover facing the bracket;

[0051] The inner box is also provided with a medicine inlet, which is connected to the medicine-containing cavity. In the medicine-storing state, the upper cover closes the inner box, and the sealing element seals against the medicine inlet.

[0052] In one embodiment, the medicine box includes a plurality of inner boxes, which are arranged in a rectangular array at intervals along a first direction and a second direction that are perpendicular to each other;

[0053] The tray includes a tray body and multiple guide plates. The guide plates are disposed on the side of the tray body facing the support. The multiple guide plates are spaced apart along the first direction to divide the medicine dispensing slot into multiple unit slots.

[0054] Each unit slot along the first direction corresponds to one inner box, and each unit slot along the second direction corresponds to multiple inner boxes.

[0055] In one embodiment, the medicine box includes two outer box bodies, two brackets arranged in parallel and spaced apart, and two trays connected to each other and located between the two brackets;

[0056] The medicine box includes at least two inner boxes, and each bracket has at least one inner box. The medicine outlet of the inner box located on different brackets is oriented toward the tray.

[0057] In one embodiment, the medicine box further includes a controller and a display, the display being disposed on the outer box and electrically connected to the controller;

[0058] And / or, the medicine box further includes a controller and a light assembly, the light assembly being disposed in the inner box and electrically connected to the controller;

[0059] And / or, the medicine box further includes a controller and a speaker, the speaker being disposed in the inner box and electrically connected to the controller.

[0060] The medicine box of this utility model includes an outer box, an inner box, and a pressing mechanism. The inner box is located within the outer box and has a medicine-containing cavity and a medicine-dispensing port. The medicine-containing cavity is used to hold medicine, and the medicine-dispensing port is connected to the medicine-containing cavity. The pressing mechanism includes an actuator and a button. The actuator is movably located in the inner box and is situated at the medicine-dispensing port. The button is movably located in the inner box and connected to the actuator. The medicine box has a medicine-storing state where the actuator blocks the medicine-dispensing port and a medicine-dispensing state where the actuator moves away from the medicine-dispensing port. In the medicine-dispensing state, the button pushes the actuator away from the medicine-dispensing port, and the medicine is dispensed from the medicine-dispensing port. By setting up a pressing mechanism, users can directly press the button to operate the actuator to move away from the medicine-dispensing port, thereby achieving faster and more convenient medicine retrieval, improving the comfort and convenience of using the medicine box, and reducing the complexity of medicine retrieval operations. Attached Figure Description

[0061] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.

[0062] Figure 1 This is a schematic diagram of the structure of the medicine box in one embodiment of the present invention;

[0063] Figure 2 for Figure 1 A schematic diagram of the inner box and the pressing mechanism;

[0064] Figure 3 for Figure 1 Another structural diagram of the inner box and pressing mechanism;

[0065] Figure 4 This is a schematic diagram of the structure of the medicine box in another embodiment of the present invention;

[0066] Figure 5 for Figure 4 A schematic diagram of the inner box and the pressing mechanism;

[0067] Figure 6 This is a schematic diagram of the structure of the medicine box in another embodiment of the present invention;

[0068] Figure 7 for Figure 6 A schematic diagram of the inner box and the pressing mechanism;

[0069] Figure 8 This is a schematic diagram of the structure of the medicine box in another embodiment of the present invention;

[0070] Figure 9This is a schematic diagram of the structure of the medicine box in another embodiment of the present invention;

[0071] Figure 10 for Figure 9 A schematic diagram of the inner box and pressing mechanism in one embodiment;

[0072] Figure 11 for Figure 9 A schematic diagram of the inner box and pressing mechanism in another embodiment;

[0073] Figure 12 This is a schematic diagram of the inner box and pressing mechanism in one embodiment of the present invention;

[0074] Figure 13 This is a schematic diagram of the inner box and pressing mechanism in another embodiment of the present invention;

[0075] Figure 14 for Figure 12 and Figure 13 Cross-sectional schematic diagram of the inner box and the pressing mechanism;

[0076] Figure 15 for Figure 12 and Figure 13 A cross-sectional view of the inner box and the pressing mechanism from another perspective;

[0077] Figure 16 This is a schematic diagram of the structure of a medicine box composed of multiple inner boxes in one embodiment of the present invention;

[0078] Figure 17 This is a schematic diagram of the structure of a medicine box composed of multiple inner boxes in another embodiment of the present invention;

[0079] Figure 18 This is a schematic diagram of the structure of the medicine box in one embodiment of the present invention;

[0080] Figure 19 This is a schematic diagram of the structure of the inner box and the medicine storage box in one embodiment of the present invention.

[0081] Explanation of icon numbers:

[0082] 100. Medicine box; 1. Outer box body; 11. Support; 111. Inner cavity; 12. Tray; 121. Plate body; 122. Guide plate; 123. Unit slot; 13. Medicine dispensing slot; 14. Top cover; 15. Sealing element; 2. Inner box body; 21. Medicine receiving cavity; 22. Medicine dispensing port; 23. Rotating hole; 24. Guide groove; 241. Straight section; 242. Pressing section; 25. Medicine inlet; 26. Recessed part; 3. Pressing mechanism; 31. Button; 311. Press 312. Button; 313. Movable lever; 314. Torsion spring; 315. Electromagnetic switch; 316. Compression spring; 317. Gear; 318. Rack; 32. Actuator; 321. Plate; 322. Rotating shaft; 323. Guide wheel; 324. Rolling body; 325. Protrusion; 326. Groove; 33. Mounting shell; 331. Leakage chamber; 332. Inlet; 333. Leakage port; 4. Single-layer box; 5. Display; 6. Medicine storage box; 61. Pressing part.

[0083] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0084] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present utility model.

[0085] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.

[0086] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.

[0087] Please refer to Figures 1 to 15 As shown, this utility model proposes a medicine box 100, which includes an outer box body 1, an inner box body 2, and a pressing mechanism 3. The inner box body 2 is disposed on the outer box body 1 and has a medicine-containing cavity 21 and a medicine-dispensing port 22. The medicine-containing cavity 21 is configured to contain medicine, and the medicine-dispensing port 22 is connected to the medicine-containing cavity 21. The pressing mechanism 3 includes an actuator 32 and a button 31. The actuator 32 is movably disposed on the inner box body 2 and located at the medicine-dispensing port 22, and the button 31 is movably disposed on the inner box body 2 and connected to the actuator 32. The medicine box 100 has a medicine-storing state in which the actuator 32 blocks the medicine-dispensing port 22 and a medicine-dispensing state in which the actuator 32 moves away from the medicine-dispensing port 22. In the medicine-dispensing state, the button 31 pushes the actuator 32 away from the medicine-dispensing port 22, and the medicine is delivered from the medicine-dispensing port 22.

[0088] In this embodiment, the outer box 1 refers to the external support structure used to accommodate the inner box 2 and the pressing mechanism 3. Specifically, it can be made of plastic or metal. The outer box 1 can be a box, shell, or frame structure. The inner box 2 refers to the container structure set inside the outer box 1. The inner box 2 can be a box, shell, bowl, cup, or cylinder structure, etc., without limitation. The inner box 2 is an independent cavity for storing drugs. The outer box 1 and the inner box 2 can be separate and detachable or integrally formed. The drug-containing cavity 21 formed by the inner box 2 is a closed space for containing drugs. Specifically, it can be formed by injection molding or assembly to ensure the airtightness of drug storage. The inner box 2 is also provided with a drug outlet 22 connected to the drug-containing cavity 21. At the same time, the drug outlet 22 is connected to the external environment. Specifically, it can be designed as a circular or rectangular through hole to realize the directional output of drugs.

[0089] In this embodiment, the pressing mechanism 3 refers to the operating component that controls the opening and closing of the drug outlet 22 through mechanical linkage. Specifically, it includes an actuator 32 and a button 31, which is used to release the drug by one hand. The actuator 32 is movably disposed at the drug outlet 22. The actuator 32 can be rotatably connected to the inner box 2 through a rotating shaft 322, or a sliding groove can be provided at the drug outlet 22 of the inner box 2, and the actuator 32 can be slidably disposed in the sliding groove to change the on / off state of the drug outlet 22 by displacement. Meanwhile, a sealing ring is provided around the actuator 32 to seal the medicine outlet 22; the button 31 is an external operating component that is linked with the actuator 32. Specifically, it can be designed as a press-type or toggle-type structure to receive user operation and transmit mechanical force to the actuator 32. For example, the button 31 is a linkage rod that is elastically connected to the inner box 2 and abuts or connects with the actuator 32. By pressing or toggling the linkage rod, the actuator 32 can be rotated or slid relative to the medicine outlet 22, thereby achieving the blocking or opening of the medicine outlet 22.

[0090] Specifically, the medicine box 100 includes a medicine storage state and a medicine dispensing state. The medicine storage state refers to the closed state in which the medicine cannot be dispensed when the actuator 32 blocks the medicine dispensing port 22. This is achieved by the tight fit between the actuator 32 and the medicine dispensing port 22 to prevent accidental leakage of the medicine. The medicine dispensing state refers to the open state in which the medicine can be dispensed when the actuator 32 is away from the medicine dispensing port 22. When the medicine needs to be dispensed, it is achieved by pushing the actuator 32 to move using the button 31, which is used to release a fixed amount of medicine in a targeted manner.

[0091] Understandably, this application achieves rapid switching between the medication storage state and the medication dispensing state of the inner box 2 through the pressing mechanism 3. Users only need to operate button 31 to control the displacement of the actuator 32 to release the medication, avoiding the cumbersome operation of repeatedly disassembling the inner box 2 required by traditional medicine boxes 100. This improves medication retrieval efficiency and convenience. In the medication storage state, the actuator 32 blocks the medication dispensing port 22 to prevent leakage or external contamination of the medication. When medication needs to be retrieved, the user presses button 31, which pushes the actuator 32 away from the medication dispensing port 22, and the medicine box 100 enters the medication dispensing state. At this time, the medication dispensing port 22 opens, and the medication can be dispensed from it.

[0092] The connection design between the actuator 32 and the button 31 allows for the opening of the dispensing port 22 and the delivery of the medicine with a single operation, simplifying the medicine dispensing process. The movable setting of the actuator 32 enables dynamic sealing of the dispensing port 22, reliably sealing the medicine-containing cavity 21 when not dispensing medicine. The fixed connection between the inner box 2 and the outer box 1 avoids frequent disassembly and assembly, reducing mechanical wear.

[0093] After the button 31 is released, the actuator 32 automatically resets under the action of elastic force, resealing the dispensing port 22. This design ensures that the dispensing port 22 remains sealed when not dispensing medication, effectively preventing the medication from getting damp or contaminated.

[0094] Understandably, this application enables medication retrieval with a single operation, avoiding the cumbersome steps of disassembling the inner box 2 required by traditional medicine boxes 100. The dynamic sealing mechanism effectively prevents medication from being contaminated by the external environment, and the fixed connection between the inner and outer box 1 reduces mechanical wear and improves the service life of the medicine box 100. The simplified operation process and reliable sealing performance enhance the ease of use and safety of medication storage of the medicine box 100. It is especially suitable for users who need to take multiple medications at regular intervals and in fixed quantities, effectively improving user comfort and convenience to achieve rapid medication retrieval.

