A component storage device with an anti-drop structure
The component storage device with an anti-drop structure, using baffle-block locking and sponge cushioning design, solves the problem of components popping out during transportation, and achieves stable storage and convenient access to components.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI MAKINO ENVIRONMENTAL INNOVATION INTELLIGENT TECHNOLOGY CO LTD
- Filing Date
- 2025-09-04
- Publication Date
- 2026-06-30
AI Technical Summary
Traditional storage devices are difficult to prevent small components from popping out of the slots and scattering during transportation and handling, and are also difficult to protect the components from physical damage.
The component storage device adopts an anti-drop structure, which uses a baffle-block locking structure and a sponge buffer fixing design, combined with a push plate-top rod material picking component design. The components are fixed by friction and buffer material to prevent them from popping out and to protect them.
It effectively prevents components from popping out during transportation and handling, protects components from damage, and facilitates the access of small or pin-dense components.
Smart Images

Figure CN224428358U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of component storage equipment technology, and in particular to a component storage device with an anti-fall-off structure. Background Technology
[0002] In fields such as electronics manufacturing, repair, laboratory research and development, and education, the storage and management of a vast number and diverse range of bulk electronic components, including resistors, capacitors, integrated circuits, transistors, and connectors, has always been a fundamental and critical challenge. Traditional storage solutions mainly use plastic storage boxes or dividers, whose ability to prevent components from falling out relies entirely on the simple physical relationship between the weight of the components themselves and the depth of the compartments. Once the device is subjected to external disturbances, such as bumps during transportation, accidental tilting during handling, or even the inertia of opening and closing drawers, small components can easily pop out of the compartments and scatter. Utility Model Content
[0003] The purpose of this invention is to address the shortcomings of existing technologies by proposing a component storage device with an anti-drop structure.
[0004] To achieve the above objectives, the present invention adopts the following technical solution: a component storage device with an anti-drop structure, comprising a second groove, a connecting block hinged to one end of the second groove, and a first groove with the same internal structure as the second groove hinged to the other end of the connecting block. Two baffles are symmetrically hinged to the inner side of the second groove, one of the baffles having a sliding insert block inside, and the other baffle having a slot at its end. Multiple equally spaced storage slots are fixedly connected inside the second groove, and a sponge block is fixedly connected inside the storage slot. A storage opening is penetrated through the sponge block. A material retrieval component is slidably connected inside the second groove, and the material retrieval component slides through the storage slot.
[0005] As a further description of the above technical solution: two first fixing blocks are symmetrically fixed at the end of the first groove, and a positioning groove is opened on the bottom surface of the first fixing block. Two second fixing blocks are symmetrically fixed on the outside of the second groove, and a through groove is passed through the top surface of the second fixing blocks. An L-shaped block is slidably inserted in the through groove. Two fourth sliding grooves are symmetrically opened in the through groove. A fourth slider is slidably connected in the fourth sliding groove. The fourth slider is fixedly connected to the L-shaped block. A third spring is fixed between the inner wall of the fourth sliding groove and the fourth slider.
[0006] As a further description of the above technical solution: an avoidance groove is formed on the outside of the baffle, a toggle block is slidably connected in the avoidance groove, a groove is formed in the avoidance groove, a guide plate is slidably connected in the groove, the guide plate is fixedly connected to the toggle block, the insert block is fixedly connected to the guide plate, and the insert block slidably passes through the groove.
[0007] As a further description of the above technical solution: two third sliding grooves are symmetrically opened in the groove, a third slider is slidably connected in the third sliding groove, the third slider is fixedly connected to the guide plate, and a second spring is fixed between the inner wall of the third sliding groove and the third slider.
[0008] As a further description of the above technical solution: the material receiving component includes a second trapezoidal block slidably connected to the second groove, the inclined surface of the second trapezoidal block is fitted with a matching first trapezoidal block, the top surface of the first trapezoidal block is fixedly connected to a support plate, the support plate is slidably connected to the second groove, the top surface of the support plate is vertically fixed to a push rod, the push rod slidably passes through the storage groove and extends into the storage opening, the storage opening is provided with a push plate, and the push plate is fixed to the top surface of the push rod.
[0009] As a further description of the above technical solution: two second sliding grooves are symmetrically opened on the inner wall of the second groove, and a second slider is slidably connected in the second sliding groove. The second slider is fixedly connected to the support plate, and a first spring is fixed between the inner wall of the second sliding groove and the second slider.
[0010] As a further description of the above technical solution: a first sliding groove is formed on the bottom surface of the second groove, a first slider is slidably connected in the first sliding groove, the first slider is fixed on the bottom surface of the second trapezoidal block, and a bolt is rotatably connected to the side of the second trapezoidal block, the bolt thread passing through the second groove.
[0011] This utility model has the following beneficial effects:
[0012] 1. Compared with existing technologies, this component storage device with an anti-fall-off structure, through its innovative "baffle-block" locking structure and internal sponge cushioning and fixing design, provides double protection to prevent components from popping out of the slots or scattering due to inertia, vibration, or tilting during transportation, handling, and opening and closing of drawers. This completely solves the biggest pain point of traditional solutions. The sponge blocks in the storage slots not only fix the components with friction but also prevent physical damage caused by collisions or friction with the hard plastic box during movement, thus improving the preservation quality of the components.
[0013] 2. Compared with existing technologies, this component storage device with an anti-drop structure and a unique "push plate-top rod" material handling design solves the problem of traditional deep-grid components being difficult to pick out with fingers. Rotating the bolt drives the second trapezoidal block to move. The second trapezoidal block pushes the support plate upward through the first trapezoidal block. The support plate drives the top rod and push plate to smoothly push the components in the storage opening of the sponge block out from the bottom. It is especially suitable for small, thin, or densely pinned components, making them