[0095] This medicine box 100 includes an outer box body 1, an inner box body 2, and a pressing mechanism 3. The inner box body 2 is located on the outer box body 1 and has a medicine receiving cavity 21 and a medicine dispensing port 22. The medicine receiving cavity 21 is configured to contain medicine, and the medicine dispensing port 22 communicates with the medicine receiving cavity 21. The pressing mechanism 3 includes an actuator 32 and a button 31. The actuator 32 is movably located on the inner box body 2 and is situated at the medicine dispensing port 22. The button 31 is movably located on the inner box body 2 and is connected to the actuator 32. The medicine box 100 has an actuator. The button 32 blocks the medicine storage state of the medicine outlet 22 and the actuator 32 moves away from the medicine outlet 22 to the medicine dispensing state. In the medicine dispensing state, the button 31 pushes the actuator 32 away from the medicine outlet 22, and the medicine is sent out from the medicine outlet 22. By setting the pressing mechanism 3, the user can directly press the button 31 to operate the actuator 32 to move away from the medicine outlet 22, thereby realizing medicine retrieval more quickly and conveniently, improving the comfort and convenience of using the medicine box 100, and reducing the complexity of medicine retrieval operation.

[0096] In one embodiment, such as Figures 1 to 7 As shown, the inner box 2 is provided with a rotating hole 23, which is located around the medicine outlet 22; the actuator 32 includes a plate 321 and a rotating shaft 322, the rotating shaft 322 is provided on the plate 321, the rotating shaft 322 is rotatably provided on the rotating hole 23, and the rotating shaft 322 is elastically connected to the inner box 2; the button 31 is connected to the plate 321, and the plate 321 is configured to cover or move away from the medicine outlet 22.

[0097] In this embodiment, the rotating hole 23 is machined in the form of a circular through hole on the side wall of the medicine outlet 22, and the hole axis is parallel to the plane of the medicine outlet 22; the rotating shaft 322 is a cylindrical metal rod, with both ends extending into the bearing structure of the inner wall of the rotating hole 23 to form a rotating pair; the plate 321 is a thin plate structure, the length direction of which is consistent with the extension direction of the rotating shaft 322, and the width covers the opening of the medicine outlet 22; the elastic connection is achieved by torsion springs 313 sleeved on both ends of the rotating shaft 322, the inner ring of the torsion spring 313 is fixed to the rotating shaft 322, and the outer ring is fixed to the side wall of the inner box 2; the button 31 is fixed to the end of the plate 321 away from the rotating shaft 322 by a threaded connection, and the axis of the button 31 is perpendicular to the plane of the plate 321.

[0098] Specifically, when button 31 is subjected to vertical pressure, plate 321 rotates around shaft 322. Shaft 322 maintains a stable rotation trajectory within rotating hole 23 to prevent plate 321 from shifting laterally. Torsion spring 313 accumulates elastic potential energy when plate 321 rotates. After the external force is removed, it drives shaft 322 to rotate in the opposite direction, causing plate 321 to reset. When plate 321 covers the drug outlet 22, its edge forms a surface contact seal with the periphery of the drug outlet 22. When it is away from the drug outlet 22, plate 321 rotates at an angle of 15-30 degrees to ensure that the drug channel is fully open.

[0099] Understandably, this application enables flexible rotation of the actuator 32, making the opening and closing of the dispensing port 22 more convenient. The setting of the rotating shaft 322 provides stable rotation support, ensuring that the plate 321 can accurately cover or move away from the dispensing port 22. The elastic connection design enables the actuator 32 to have an automatic reset function, eliminating the need for the user to manually close the dispensing port 22. The connection between the button 31 and the plate 321 simplifies the operation. The user only needs to press the button 31 to open the dispensing port 22. This structural design improves the ease of use of the medicine box 100, reduces the possibility of misoperation, and also improves the sealing performance of the medicine box 100.

[0100] In one embodiment, such as Figure 2 , Figure 3 , Figure 5 as well as Figure 7 As shown, button 31 includes button 311 and movable rod 312. Button 311 is connected to movable rod 312 and is movably disposed in inner box 2. The end of movable rod 312 away from button 311 is connected to plate 321. Optionally, actuator 32 also includes torsion spring 313. Torsion spring 313 is sleeved on rotating shaft 322. One end of torsion spring 313 elastically abuts against inner box 2, and the other end of torsion spring 313 elastically abuts against plate 321.

[0101] In this embodiment, one end of the movable rod 312 is hinged to the plate 321. The plate 321 and the inner box 2 are connected by a hinge, and the hinge axis is perpendicular to the sliding direction of the movable rod 312. When an external force is applied to the movable rod 312, the movable rod 312 slides and pushes the plate 321 to rotate around the hinge axis, so that the plate 321 rotates from the blocked position to the open position. The elastic element is compressed and stores energy during the sliding process of the movable rod 312. After the external force is removed, the elastic element releases the elastic force to drive the movable rod 312 to slide back and reset. The plate 321 then rotates back to the blocked position. The axial limiting structure of the movable cavity prevents the movable rod 312 from displacing excessively. The rotational trajectory of the plate 321 is geometrically constrained by the position of the hinge axis to ensure that the opening of the drug outlet 22 and the stroke of the movable rod 312 are linearly proportional, thereby achieving a controllable drug output. The button 31 also includes an elastic element, which is sleeved on the outside of the movable rod 312 and limited to the inner box 2. Alternatively, the elastic element is a torsion spring 313, which is sleeved on the rotating shaft 322 and has one end of the torsion spring 313 elastically abutting against the inner box 2, and the other end of the torsion spring 313 elastically abutting against the plate 321.

[0102] Button 311 can be round or square and is made of ABS plastic. Movable rod 312 is made of metal, with one end fixedly connected to button 311 and the other end hinged to plate 321. Torsion spring 313 is made of stainless steel and is fitted onto pivot 322, with one end abutting the inner wall of inner box 2 and the other end abutting the back of plate 321. When button 311 is pressed, movable rod 312 causes plate 321 to rotate around pivot 322, overcoming the elasticity of torsion spring 313 and moving plate 321 away from dispensing port 22. After button 311 is released, plate 321 automatically returns to its original position and seals dispensing port 22 under the action of torsion spring 313.

[0103] Understandably, the movable rod 312 can slide axially back and forth relative to the inner box 2. When the movable rod 312 is pressed, it drives the plate 321 to rotate, moving the plate 321 away from the medicine outlet 22. At the same time, the elastic element is compressed, storing elastic potential energy. After the press is released, the elastic element releases its elastic potential energy, pushing the movable rod 312 back to its original position, causing the plate 321 to re-seal the medicine outlet 22.

[0104] Understandably, this application achieves the connection and control of button 31 and plate 321 through movable rod 312 and elastic element. Thus, the user can easily open the medicine outlet 22 of the medicine box 100 by simply pressing button 31, without directly contacting the internal structure, making operation simple and convenient. Simultaneously, the elastic element ensures that movable rod 312 and plate 321 can automatically reset and seal the medicine outlet 22, preventing drug leakage and improving the safety and reliability of the medicine box 100. Furthermore, the combination structure of movable rod 312 and elastic element is simple and compact, facilitating installation and maintenance, and contributing to a longer overall service life of the medicine box 100. At the same time, the torsion spring 313 enables the actuator 32 to have an automatic reset function, eliminating the need for the user to manually close the medicine outlet 22, further enhancing the convenience and safety of using the medicine box 100.

[0105] In one embodiment, such as Figures 1 to 7 As shown, button 31 is located on the side of inner box 2 facing away from medicine cavity 21 and is located at the periphery of inner box 2; or, button 31 is movably located in medicine cavity 21; or, inner box 2 is provided with recess 26, recess 26 protrudes to one side of medicine cavity 21, and button 31 is located on the side of recess 26 facing away from medicine cavity 21.

[0106] In this embodiment, the inner box 2 is rectangular, the medicine-containing cavity 21 is disposed inside the inner box 2, and the medicine outlet 22 is opened on one side or one bottom surface of the inner box 2. The button 31 is installed on the outer surface of the inner box 2 facing away from the medicine-containing cavity 21. Furthermore, the button 31 is arranged in the edge area of ​​this side, close to one of the four side edges of the inner box 2. Thus, the user can easily touch and operate the button 31 without interfering with the storage and removal of the medicine.

[0107] Alternatively, button 31 may be movably disposed in the medicine-containing cavity 21. In this embodiment, button 31 passes through the wall of the inner box 2, with one end extending into the interior of the medicine-containing cavity 21. For example, button 31 may be a rod-shaped structure, with its middle part passing through a hole in the wall of the inner box 2, one end located inside the medicine-containing cavity 21, and the other end exposed on the outer surface of the inner box 2 for user operation.

[0108] Alternatively, the inner box 2 may have a recessed portion 26 that protrudes towards one side of the medicine-containing cavity 21. The button 31 is located on the side of the recessed portion 26 facing away from the medicine-containing cavity 21. Specifically, an inwardly recessed area is formed in the wall of the inner box 2, which forms a protrusion within the medicine-containing cavity 21. The button 31 is installed on the outer side of this recessed area, i.e., on the side facing away from the medicine-containing cavity 21. This design provides installation space for the button 31 without reducing the volume of the medicine-containing cavity 21. Furthermore, the design of the recessed portion 26 creates a height difference between the button 31 and the surface of the inner box 2, preventing accidental activation. The recessed portion 26 protrudes towards the medicine-containing cavity 21, and its back side forms a planar space for the button 31, while maintaining a compact overall structure of the inner box 2. The choice of the button 31's position balances ease of operation and space utilization, adapting to different usage scenarios.

[0109] Understandably, when button 31 is located on the outer periphery of the inner box 2, the user can directly press the periphery area with their finger without needing to penetrate the medicine-containing cavity 21, thus reducing operational resistance. When button 31 is located inside the medicine-containing cavity 21, the driving path of the actuator 32 is shortened, improving the response speed. The protruding structure of the recessed part 26 forms a natural limit. When button 31 is located on the back side of the recessed part 26, its operating surface forms a stepped structure with the surface of the inner box 2, which prevents accidental touches while retaining the tactile feedback. Through these three position options, button 31 can be flexibly configured according to the specific structural layout of the medicine box 100. While ensuring the normal triggering of the actuator 32, the ergonomic design is optimized, and the operational complexity is reduced.

[0110] Furthermore, this application provides multiple arrangements of the buttons 31, increasing the design flexibility of the medicine box 100. Positioning the buttons 31 on the side of the inner box 2 facing away from the medicine-containing cavity 21 avoids accidental touches and improves operational accuracy. Movable placement of the buttons 31 within the medicine-containing cavity 21 saves external space, making the medicine box 100 structure more compact. The recessed design 26 allows for efficient use of space without affecting the volume of the medicine-containing cavity 21. These design schemes optimize the arrangement of the buttons 31, improving the ease of use and space utilization of the medicine box 100.

[0111] In one embodiment, such as Figure 19 As shown, the inner box 2 forms an installation cavity. The medicine box 100 also includes a medicine storage box 6, a differential shaft, and an elastic element. The medicine storage box 6 is located in the installation cavity. The elastic element is connected to the medicine storage box 6 and the cavity wall of the installation cavity. The differential shaft is connected to the medicine storage box 6. The inner box 2 also includes a push rod. The push rod slides within the installation cavity. The end of the push rod facing the differential shaft is provided with a limiting tooth. When the medicine storage box 6 is pressed, the differential shaft rotates relative to the push rod. The medicine storage box 6 has a protruding state where the differential shaft abuts against the limiting tooth and a retracted state where the differential shaft moves away from the limiting tooth.

[0112] In this embodiment, the inner box 2 has a mounting cavity, which provides spatial constraints for the medicine storage box 6. The medicine storage box 6 can form the aforementioned medicine-containing cavity 21. The elastic element maintains the initial position of the medicine storage box 6 through pre-tightening force. The rigid connection between the differential shaft and the medicine storage box 6 transmits the pressing force. The sliding limit of the push rod is achieved through the cooperation of the guide rail and the first guide block. The differential shaft slides along the guide rail through the second guide block to limit the rotation angle. The limiting tooth and the differential tooth at the end of the differential shaft form a meshing relationship. When the differential shaft rotates, the contact surface between the differential tooth and the limiting tooth generates a displacement difference, driving the medicine storage box 6 to move axially.

[0113] Specifically, when the medicine dispenser 6 is pressed, the elastic element compresses, and the differential shaft drives the differential gear to rotate around the push rod axis. The engagement of the differential gear and the limiting gear causes the push rod to slide along the guide rail until the differential gear disengages from the limiting gear. At this point, the medicine dispenser 6 enters the retracted state. After the pressing force is released, the elastic element rebounds and pushes the medicine dispenser 6 back to its original position. The differential gear and the limiting gear re-engage, and the medicine dispenser 6 returns to its protruding state. The cooperation between the guide rail and the guide block ensures the precise movement trajectory of the push rod and the differential shaft, reducing frictional loss and improving operational smoothness. Through the differential transmission between the differential shaft and the push rod, the popping and retracting process of the medicine dispenser 6 is simplified, and the user only needs to press once to switch states.

[0114] The mounting cavity can be located on the side wall of the inner box 2. The medicine storage box 6 is cylindrical. The differential shaft is fixedly connected to the bottom of the medicine storage box 6. The elastic element can be a compression spring, with one end connected to the top of the medicine storage box 6 and the other end connected to the top wall of the mounting cavity. The push rod can be a long strip structure that slides along the length of the mounting cavity. Multiple limiting teeth can be set and distributed in a gear shape at the end of the push rod. A corresponding protrusion structure can be set at the bottom of the differential shaft to cooperate with the limiting teeth.

[0115] When the medicine reservoir 6 is pressed, it causes the differential shaft to move downwards. The protrusion at the bottom of the differential shaft contacts the limiting tooth at the end of the push rod, resulting in relative rotation. As the pressing force increases, the differential shaft continues to move downwards and engages with the limiting tooth, causing the medicine reservoir 6 to be in the protruding state. After the pressing force is released, under the action of the elastic element, the medicine reservoir 6 causes the differential shaft to move upwards, disengaging the differential shaft from the limiting tooth, and the medicine reservoir 6 returns to the retracted state.

[0116] Understandably, this application enables the switching between the protruding and retracted states of the medicine storage box 6. This allows users to control the position of the medicine storage box 6 with a simple pressing operation, facilitating medication retrieval. Simultaneously, the elastic element ensures that the medicine storage box 6 automatically returns to the retracted state, preventing medication exposure to the external environment. Furthermore, the cooperation mechanism of the differential shaft and the limiting teeth provides a reliable positioning function, preventing the medicine storage box 6 from accidentally sliding out during use. This design improves the ease of use and safety of the medicine box 100, effectively solving the problems of complex operation and inconvenient medication retrieval associated with traditional medicine boxes 100.

[0117] This application further proposes that the inner box 2 is provided with a guide rail, the push rod is provided with a first guide block, the first guide block is slidably disposed on the guide rail, and the differential shaft is provided with a second guide block, the second guide block is slidably disposed on the guide rail.

[0118] The guide rail can be fixed to the side wall of the mounting cavity of the inner box 2 in the form of a groove or a protrusion. The first guide block and the second guide block are respectively designed as slider structures that match the cross-section of the guide rail. The first guide block is rigidly connected to the end of the push rod, and the second guide block is fixedly connected to the surface of the differential shaft. The extension direction of the guide rail is parallel to the sliding direction of the push rod, and the sliding stroke of the first guide block and the second guide block in the guide rail is limited by the length of the guide rail. For example, the guide rail can adopt a dovetail groove structure, and the first guide block and the second guide block are correspondingly designed as dovetail sliders to improve sliding stability.

[0119] Specifically, when the medicine storage box 6 is pressed by an external force, the differential shaft drives the second guide block to slide along the guide rail, and the push rod slides along the same guide rail via the first guide block. The guide rail constrains the movement direction of the push rod and the differential shaft, ensuring that their movement trajectories within the mounting cavity remain parallel. During the rotation of the differential shaft, the second guide block restricts the axial displacement of the differential shaft along the sliding path of the guide rail, preventing lateral offset between the shaft and the push rod, thereby ensuring the meshing accuracy of the limiting teeth and the differential teeth. The first and second guide blocks share the same guide rail, further reducing structural complexity. At the same time, the rigid support of the guide rail reduces sliding friction, making the switching action of the medicine storage box 6 between the protruding and retracted states smoother.

[0120] Understandably, the smooth sliding of the push rod and differential shaft improves the operational stability of the medicine box 100. The guide rail structure restricts the movement trajectory of the push rod and differential shaft, preventing deviation or jamming. At the same time, the guide rail design simplifies the internal structure of the medicine box 100, facilitating assembly and maintenance. In addition, the guide rail structure enhances the overall strength of the inner box 2, improving the durability of the medicine box 100.

[0121] Meanwhile, a push button 61 is provided on the top of the medicine storage box 6 so that the user can press the medicine storage box 6 through the push button 61 and make the medicine storage box 6 protrude from the inner box 2, so that the user can take the medicine from the medicine storage box 6.

[0122] In one embodiment, the button 31 includes a button 311 and a first inclined block. The button 311 is elastically connected to the inner box 2, and the first inclined block has a first inclined surface. The inner box 2 has a second inclined block on the side facing the first inclined block, and the second inclined block has a second inclined surface. The first inclined surface and the second inclined surface abut against each other. When the button 311 is pressed, the first inclined block and the second inclined block slide relative to each other, and the inner box 2 and the button 311 move in opposite directions.

[0123] In this embodiment, button 311 achieves the reset function through an elastic connection. The inclined surfaces of the first and second inclined blocks contact to form a sliding pair. The angle of the inclined surfaces is set to 30 to 60 degrees to achieve effective force transmission. The first inclined block and button 311 are fixedly connected by integral molding or separate assembly. The second inclined block and inner box 2 are formed into an integral structure through injection molding. Button 311 can be connected to inner box 2 by a spring sheet, and the first inclined block is fixed to button 311. The second inclined block can be directly molded onto inner box 2, or fixed onto inner box 2 by adhesive, screws, or other means. The inclination angles of the first and second inclined surfaces can be designed to be the same to ensure that they can fit tightly together.

[0124] Specifically, when the user presses button 311 downwards, the first inclined surface of the first inclined block and the second inclined surface of the second inclined block slide relative to each other. The contact of the inclined surfaces decomposes the longitudinal pressing force into a lateral component, pushing the inner box 2 to produce a lateral displacement relative to the outer box 1. Since the inner box 2 and button 311 move in opposite directions, the actuator 32 releases the blockage on the dispensing port 22 as the inner box 2 moves, and the medicine is automatically dispensed under the action of gravity. When the inclination angle of the inclined surface is set to 45 degrees, the conversion efficiency of the longitudinal pressing force and the lateral driving force reaches the optimal level. The user only needs to apply a small force to complete the operation. After the button 311 is released, it automatically resets through the elastic connection, driving the first inclined block and the second inclined block to return to the initial contact position. Thus, the movement of the inner box 2 can be achieved through a simple pressing action, making it convenient for the user to take out the medicine.

[0125] Understandably, this application enables the inner box 2 to move simply by pressing button 311, simplifying user operation and improving the ease of use of the medicine box 100. Simultaneously, the inclined block design effectively converts the pressing force into the moving force of the inner box 2, reducing the force applied by the user and improving operational comfort. Furthermore, this structural design is simple, easy to manufacture, and helps reduce production costs.

[0126] In one embodiment, such as Figure 8 As shown, the inner box 2 also includes a medicine storage box 6, which is located on the box body and forms a medicine-containing cavity 21. The medicine storage box 6 is detachably connected to the movable rod 312. When the movable rod 312 is pressed, the actuator 32 moves away from the medicine outlet 22, and the movable rod 312 causes the medicine storage box 6 to protrude from the medicine outlet 22.

[0127] In this embodiment, the medicine storage box 6 can be a medicine storage cup or medicine storage cylinder, etc. The medicine storage box 6 is located in the space formed by the inner box body 2, and the medicine storage box 6 forms the above-mentioned medicine-containing cavity 21. The medicine storage box 6 is mechanically linked with the movable rod 312 through a detachable connection structure, such as using a snap or threaded interface. A connecting part is provided on the movable rod 312, and a matching slot or threaded groove is provided at the corresponding position of the medicine storage box 6 to achieve axial fixation. During the compression of the elastic element, the movable rod 312 moves axially along the movable cavity, and the medicine storage box 6 is synchronously displaced by pulling the connecting part.

[0128] Specifically, when the user presses the movable rod 312, the movable rod 312 overcomes the resistance of the elastic element and moves towards the actuator 32, causing the actuator 32 to rotate around the rotating shaft 322 to release the blockage of the medicine outlet 22. At the same time, the movable rod 312 pulls the medicine storage box 6 along the medicine outlet 22 through the detachable connection structure, so that the medicine storage box 6 partially protrudes from the medicine outlet 22. For example, when the movable rod 312 is pressed, the actuator 32 moves away from the medicine outlet 22, and the movable rod 312 causes the medicine storage box 6 to protrude from the medicine outlet 22. The stroke of the movable rod 312 can be set to 10mm, so that the medicine storage box 6 protrudes from the medicine outlet 225mm. This ensures that the medicine can be taken out smoothly without causing the medicine storage box 6 to completely detach from the inner box 2.

[0129] This linkage mechanism allows the user to simultaneously open the actuator 32 and push out the medicine storage box 6 with a single press, facilitating direct delivery of medication through the medicine storage box 6 for easy access or disassembly for refilling. Since the medicine storage box 6 is separable from the movable rod 312, the user only needs to disconnect the connection structure to remove the medicine storage box 6 independently, without disassembling other components of the pressing mechanism 3, significantly shortening maintenance time and effectively improving the ease of use of the medicine box 100. At the same time, the detachable design of the medicine storage box 6 facilitates cleaning and replacement, further enhancing the practicality and hygiene of the medicine box 100.

[0130] In one embodiment, such as Figures 9 to 11 As shown, the inner box 2 is provided with a guide groove 24, which is arranged in parallel on both sides of the medicine outlet 22. The actuator 32 is slidably disposed in the guide groove 24 and elastically connected to the inner box 2. The button 31 includes a button 311 and an electromagnetic switch 314, which are electrically connected. The button 311 is movably disposed in the inner box 2, and the electromagnetic switch 314 is connected to the actuator 32. The movement of the electromagnetic switch 314 drives the actuator 32 to slide along the guide groove 24.

[0131] In this embodiment, the guide groove 24 is a parallel strip-shaped groove structure, extending perpendicularly to the length direction of the drug outlet 22. The actuator 32 is made of a flexible plate, such as a polyethylene flexible plate, a soft rubber structure, or a polycarbonate sheet, etc. The side of the flexible plate is embedded in the guide groove 24 and slides along the groove. The flexible plate is fixedly connected to the output end of the electromagnetic switch 314 by a buckle or bolt. The electromagnetic switch 314 can be a linear motor or an electromagnet. A buffer pad is provided at the connection between its output end and the flexible plate to reduce impact. A compression spring 315 is connected to the end of the flexible plate away from the electromagnetic switch 314. The compression spring 315 is pre-pressed between the side wall of the inner box 2 and the flexible plate along the extension direction of the guide groove 24 to provide a reset elastic force. An arc transition surface is provided at the connection between the straight section 241 and the pressing section 242 of the guide groove 24. The end of the pressing section 242 extends into the drug-containing cavity 21 to form a drug guiding channel.

[0132] Specifically, when button 311 is pressed, electromagnetic switch 314 receives an electrical signal and drives the flexible plate to move along guide groove 24. Under the action of electromagnetic force, the flexible plate overcomes the resistance of compression spring 315 and slides away from the drug outlet 22, so that the drug outlet 22 opens to expose the drug. After button 311 is released, electromagnetic switch 314 is de-energized, compression spring 315 pushes the flexible plate to slide back to the initial position, and sealing strip re-presses the groove wall of guide groove 24 to close the drug outlet 22. Electromagnetic switch 314 replaces traditional mechanical transmission with electrical control, realizing precise control of the movement of actuator 32, reducing operating force and extending the service life of the mechanism.

[0133] Understandably, this application implements electric control of the dispensing port 22 of the medicine box 100. Users can open the dispensing port 22 simply by pressing button 311, without manually disassembling the inner box 2, greatly improving the ease of use of the medicine box 100. Simultaneously, the electromagnetic switch 314 controls the actuator 32 to slide along the guide groove 24, ensuring the smoothness and reliability of the opening and closing action of the dispensing port 22 and avoiding potential jamming problems in the mechanical structure. Furthermore, the elastic connection design between the actuator 32 and the inner box 2 allows the dispensing port 22 to remain closed when not in use, preventing accidental drug leakage and improving the safety of the medicine box 100. This application achieves automated and intelligent control of the actuator 32, improving the ease of use of the medicine box 100. Users can move the actuator 32 relative to the dispensing port 22 by pressing the electromagnetic switch 314, thereby switching between the drug storage and dispensing states, making the opening and closing operation of the actuator 32 more flexible and controllable.

[0134] In one embodiment, such as Figure 10 and Figure 11 As shown, the actuator 32 includes a flexible plate and a compression spring 315. The compression spring 315 extends along the direction of the guide groove 24. One end of the compression spring 315 is connected to the inner box 2, and the other end of the compression spring 315 is connected to the end of the flexible plate away from the electromagnetic switch 314.

[0135] In this embodiment, the compression spring 315 adopts a helical compression spring structure. The compression spring 315 is installed along the extension direction of the guide groove 24, with one end fixed to the surface of the inner box 2 and the other end forming a telescopic connection with the end of the flexible plate. The compression stroke of the compression spring 315 is equal to the moving distance of the flexible plate along the guide groove 24. The flexible plate can be made of elastic plastic material. The guide groove 24 is set on the side wall of the inner box 2, and its width is adapted to the thickness of the flexible plate. The electromagnetic switch 314 is fixed at the bottom of the inner box 2, and its output shaft is connected to one end of the flexible plate. When the electromagnetic switch 314 is energized, the output shaft extends and pushes the flexible plate to slide upward along the guide groove 24, so that the flexible plate covers the medicine outlet 22. When the electromagnetic switch 314 is de-energized, the output shaft retracts, and the flexible plate slides downward along the guide groove 24 under its own gravity, away from the medicine outlet 22.

[0136] Specifically, the electromagnetic switch 314 can drive the flexible plate to slide along the guide groove 24. When the flexible plate moves away from the drug outlet 22, the compression spring 315 is stretched to generate an elastic restoring force. After the electromagnetic switch 314 is de-energized, the restoring force of the compression spring 315 drives the flexible plate to slide in the opposite direction, so that the flexible plate automatically returns to the initial position covering the drug outlet 22. The rolling action of the guide wheel 323 can reduce the contact area between the side wall of the flexible plate and the groove wall of the guide groove 24, and avoid the flexible plate from deforming due to friction. The elastic force of the compression spring 315 matches the mass of the flexible plate, ensuring that the flexible plate maintains uniform motion during movement and avoiding vibration or displacement due to inertia.

[0137] Understandably, this application achieves automatic opening and closing control of the medicine outlet 22. By using a flexible plate as the actuator 32, it can better adapt to the shape of the medicine outlet 22, improving the sealing effect. Simultaneously, the electromagnetic switch 314 has a simple and reliable driving method and is easy to operate, improving the comfort and convenience of using the medicine box 100. Furthermore, the sliding design of the flexible plate makes the opening and closing action smooth, reducing mechanical wear and extending the service life of the medicine box 100.

[0138] Optionally, such as Figure 10 and Figure 11 As shown, the actuator 32 also includes a guide wheel 323, which is connected to the end of the flexible plate away from the electromagnetic switch 314 and is rotatably disposed in the guide groove 24.

[0139] In this embodiment, the guide wheel 323 adopts a ball bearing structure. Its axle is embedded in a pre-set mounting hole at the end of the flexible plate, and its rim contacts the bottom of the guide groove 24. The guide wheel 323 is mounted on the end of the flexible plate via a rotating shaft 322 or a bearing structure, and its outer circumferential surface forms a rolling contact with the inner wall of the guide groove 24. The diameter of the guide wheel 323 can be adjusted according to the width of the guide groove 24. The guide wheel 323 can be made of nylon or metal, and its surface is smoothed to reduce rolling resistance. The compression spring 315 applies an elastic force in the extension direction of the guide groove 24, so that the flexible plate maintains its initial position when not driven by the electromagnetic switch 314. The guide wheel 323 and the compression spring 315 cooperate to provide both an elastic reset function and reduce motion resistance through rolling contact.

[0140] Specifically, when the electromagnetic switch 314 is energized, the flexible plate moves along the guide groove 24 under electromagnetic force. The guide wheel 323 rolls on the inner wall of the guide groove 24, converting sliding friction into rolling friction, reducing the resistance to movement of the flexible plate. The compression spring 315 is stretched during the movement of the flexible plate, storing elastic potential energy. When the electromagnetic switch 314 is de-energized, the compression spring 315 releases its elastic potential energy, causing the flexible plate to move in the opposite direction and reset. At this time, the guide wheel 323 also assists in the reset action by rolling. The rolling contact of the guide wheel 323 can avoid excessive wear between the side of the flexible plate and the guide groove 24, and at the same time improve the adhesion stability between the sealing strip and the groove wall of the guide groove 24. In the area of ​​the guide groove 24 in the lower pressure section 242, the guide wheel 323 can adaptively adjust its movement trajectory through rolling contact to prevent the flexible plate from deviating and getting stuck.

[0141] Furthermore, the flexible plate's two side edges are embedded in the guide grooves 24 of the inner box 2. A compression spring 315 is horizontally installed along the length of the guide groove 24, with one end fixed to the wall of the inner box 2 at the end of the guide groove 24, and the other end welded to the end of the flexible plate furthest from the electromagnetic switch 314. A pair of guide wheels 323 are symmetrically installed on both sides of the flexible plate's end. The guide wheels 323 are made of polytetrafluoroethylene (PTFE), and their rims contact the groove wall of the guide groove 24. The shafts of the guide wheels 323 are connected to the flexible plate via bearings, allowing the guide wheels 323 to roll along the guide groove 24 when the flexible plate slides.

[0142] Understandably, this application achieves automatic reset of the flexible plate through the elastic restoring force of the compression spring 315, reducing the driving load of the electromagnetic switch 314; the guide wheel 323 reduces the resistance when the flexible plate moves by replacing sliding friction with rolling friction, and avoids wear or deformation of the contact surface between the flexible plate and the guide groove 24 due to long-term friction, thereby maintaining the tight fit between the sealing strip and the groove wall and ensuring the sealing performance of the medicine outlet 22 in the closed state.

[0143] In one embodiment, such as Figure 10 and Figure 11As shown, the guide channel 24 includes a straight section 241 and a pressing section 242 connected to each other. The pressing section 242 and the electromagnetic switch 314 are located at both ends of the straight section 241 in the extension direction. The end of the pressing section 242 away from the straight section 241 extends towards the medicine chamber 21 away from the medicine outlet 22.

[0144] In this embodiment, the guide groove 24 consists of a straight section 241 and a pressing section 242. The two ends of the straight section 241 extend into the pressing section 242 and the mounting position for the electromagnetic switch 314, respectively. The end of the pressing section 242 away from the straight section 241 extends at a 15° slope towards the drug-containing cavity 21 and away from the drug outlet 22. The flexible plate is made of food-grade silicone material, and an annular silicone sealing strip is provided at its edge. This sealing strip forms an interference fit with the polypropylene wall of the guide groove 24 when the flexible plate slides along the guide groove 24. When the electromagnetic switch 314 is energized, the flexible plate is pulled to the end of the straight section 241. At this time, the contact surface between the sealing strip and the guide groove 24 experiences a compression deformation of 0.5 mm, forming a physical isolation barrier.

[0145] Understandably, this application effectively solves the problem of drug moisture absorption caused by poor sealing in the sliding dispensing structure of traditional medicine box 100. The combined structure of the straight section 241 and the pressing section 242 enables the flexible plate to form a height difference compensation during movement, so that the flexible plate can completely cover the dispensing port 22 and avoid movement jamming caused by processing errors. The continuous compression contact of the annular sealing strip in the guide groove 24 achieves full circumferential sealing protection in the closed state of the dispensing port 22.

[0146] Optionally, a sealing strip is provided around the periphery of the flexible plate. The flexible plate slides in the guide groove 24, and the sealing strip seals against the groove wall of the guide groove 24. It can be understood that the sealing strip around the periphery of the actuator 32, i.e., a sealing strip is provided around the periphery of the flexible plate, the flexible plate slides in the guide groove 24, and the sealing strip seals against the groove wall of the guide groove 24. The cooperation between the guide groove 24 and the sealing strip enhances the sealing performance of the medicine box 100, effectively preventing the medicine from becoming damp and deteriorating. Furthermore, this design facilitates cleaning and maintenance, improving the service life of the medicine box 100. The sealing strip is made of silicone or rubber, with a trapezoidal or rectangular cross-section, and is fixed to the edge of the actuator 32 by snap-fit ​​or adhesive.

[0147] In one embodiment, such as Figure 10 and Figure 11 As shown, the electromagnetic switch 314 is located on the side of the inner box 2 away from the medicine-containing cavity 21 and at the end of the actuator 32 in the direction of movement relative to the guide groove 24; or, the electromagnetic switch 314 is located on the side of the inner box 2 away from the medicine-containing cavity 21 and at the side of the actuator 32 in the direction of movement relative to the guide groove 24.

[0148] In this embodiment, when the electromagnetic switch 314 is fixed at the end of the guide groove 24 in the extending direction, its output end is coaxial with the moving direction of the actuator 32, directly pushing the flexible plate to translate along the straight section 241 of the guide groove 24; when the electromagnetic switch 314 is located on the side of the guide groove 24 in the extending direction, its output end is connected to the flexible plate through a linkage mechanism, converting linear motion into lateral displacement. When set at the end, the stroke of the electromagnetic switch 314 matches the length of the straight section 241 of the guide groove 24, ensuring that the flexible plate completely covers or completely detaches from the medicine outlet 22; when set on the side, the stroke of the electromagnetic switch 314 is adjusted by the transmission ratio so that the displacement of the flexible plate meets the opening and closing requirements.

[0149] Specifically, the electromagnetic switch 314 is installed on the back side of the inner housing 2. When it is located at the end of the guide groove 24 in the moving direction, after the electromagnetic switch 314 is energized, the output shaft pushes directly out along the axis of the guide groove 24, driving the flexible plate to compress the spring 315 and slide along the straight section 241 of the guide groove 24, so that the medicine outlet 22 is fully opened. After the power is cut off, the spring 315 pushes the flexible plate to reset and cover the medicine outlet 22. When the electromagnetic switch 314 is located on the side of the guide groove 24, the output shaft is connected to the flexible plate through the hinged transmission rod. The linear motion of the electromagnetic switch 314 is converted into the lateral sliding of the flexible plate along the guide groove 24. At this time, the lower section 242 of the guide groove 24 guides the flexible plate to deflect into the medicine cavity 21 at the moving end, avoiding interference with the medicine. Both arrangements reduce energy loss through rigid transmission paths. The end arrangement achieves efficient transmission of linear thrust, while the side arrangement uses spatial staggering to reduce the overall height.

[0150] Understandably, by limiting the installation position of the electromagnetic switch 314, this application ensures that the direction of the electromagnetic driving force matches the movement path of the actuator 32, effectively reducing energy loss during transmission. When the electromagnetic switch 314 is located at the end of the movement direction, it can directly push the actuator 32 to make linear displacement, avoiding jamming problems caused by transmission path deviation. When the electromagnetic switch 314 is located on the side of the movement direction, the driving force can be converted into linear motion of the actuator 32 through a transmission mechanism such as a lever or gear 316. This structural design allows for stable control of the opening and closing state of the dispensing port 22 without applying excessive torque when operating the button 31, significantly reducing the difficulty of operation for the user.

[0151] In one embodiment, such as Figures 12 to 15As shown, the pressing mechanism 3 also includes a mounting shell 33, which is disposed in the inner box 2 and located at the medicine outlet 22. The mounting shell 33 forms a medicine leakage cavity 331. The mounting shell 33 is provided with a medicine inlet 332 and a medicine leakage outlet 333 that communicate with the medicine leakage cavity 331. The medicine inlet 332 is connected to the medicine outlet 22, and the medicine leakage outlet 333 is located at the end of the mounting shell 33 away from the medicine inlet 332. The actuator 32 is rotatably disposed in the medicine leakage cavity 331. The button 31 is configured to push the actuator 32 to rotate, so as to move the medicine from the medicine inlet 332 to the medicine leakage outlet 333.

[0152] In this embodiment, the mounting shell 33 can be made of plastic and is cylindrical. The dispensing cavity 331 is a cylindrical cavity located inside the mounting shell 33. The inlet 332 is located at the top of the mounting shell 33 and is aligned and connected to the outlet 22 of the inner box 2. The dispensing outlet 333 is located at the bottom of the mounting shell 33. The actuator 32 is a cylindrical structure and can rotate freely within the dispensing cavity 331. The button 31 is located on the outside of the inner box 2 and is connected to the actuator 32 through a gear 316 transmission mechanism. In use, pressing the button 31 can drive the actuator 32 to rotate within the dispensing cavity 331, transferring the medicine from the inlet 332 to the dispensing outlet 333. The mounting shell 33 forms a continuous docking channel with the drug outlet 22 of the inner box 2 through the drug inlet 332. The drug leakage chamber 331 forms a closed drug transfer space. The drug leakage port 333 is set at the bottom end of the mounting shell 33 to form a directional outlet. The rotation axis of the actuator 32 is perpendicular to the drug movement direction. The cross-section of the drug leakage chamber 331 of the mounting shell 33 is arc-shaped to adapt to the rotation trajectory of the actuator 32.

[0153] Specifically, when button 31 is pressed down, actuator 32 rotates around its axis within the dispensing chamber 331 of mounting housing 33. The drug enters the dispensing chamber 331 through inlet 332 and is captured by the rotating surface of actuator 32. As actuator 32 continues to rotate, the drug slides along the arc-shaped inner wall of dispensing chamber 331 to the dispensing port 333, and is finally discharged directionally through the dispensing port 333. The dispensing chamber 331 of mounting housing 33 constrains the drug's movement path, preventing the drug from shifting or scattering during transfer. The rotation of actuator 32 causes the drug to be output continuously as single particles. The spacing between inlet 332 and dispensing port 333 ensures that only a single dose of drug is delivered with each rotation. The bottom of the dispensing chamber 331 of mounting housing 33 has an inclined guide surface, the angle of which matches the rotational angular velocity of actuator 32, allowing the drug to complete directional movement under the combined action of centrifugal force and gravity.

[0154] Understandably, this application achieves quantitative drug output. The leakage cavity 331 formed by the mounting shell 33 can hold a fixed dose of drug. The rotation of the actuator 32 can accurately transfer the drug from the inlet 332 to the leakage port 333. This structural design avoids random spillage of the drug and ensures the accuracy of the dosage each time. At the same time, the button 31 is simple and intuitive to operate, improving the ease of use of the medicine box 100. In addition, the combined structure of the mounting shell 33 and the inner box 2 enhances the sealing of the medicine box 100 and effectively prevents the drug from getting damp and deteriorating.

[0155] In one embodiment, such as Figure 14 As shown, the actuator 32 includes a rolling body 324 and a plurality of protrusions 325. The rolling body 324 is rotatably disposed in the drug dispensing chamber 331, and the plurality of protrusions 325 are arranged in a ring array around the periphery of the rolling body 324. Two adjacent protrusions 325 enclose each other to form a groove 326, and the plurality of grooves 326 are arranged in a ring array at intervals around the periphery of the rolling body 324. In the drug dispensing state, the groove 326 is configured to carry the drug and transfer the drug from the drug inlet 332 to the drug dispensing outlet 333.

[0156] In this embodiment, the rolling body 324 is a cylindrical structure with several protrusions 325 evenly distributed on its circumferential surface. The protrusions 325 are rectangular or semi-circular strips. The distance between adjacent protrusions 325 is greater than the outer diameter of a single drug. The bottom of the groove 326 is flush with the surface of the rolling body 324. The two ends of the rolling body 324 are connected to the side wall of the mounting shell 33 through the rotating shaft 322. The side wall of the groove 326 and the side of the protrusion 325 form a guide slope. In the drug dispensing state, the groove 326 is set to carry the drug and transfer the drug from the drug inlet 332 to the drug outlet 333.

[0157] Specifically, when button 31 drives actuator 32 to rotate, rolling body 324 rotates synchronously. Groove 326 follows the rotation trajectory, passing sequentially between drug inlet 332 and drug outlet 333. Drug in inlet 332 falls into groove 326 under gravity. Protrusion 325 on sidewall of groove 326 provides lateral restraint for drug. As rolling body 324 continues to rotate, groove 326 carries drug along inner wall of mounting shell 33 to above drug outlet 333. Drug leaves groove 326 due to gravity, completing drug dispensing. The grooves 326 are spaced to ensure that only one drug enters groove 326 with each rotation. The circular array of protrusions 325 keeps groove 326 in a vertical bearing state. Each rotation of rolling body 324 corresponds to one groove 326, completing a single drug transfer. This structure avoids drug accumulation and blockage, while ensuring the reliability of quantitative drug dispensing.

[0158] Understandably, by rotating the rolling body 324, the medication in the groove 326 is transferred from the inlet 332 to the outlet 333, achieving quantitative medication output. For example, one dose, two doses, or multiple doses may be dispensed from the outlet 333 with a single press; no limitation is made here. The groove 326 on the rolling body 324 can precisely control the amount of medication dispensed each time, avoiding excessive or insufficient medication. Simultaneously, the groove 326 structure between the protrusions 325 prevents medication leakage or jamming, ensuring the stability and reliability of medication delivery. Furthermore, this structure is simple and compact, easy to manufacture and assemble, improving the practicality of the medicine box 100.

[0159] In one embodiment, such as Figure 12 , Figure 14 as well as Figure 15 As shown, button 31 includes button 311, gear 316 and rack 317. Button 311 is elastically connected to inner box 2. Gear 316 is connected to rolling body 324. Gear 316 and rolling body 324 rotate coaxially. One end of rack 317 is connected to button 311, and the other end of rack 317 is meshed with gear 316.

[0160] In this embodiment, button 311 adopts an elastic connection structure to form a spring-back reset function. Gear 316 and rolling body 324 are coaxially arranged so that they have the same rotation axis 322. The meshing transmission between rack 317 and gear 316 converts the linear motion of button 311 into rotational motion. Specifically, when the user presses button 311, rack 317 moves in a straight line and drives gear 316 to rotate. Gear 316 and rolling body 324 rotate synchronously, causing the medicine carried in groove 326 to move from medicine inlet 332 to medicine outlet 333. After button 311 is released, the elastic connection structure drives rack 317 to reverse reset, and gear 316 remains stationary to prevent medicine from retraction. The gear 316 and rack 317 transmission mechanism accurately converts the linear displacement of manual operation into the rotation angle of actuator 32, ensuring that a single press action can stably transfer a quantitative amount of medicine and overcome the problem of low motion conversion efficiency in manual direct drive.

[0161] Understandably, this application implements a mechanical transmission connection between button 31 and actuator 32, allowing users to control drug delivery through simple pressing actions. This design simplifies operation and improves the ease of use of the pillbox 100. Simultaneously, the transmission mechanism of gear 316 and rack 317 provides stable and reliable motion transmission, ensuring the accuracy and controllability of drug delivery. Furthermore, the flexible connection design of button 311 provides good tactile feedback, enhancing the user's operating experience.

[0162] In one embodiment, the inner box 2 includes a box body, a first limiting member, and a second limiting member. The first limiting member and the second limiting member are spaced apart from each other in the box body and enclose a movable cavity. The movable rod 312 includes a movable rod 312 and a limiting part connected to each other. The movable rod 312 slides through the first limiting member and the second limiting member in sequence. One end of the movable rod 312 away from the limiting part abuts against the actuator 32. The limiting part is located in the movable cavity and limits abutting against the first limiting member. The elastic member limits abutting against the second limiting member and the limiting part.

[0163] In this embodiment, the box body can be injection molded from plastic material. The first and second limiting members can be integrally formed with the box body or detachably connected. The first and second limiting members are spaced apart so that the movable rod 312 passes through the first and second limiting members in sequence. The first limiting member, the box body, and the second limiting member together form a movable cavity. The movable rod 312 passes through the movable cavity, and the cross-section of the movable cavity can be cylindrical. The movable rod 312 can adopt a cylindrical structure, and its diameter is slightly smaller than the inner diameter of the corresponding hole on the first and second limiting members to achieve a sliding fit. The spaced arrangement of the first and second limiting members forms a fixed guide channel. The movable rod 312 passes through both to achieve double limiting and avoid lateral displacement.

[0164] Meanwhile, the movable rod 312 is provided with a limiting part. The movable rod 312 is rod-shaped, column-shaped, or rod-shaped, and there is no limitation here. The limiting part is located on the outer periphery of the movable rod 312 and extends away from the movable rod 312. Preferably, the limiting part can be disc-shaped, and its diameter is larger than the diameter of the movable rod 312. The limiting part is located in the movable cavity, and the two ends of the movable rod 312 pass through the first limiting member and the second limiting member, respectively. The elastic member can be a compression spring, which is sleeved on the movable rod 312. The contact between the limiting part and the first limiting member limits the maximum retraction position of the movable rod 312 to prevent excessive pressing from causing structural separation. The two ends of the elastic member abut against the second limiting member and the limiting part, respectively, to ensure that a uniform elastic force is generated during compression.

[0165] Specifically, when the movable rod 312 is pressed, the limiting part slides towards the second limiting member. The limiting part and the second limiting member together compress the elastic element, which is compressed and stores energy. At the same time, the end of the movable rod 312 protruding from the second limiting member pushes the actuator 32 away from the drug outlet 22. After the movable rod 312 is released, the elastic element releases energy, pushing the limiting part back to the first limiting member, causing the actuator 32 to re-seal the drug outlet 22. The distance between the first and second limiting members precisely controls the compression stroke of the elastic element, avoiding excessive deformation of the elastic element. The sliding cooperation between the movable rod 312 and the two limiting members further restricts the radial sway of the movable rod 312, ensuring the straightness of the movement path of the actuator 32. The drug storage box 6 is detachably connected to the movable rod 312. During the pressing process, the movable rod 312 drives the drug storage box 6 to move outward, facilitating the discharge of the drug from the drug outlet 22.

[0166] Understandably, the cooperation of the movable lever 312, the limiting part, and the elastic element enables the button 31 to have a self-resetting function, eliminating the need for an additional reset structure. At the same time, the connection between the movable lever 312 and the actuator 32 realizes the linkage between the pressing operation and the action of the actuator 32, improving the ease of use of the medicine box 100. In addition, the setting of the first and second limiting elements effectively limits the range of motion of the movable lever 312, ensuring the reliable operation of the pressing mechanism 3 and effectively improving the comfort and convenience of use.

[0167] In one embodiment, such as Figure 1 , Figure 4 , Figure 6 , Figure 8 , Figure 9 as well as Figure 18 As shown, the outer box 1 includes a support 11 and a tray 12. The support 11 is connected to the tray 12, and the inner box 2 is disposed on the support 11. The support 11 and the tray 12 are spaced apart and enclosed to form a medicine dispensing trough 13. In the medicine dispensing state, the medicine outlet 22 connects the medicine receiving cavity 21 and the medicine dispensing trough 13.

[0168] In this embodiment, the bracket 11 can be injection molded from plastic material. The bracket 11 is provided with multiple limiting grooves 326 or limiting holes so that the inner box 2 is limited in the limiting grooves 326 or limiting holes of the bracket 11, or the inner box 2 is detachably connected to the bracket 11. The tray 12 is connected to the bracket 11 and spaced apart from the bracket 11. The bottom of the bracket 11 is fixedly connected to the upper surface of the tray 12 by screws. The tray 12 is a flat plate or a groove 326 structure. The tray 12 is spaced apart from the bracket 11 to form a medicine dispensing slot 13. The medicine dispensing slot 13 has a medicine receiving port for the user to receive medicine. The medicine dispensing port 22 of the inner box 2 is arranged towards the tray 12 and is connected to the medicine dispensing slot 13.

[0169] Specifically, after pressing button 31 to push actuator 32 away from dispensing port 22, the medicine in the containing cavity 21 enters dispensing slot 13 between support 11 and tray 12 through dispensing port 22. Dispensing slot 13 temporarily contains and guides the medicine, and the user can directly remove the medicine from dispensing slot 13 at once without operating inner box 2 separately.

[0170] Understandably, the connection structure between the support 11 and the tray 12 ensures the stability of the dispensing trough 13 and prevents the medicine from spilling. The tray 12 can be made of transparent material to facilitate observation of the state of the medicine in the dispensing trough 13. When multiple inner boxes 2 are in the dispensing state at the same time, the medicine discharged from each dispensing port 22 is collected in the same area along the dispensing trough 13, further simplifying the medicine retrieval process.

[0171] The above technical solution enables convenient transfer of medication from the inner box 2 to the dispensing slot 13. Users do not need to remove the inner box 2 one by one; they can simply press the corresponding button 31 to send the medication to the unified dispensing slot 13, which greatly improves the efficiency and convenience of medication retrieval. At the same time, the design of the dispensing slot 13 prevents medication from scattering, ensuring medication safety and hygiene. In addition, the inner box 2 is fixed to the bracket 11, avoiding the inconvenience caused by frequent disassembly and assembly, and improving the overall user comfort of the medicine box 100.

[0172] In one embodiment, such as Figure 16 As shown, the support 11 has a ring structure, and the support 11 encloses and forms an inner cavity 111. The tray 12 is disposed in the inner cavity 111, and the tray 12 and the support 11 enclose and form an annular medicine dispensing groove 13. The medicine box 100 includes multiple inner boxes 2 and multiple pressing mechanisms 3. The multiple inner boxes 2 are arranged in a ring around the side of the support 11 facing away from the tray 12. Each button 31 is movably disposed in an inner box 2, and each actuator 32 is rotatably disposed in a medicine dispensing port 22.

[0173] In this embodiment, the support 11 can adopt a circular structure, with the support 11 itself forming a cylindrical inner cavity 111. The tray 12 is a cylindrical structure and is disposed in the inner cavity 111 of the support 11. At this time, the tray 12 and the support 11 together form an annular medicine dispensing groove 13. The medicine box 100 includes multiple inner boxes 2, which are evenly distributed on the outer circumference of the support 11. Each inner box 2 has a medicine dispensing port 22 at its bottom, and the medicine dispensing port 22 of each inner box 2 is oriented towards the central axis of the annular medicine dispensing groove 13. Each medicine dispensing port 22 is connected to the medicine dispensing groove 13. The multiple inner boxes 2 can be rotatably connected in sequence, such as through a shaft hole structure or through soft rubber connection to achieve rotatable connection. Furthermore, the multiple inner boxes 2 can be stored by curling and wrapping. Further, the button 31 of each pressing mechanism 3 is arranged along the radial direction of the inner box 2, and the actuator 32 is rotatably connected to the edge of the medicine dispensing port 22 through a rotating shaft.

[0174] Specifically, when medication needs to be retrieved, the user presses the buttons 31 of each inner box 2 sequentially along the annular support 11. The buttons 31 push the actuator 32 to rotate around the rotation axis, causing the actuator 32 to move away from the medication outlet 22. The medication falls into the annular medication outlet 13 through the medication outlet 22. Since multiple inner boxes 2 are arranged around the annular support 11, all medication outlets 22 face the central axis of the annular medication outlet 13. After passing through the medication outlet 22, the medication falls naturally along the direction of gravity into the same annular space of the annular medication outlet 13, and finally gathers along the circumference of the annular medication outlet 13 to the centralized medication retrieval area on the tray 12. Through the annular layout, the medications of different inner boxes 2 can be uniformly collected in the same annular space after being dispensed, avoiding the need to retrieve medications one by one from the scattered unit slots 123, thus simplifying the operation steps.

[0175] Through the above technical solution, this application achieves a circular arrangement of multiple inner boxes 2, allowing users to conveniently take out the medicine from different inner boxes 2 in sequence. The circular medicine dispensing slot 13 concentrates the medicine in one place for easy collection, and the press-type medicine dispensing mechanism is simple and intuitive to operate. The overall structure is compact and easy to use, improving the practicality of the medicine box 100, and the circular arrangement of the medicine box 100 also facilitates daily use by users.

[0176] In another embodiment of this utility model, the medicine box 100 includes multiple outer box bodies 1, each outer box body 1 including a support 11 and a tray 12, and at least one inner box body 2 is provided on each outer box body 1. The multiple outer box bodies 1 are rotatably connected to each other through the support 11. For example, one of two adjacent support 11 is provided with a rotating hole 23, and the other of two adjacent support 11 is provided with a rotating shaft 322. The rotating shaft 322 is rotatably disposed in the rotating hole 23 to realize the rotatable connection of the two adjacent outer box bodies 1, and to make the multiple outer box bodies 1 rotatably connected in sequence, so that the medicine box 100 can be rolled up and stored through the rotatable connection of the outer box bodies 1, thereby effectively reducing the space occupied by the conventional structure medicine box 100 and making it convenient for users to store and use.

[0177] In one embodiment, such as Figure 17 As shown, multiple inner boxes 2 are arranged in a ring to form a single-layer box 4. The medicine box 100 includes multiple single-layer box 4, the surrounding axes of the multiple single-layer box 4 coincide, and the multiple single-layer box 4 are stacked and abutted in sequence; the inner cavities 111 of the multiple single-layer box 4 are interconnected.

[0178] In this embodiment, the single-layer box 4 is formed by multiple inner boxes 2 arranged in a ring. Each single-layer box 4 is stacked along the same axis, and the layers are connected through an inner cavity 111. The design of coinciding around the axis ensures that the stacked single-layer box 4 maintains structural alignment, and the interconnected inner cavities 111 allow the drug to flow between different single-layer box 4s. The stacking and abutting method avoids misalignment between layers, and the connectivity of the inner cavities 111 enables uniform distribution of the drug among multiple layers.

[0179] Specifically, when the single-layer boxes 4 are stacked in a ring, the medication can be transferred from the upper layer to the lower layer through the inner cavity 111. Users can directly access the medication through the interconnected inner cavities 111 without disassembling each layer. For example, the inner cavities 111 of each single-layer box 4 are interconnected by axially aligned channels. The medication moves along these channels under gravity or external force. The stacked, abutting structure restricts the relative displacement between layers through physical contact, ensuring the stability of the communication path within the inner cavities 111. Therefore, users only need to operate the outermost box to complete the medication dispensing, reducing disassembly and assembly actions and improving ease of use.

[0180] For example, a single-layer box 4 is composed of six inner boxes 2 arranged in a circular array. The six inner boxes 2 are fixed together by a connecting frame to form a circular structure, with the central axis coinciding with the overall axis of the medicine box 100. Three single-layer boxes 4 are stacked axially, and adjacent single-layer boxes 4 are connected by a bottom snap-fit ​​structure and a top limiting groove. The inner cavities 111 of each single-layer box 4 are interconnected by drug delivery channels provided on the side walls of the inner boxes 2. Each inner box 2 has an independent drug-containing cavity 21. The drug outlet 22 at the bottom of the drug-containing cavity 21 is connected to the drug delivery channel of the adjacent single-layer box 4 through a drug delivery hose, forming a continuous drug delivery path.

[0181] Understandably, this application achieves an integrated design of a multi-level drug storage structure. The ring-stacked single-layer box 4 structure maintains the independence of each drug storage unit while, through axial stacking and interconnected drug delivery channels, allowing users to centrally retrieve all drugs without disassembling the single-layer box 4. This structure, through its axially stacked snap-fit ​​connection, ensures the assembly stability of the multi-layer structure and avoids the space waste caused by traditional horizontal arrangements. The interconnected drug delivery channels integrate the drug flow paths between the single-layer boxes 4, enabling drugs from different levels to be delivered through a unified outlet, effectively simplifying the user's operating procedures.

[0182] In one embodiment, such as Figure 1 , Figure 4 , Figure 6 , Figure 8 , Figure 9 as well as Figure 18 As shown, the outer box 1 also includes an upper cover 14 and a sealing element 15. The upper cover 14 is rotatably connected to the bracket 11, and the sealing element 15 is located on the side of the upper cover 14 facing the bracket 11. The inner box 2 is also provided with a medicine inlet 25, which is connected to the medicine storage chamber 21. In the medicine storage state, the upper cover 14 covers the inner box 2, and the sealing element 15 seals against the medicine inlet 25.

[0183] In this embodiment, the upper cover 14 is rotatably connected to the top of the bracket 11 via a hinge structure. The hinge structure includes two metal pivots 322 and matching pins. The sealing element 15 is made of silicone material and has an annular protruding structure in cross-section. It is fixed to the upper cover 14 by a hot-pressing process. The top of the inner box 2 is provided with a medicine inlet 25. The outer edge of the medicine inlet 25 forms an annular platform. When the upper cover 14 rotates around the hinge axis to the closed position, the annular protruding structure of the sealing element 15 is completely pressed against the annular platform of the medicine inlet 25, forming a line contact seal. The upper cover 14 is rotated... The upper cover 14 is connected to the bracket 11, and the sealing element 15 is fixed to the side surface of the upper cover 14 facing the bracket 11. The medicine inlet 25 is located on the top or side of the inner box 2 and communicates with the medicine containing cavity 21. When the upper cover 14 is in the closed position, the sealing element 15 covers and presses the edge area of ​​the medicine inlet 25 to form a physical seal. The rotation axis of the upper cover 14 can be located on the side or rear of the bracket 11 to facilitate one-handed operation of opening and closing by the user. The sealing element 15 can be made of elastic material, such as silicone or rubber, and its shape matches the edge of the medicine inlet 25 to ensure the tightness of the sealing contact surface.

[0184] Specifically, in the medication storage state, the user closes the top cover 14 around the rotation axis towards the support 11. The sealing element 15 deforms under the pressure of the top cover 14 and tightly fits the outer edge of the inlet 25, preventing external air, moisture, or impurities from entering the medication chamber 21. When medication needs to be replenished, the user lifts the top cover 14 upwards, and the sealing element 15 moves away from the inlet 25 with the top cover 14. At this time, medication can be loaded into the medication chamber 21 through the inlet 25. After loading, the top cover 14 is closed again, and the sealing element 15 presses the inlet 25 again to achieve a seal. In this process, the rotating connection structure simplifies the opening and closing operation, and the elastic sealing element 15 adaptively fits the inlet 25 under pressure, ensuring reliable sealing and preventing the medication from being affected by environmental factors during storage.

[0185] Through the above technical solution, this application solves the problem of drug moisture absorption caused by poor sealing of the inlet 25 in the existing medicine box 100, and avoids structural wear caused by frequent disassembly of the inner box 2. The rotating connection design between the top cover 14 and the bracket 11 makes the opening and closing operation direction of the inlet 25 consistent with the force direction of the human hand. The line contact sealing method between the sealing element 15 and the inlet 25 reduces the opening and closing resistance while ensuring airtightness. The elastic deformation characteristics of the silicone material can compensate for the gap in the sealing surface caused by assembly errors. When the user performs daily drug addition operations, the sealing state can be switched by pushing the top cover 14 with one hand, which effectively improves the stability of drug storage and operation efficiency. In addition, when the medicine box 100 includes multiple inner boxes 2, the top cover 14 can be used to replenish the medicine in multiple inner boxes 2 at one time, avoiding the need for the user to replenish the medicine in each inner box 2 and close them one by one in the traditional medicine box 100, thereby effectively improving the convenience and comfort of the medicine box 100.

[0186] In one embodiment, such as Figure 1 , Figure 4 , Figure 6 , Figure 8 , Figure 9 as well as Figure 18 As shown, the medicine box 100 includes multiple inner boxes 2, which are arranged in a rectangular array at intervals along a first direction and a second direction that are perpendicular to each other; the tray 12 includes a tray body 121 and multiple guide plates 122, which are disposed on the side of the tray body 121 facing the support 11, and the multiple guide plates 122 are spaced apart along the first direction to divide the medicine dispensing slot 13 into multiple unit slots 123; each unit slot 123 along the first direction corresponds to one inner box 2, and each unit slot 123 along the second direction corresponds to multiple inner boxes 2.

[0187] In this embodiment, multiple medicine boxes 100 are arranged in a rectangular array at intervals, and are arranged sequentially along a first direction and a second direction that are perpendicular to each other. The guide plate 122 is a parallel strip structure, and its length direction is consistent with the second direction. Between adjacent guide plates 122, a unit groove 123 is formed with a width equal to the arrangement spacing of a single inner box 2 in the first direction. The extension direction of the unit groove 123 is parallel to the second direction.

[0188] In this context, each unit slot 123 along the second direction corresponds to multiple inner boxes 2. When multiple inner boxes 2 corresponding to the same unit slot 123 are in the dispensing state, the medicine in the inner box 2 at that location can fall directly into the same unit slot 123 and slide out from the dispensing slot 13 along the first direction for the user to accept.

[0189] Through the above technical solution, this application realizes that the inner box 2 with different arrangement directions corresponds to the drug dispensing path of different unit slots 123, so that the drug is output in categories along the extension direction of the unit slot 123. When the user presses multiple inner boxes 2 along the second direction, the drug is guided to the same unit slot 123, avoiding the drug from being scattered to different areas. When the user operates along the first direction, different unit slots 123 correspond to different types of drugs, reducing the operation steps of searching for inner boxes 2 one by one and improving the efficiency of drug retrieval in scenarios with multiple inner boxes 2.

[0190] In one embodiment, the medicine box 100 includes two outer boxes 1, two supports 11 arranged in parallel and spaced apart, and two trays 12 connected to each other and located between the two supports 11; the medicine box 100 includes at least two inner boxes 2, each support 11 is provided with at least one inner box 2, and the medicine outlet 2 of the inner box 2 located on different supports 11 is arranged facing the tray 12.

[0191] In this embodiment, the medicine box 100 includes two outer boxes 1, each consisting of a support 11 and a rectangular tray 12. The two supports 11 are made of aluminum alloy and are fixed in parallel at intervals. The two trays 12 are integrally molded using injection molding and positioned between the two supports 11. At least one inner box 2 is mounted on the outer wall of each support 11. The medicine outlet 22 of the inner box 2 faces the tray 12. The medicine-containing cavity 21 inside the inner box 2 communicates with the medicine outlet 22, forming a medicine outlet groove 13 between the medicine outlet 22 and the tray 12. When the pressing mechanism 3 drives the actuator 32 to open, the medicine slides through the medicine guide channel into the groove 326 area on the surface of the tray 12 for centralized collection. The two outer boxes 1 are arranged with parallel and spaced supports 11, forming a symmetrical structure. Each support 11 independently supports the inner box 2. The tray 12 forms a shared medicine collection area between the two supports 11. The inner boxes 2 located on different supports 11 achieve centralized drug delivery through the medicine outlet 22 facing the tray 12.

[0192] Specifically, when the user presses the button 31 on the inner box 2 on different supports 11, the actuator 32 opens, and the medication falls vertically through the dispensing port 22 into the shared tray 12 area. Since the two supports 11 are arranged in parallel, the inner boxes 2 can be densely distributed along the length of the supports 11, and the tray 12, as a common collection area, can simultaneously hold medication from multiple inner boxes 2. During this process, the dispensing ports 22 of the inner boxes 2 located on different supports 11 all face the same tray 12, allowing for centralized medication collection, eliminating the need for the user to retrieve medication from multiple dispersed dispensing slots 13. Furthermore, the tray 12 adopts an integrated connection structure, and the distance between the two supports 11 is controlled within the range of 50-100 mm, ensuring structural stability while preventing the tray 12 from protruding excessively and affecting overall compactness.

[0193] Through the above technical solution, this application arranges two outer boxes 1 in parallel and places a tray 12 in the space between them, so that the drug outlets 22 of the inner boxes 2 on different supports 11 all face the same area of ​​the tray 12. This achieves centralized drug output, avoiding the operation of disassembling the inner boxes 2 one by one as required by the prior art, and reducing the number of drug retrieval actions. At the same time, the fixed connection structure between the tray 12 and the support 11 ensures a stable drug delivery path, prevents drug spillage, and improves the continuity and reliability of the drug retrieval operation.

[0194] In one embodiment, such as Figure 18As shown, the medicine box 100 also includes a controller and a display 5. The display 5 is located in the outer box 1 and is electrically connected to the controller. The display 5 is configured as a flat panel display device and is fixedly installed on the top or side of the outer box 1. Its display interface forms a continuous plane with the surface of the outer box 1. The controller is configured as a microprocessor unit and is installed in the internal cavity of the outer box 1. It establishes a data connection with the display 5 through a wired line. A signal conversion module is provided between the display 5 and the controller. This module converts the electrical signal output by the controller into an image signal that the display 5 can recognize.

[0195] Specifically, when a user performs a medication dispensing action using the pressing mechanism 3, the controller receives a trigger signal from button 31 and records the number of operations. The medication inventory data stored inside the controller decreases with each operation, and the updated inventory data is transmitted to the display 5 via a signal conversion module. The display 5 displays the remaining medication quantity, next dosing time, or medication type information in real time. The user can directly read the data through the surface of the outer box 1 without disassembling the inner box 2. The display interface uses a low-power LCD screen or e-ink screen, and its power supply circuit shares the same power module as the controller.

[0196] Understandably, display 5 can be an LCD screen or an LED screen, used to display data such as medication information and dosing time. The controller is connected to display 5 via a circuit and can send display commands to display 5 according to preset programs or user input to achieve intelligent management of the pillbox 100. The controller can record and process medication information, and display 5 can intuitively display relevant data to the user, such as remaining dosage and next dosing time. This design improves the accuracy and convenience of medication use, reduces the risk of users forgetting to take medication or taking medication twice, and can display messages of blessing and comfort, such as wishing you good health or a speedy recovery, to provide users with more humanistic care and improve user comfort. At the same time, the display 5 enables the pillbox 100 to have information interaction functions, enhancing the product's practicality and user experience.

[0197] Optionally, the medicine box 100 also includes a controller and a light assembly. The light assembly is located in the inner box 2 and is electrically connected to the controller. The light assembly consists of multiple LED beads arranged at intervals along the periphery of the top of the inner box 2 to form a ring light source. The controller is integrated inside the outer box 1 and is electrically connected to the light assembly via a flexible circuit board. The surface of the LED beads is covered with a translucent light guide film, through which light is evenly projected into the medicine-containing cavity 21. Furthermore, the light assembly includes red and green light-emitting units, and the controller switches the light color according to a preset program to distinguish the type of medicine.

[0198] Specifically, the light assembly is connected to the controller via wires that extend along the side wall of the inner housing 2 to the interior of the outer housing 1. When the user presses button 31 to trigger the dispensing state, the controller simultaneously receives an electrical signal and activates the light assembly. The LED beads emit a cold light source, and the light penetrates the light guide film to form diffuse reflection illumination, covering the areas of the drug-containing cavity 21 and the drug-dispensing port 22. When the ambient light intensity is below 50 Lux, the light assembly automatically switches to a high-brightness mode, making the outline of the drug clearly visible. For example, the controller has a built-in photosensor that monitors the ambient brightness in real time. When insufficient light is detected, the brightness of the LED beads is increased to 300 cd / m² through PWM dimming technology. As a result, the user can intuitively observe the movement trajectory of the drug, avoiding drug jamming or displacement during the pressing operation.

[0199] Meanwhile, the light assembly can include multiple LEDs evenly distributed along the periphery of the inner box 2. The controller can be a microprocessor with a preset medication schedule. When the preset medication time arrives, the controller activates the light assembly, causing the LEDs to flash or change color to remind the user to take the medication. Furthermore, the light assembly can use different colored LEDs to distinguish different types of medications or different medication time periods. For example, medications taken in the morning can be indicated by a yellow LED, and medications taken in the evening by a blue LED. Thus, the user can intuitively determine which medication to take based on the color of the light. The pillbox 100 includes multiple inner boxes 2, each corresponding to at least one LED. Different inner boxes 2 contain different quantities and weights of medication, and each inner box 2 has a different medication time corresponding to different medications. For example, some medications need to be taken at a certain time in the morning, while others need to be taken at a certain time in the afternoon. When the specific time arrives, the LED corresponding to each inner box 2 will flash to remind the user to take the medication in that inner box 2, making it convenient for the user.

[0200] Understandably, this application implements the intelligent reminder function of the pillbox 100, which improves the accuracy of users taking their medication on time. The visual prompts of the light group are intuitive and clear, and can effectively remind users even in noisy environments. In addition, different colored lights distinguish different drugs or medication times, which also reduces the risk of users accidentally taking or missing medications.

[0201] Optionally, the medicine box 100 also includes a controller and a speaker. The speaker is located in the inner box 2 and is electrically connected to the controller. The controller is configured to output an audio control signal, and the speaker generates sound wave vibrations according to the control signal. The speaker and the inner box 2 are embedded, with the speaker's diaphragm plane parallel to the side wall of the inner box 2 and the sound wave propagation direction perpendicular to the thickness direction of the inner box 2. In one implementation, the controller has a built-in timing module. When a preset time node is reached, the speaker is triggered to output a prompt tone with a frequency of 800-3000Hz, and can also play blessings and comforting messages, such as wishing you good health or a speedy recovery, to provide users with more humanistic care and improve user comfort. Furthermore, the speaker wire extends along the inner wall of the inner box 2 and forms a plug-in electrical connection with the controller circuit board through elastic contacts.

[0202] Specifically, the controller monitors the current time via a real-time clock chip. When it matches a preset medication time, it sends a pulse-width modulation (PWM) signal to the speaker. The voice coil inside the speaker reciprocates under the influence of alternating current, causing the diaphragm to compress air and generate sound waves. The sound waves radiate outward through the through-holes on the side wall of the inner housing 2, prompting the user to perform a pressing operation. As the user pushes the button 31, the controller simultaneously detects the displacement of the actuator 32. When the displacement reaches a threshold, the speaker outputs a short beep, providing operation confirmation feedback. During this process, the sound wave energy is concentrated within a 1.5-meter propagation distance, and the sound pressure level is controlled within the range of 50-70 decibels, ensuring effective reminders while avoiding noise pollution.

[0203] Meanwhile, the controller, which can be a microprocessor or a microcontroller, is installed on one side of the inner casing 2. The speaker is installed on the other side of the inner casing 2 and connected to the controller via a wire. The controller can send a signal to the speaker when the scheduled medication time arrives, triggering the speaker to emit a reminder sound. For example, the controller can be set to provide three timed reminders daily, triggering the speaker to play the voice prompt "Please take your medication on time" at 8:00 AM, 12:00 PM, and 8:00 PM respectively. Furthermore, the speaker can also play different types of prompts according to the controller's instructions, such as playing different prompts for different medications, to help the user distinguish between them.

[0204] Understandably, this application implements an intelligent reminder function for the Pillbox 100. This eliminates the need for users to constantly monitor medication times, reducing their memory burden. Furthermore, voice reminders are more intuitive and effective than visual cues, making them particularly suitable for elderly users with poor eyesight. In addition, by setting different prompts, users can accurately identify the type of medication they need to take, further improving the accuracy and safety of medication use.

[0205] The above description is merely an exemplary embodiment of the present utility model and does not limit the patent scope of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the patent protection scope of the present utility model.

Claims

1. A medicine box, characterized in that, The medicine box includes: Outer box; An inner box body is disposed within an outer box body. The inner box body has a medicine-containing cavity and a medicine-dispensing outlet. The medicine-containing cavity is configured to contain medicine, and the medicine-dispensing outlet communicates with the medicine-containing cavity. The pressing mechanism includes a button and an actuator. The actuator is movably disposed in the inner box and located at the medicine outlet. The button is disposed in the inner box and connected to the actuator. The medicine box has a medicine storage state in which the actuator blocks the medicine outlet and a medicine dispensing state in which the actuator moves away from the medicine outlet. In the medicine dispensing state, the button pushes the actuator away from the medicine outlet, and the medicine is delivered from the medicine outlet.

2. The medicine box as described in claim 1, characterized in that, The inner box is provided with a rotating hole, which is located around the periphery of the medicine outlet; The actuator includes a plate and a rotating shaft. The rotating shaft is disposed on the plate and rotatably disposed in the rotating hole. The rotating shaft is elastically connected to the inner box. The button is connected to the plate. The plate is configured to cover or be away from the medicine outlet.

3. The medicine box as described in claim 2, characterized in that, The button includes a button and a movable lever. The button is connected to the movable lever and is movably disposed in the inner box. The end of the movable lever away from the button is connected to the plate. And / or, the actuator further includes a torsion spring, which is sleeved on the rotating shaft, with one end of the torsion spring elastically abutting against the inner box and the other end of the torsion spring elastically abutting against the plate.

4. The medicine box as described in claim 2, characterized in that, The button is located on the side of the inner box that faces away from the medicine-containing cavity and is situated at the periphery of the inner box. Alternatively, the button may be located within the medicine-containing cavity; Alternatively, the inner box may have a recessed portion that protrudes towards one side of the medicine-containing cavity, and the button may be located on the side of the recessed portion opposite to the medicine-containing cavity.

5. The medicine box as described in claim 1, characterized in that, The inner box has an installation cavity, and the medicine box also includes a medicine storage box, a differential shaft and an elastic element. The medicine storage box is located in the installation cavity, the elastic element is connected to the medicine storage box and the cavity wall of the installation cavity, and the differential shaft is connected to the medicine storage box. The inner box also includes a push rod, which slides within the mounting cavity, and a limiting tooth is provided at the end of the push rod facing the differential shaft; When the medicine storage box is pressed, the differential shaft rotates relative to the push rod. The medicine storage box has a protruding state where the differential shaft abuts against the limiting tooth and a retracted state where the differential shaft moves away from the limiting tooth.

6. The medicine box as described in claim 1, characterized in that, The button includes a button and a first inclined block. The button is elastically connected to the inner box, and the first inclined block is provided with a first inclined surface. The inner box body has a second inclined block on the side facing the first inclined block, and the second inclined block has a second inclined surface, with the first inclined surface and the second inclined surface abutting each other; When the button is pressed, the first and second inclined blocks slide relative to each other, and the inner box moves in the opposite direction to the button.

7. The medicine box as described in any one of claims 1 to 6, characterized in that, The inner box is provided with guide grooves, which are arranged in parallel on both sides of the opposite periphery of the medicine outlet. The actuator is slidably disposed in the guide grooves and elastically connected to the inner box. The button includes a button and an electromagnetic switch, the button and the electromagnetic switch are electrically connected, the button is movably disposed in the inner box, and the electromagnetic switch is connected to the actuator; The electromagnetic switch moves to drive the actuator to slide along the guide groove.

8. The medicine box as described in claim 7, characterized in that, The actuator is a flexible plate, the side of which is slidably disposed in the guide groove, and the flexible plate is connected to the output end of the electromagnetic switch; The electromagnetic switch drives the flexible plate to move along the guide groove to cover or move away from the drug outlet.

9. The medicine box as described in claim 8, characterized in that, The actuator includes the flexible plate and a compression spring. The compression spring extends along the direction of the guide groove. One end of the compression spring is connected to the inner box, and the other end of the compression spring is connected to the end of the flexible plate away from the electromagnetic switch. And / or, the actuator further includes a guide wheel connected to the end of the flexible plate away from the electromagnetic switch, the guide wheel being rotatably disposed in the guide groove.

10. The medicine box as described in claim 8, characterized in that, The guide channel includes a straight section and a pressing section connected to each other. The pressing section and the electromagnetic switch are located at both ends of the straight section in the extension direction. The end of the pressing section away from the straight section extends towards the medicine-containing cavity away from the medicine outlet. And / or, the flexible plate is provided with a sealing strip around its periphery, the flexible plate is slidably disposed in the guide groove, and the sealing strip seals against the groove wall of the guide groove.

11. The medicine box as described in claim 7, characterized in that, The electromagnetic switch is located on the side of the inner box facing away from the medicine-containing cavity, and at the end of the actuator relative to the direction of movement of the guide groove; Alternatively, the electromagnetic switch may be located on the side of the inner box facing away from the drug-containing cavity, and on the side of the actuator relative to the direction of movement of the guide groove.

12. The medicine box as described in any one of claims 1 to 6, characterized in that, The pressing mechanism also includes a mounting shell, which is disposed in the inner box and located at the medicine outlet; The mounting shell forms a drug leakage cavity. The mounting shell is provided with a drug inlet and a drug leakage outlet that communicate with the drug leakage cavity. The drug inlet is connected to the drug outlet. The drug leakage outlet is located at the end of the mounting shell away from the drug inlet. The actuator is rotatably disposed in the drug leakage chamber, and the button is configured to push the actuator to rotate so as to move the drug from the drug inlet to the drug leakage outlet.

13. The medicine box as described in claim 12, characterized in that, The actuator includes a rolling body and a plurality of protrusions. The rolling body is rotatably disposed in the drug leakage cavity, and the plurality of protrusions are arranged in a ring array around the periphery of the rolling body. Two adjacent protrusions enclose and form a groove, and a plurality of grooves are arranged in a ring array at intervals around the periphery of the rolling body; In the dispensing state, the groove is configured to hold the drug and transfer the drug from the inlet to the outlet.

14. The medicine box as described in claim 13, characterized in that, The buttons include: A button, which is elastically connected to the inner box; A gear, the gear being connected to the rolling body, the gear rotating coaxially with the rolling body; and A rack, one end of which is connected to the button, and the other end of which is engaged with the gear.

15. The medicine box as described in any one of claims 1 to 6, characterized in that, The outer box includes a support and a tray, the support is connected to the tray, and the inner box is disposed on the support; The support and the tray are spaced apart and enclosed to form a medicine dispensing trough. In the medicine dispensing state, the medicine outlet is connected to the medicine receiving cavity and the medicine dispensing trough.

16. The medicine box as described in claim 15, characterized in that, The support is a ring structure, the support encloses to form an inner cavity, the tray is disposed in the inner cavity, and the tray and the support enclose to form the ring-shaped medicine dispensing groove; The medicine box includes multiple inner boxes and multiple pressing mechanisms. The multiple inner boxes are arranged in a ring around the side of the support facing away from the tray. Each button is movably located in one of the inner boxes, and each actuator is rotatably located in one of the medicine outlets.

17. The medicine box as described in claim 16, characterized in that, Multiple inner box bodies are arranged in a ring to form a single-layer box body. The medicine box includes multiple single-layer box bodies, the circumferential axes of the multiple single-layer box bodies coincide, and the multiple single-layer box bodies are stacked and abutted in sequence. The inner cavities of the multiple single-layer boxes are interconnected.

18. The medicine box as described in claim 15, characterized in that, The outer box also includes a top cover and a sealing element. The top cover is rotatably connected to the bracket, and the sealing element is located on the side of the top cover facing the bracket. The inner box is also provided with a medicine inlet, which is connected to the medicine-containing cavity. In the medicine-storing state, the upper cover closes the inner box, and the sealing element seals against the medicine inlet.

19. The medicine box as described in claim 15, characterized in that, The medicine box includes multiple inner boxes, which are arranged in a rectangular array at intervals along a first and a second direction that are perpendicular to each other. The tray includes a tray body and multiple guide plates. The guide plates are disposed on the side of the tray body facing the support. The multiple guide plates are spaced apart along the first direction to divide the medicine dispensing slot into multiple unit slots. Each unit slot along the first direction corresponds to one inner box, and each unit slot along the second direction corresponds to multiple inner boxes.

20. The medicine box as described in claim 15, characterized in that, The medicine box includes two outer box bodies, two brackets arranged in parallel and spaced apart, and two trays connected to each other and located between the two brackets; The medicine box includes at least two inner boxes, and each bracket has at least one inner box. The medicine outlet of the inner box located on different brackets is oriented toward the tray.

21. The medicine box as described in any one of claims 1 to 6, characterized in that, The medicine box also includes a controller and a display, the display being disposed in the outer box and electrically connected to the controller; And / or, the medicine box further includes a controller and a light assembly, the light assembly being disposed in the inner box and electrically connected to the controller; And / or, the medicine box further includes a controller and a speaker, the speaker being disposed in the inner box and electrically connected to the controller.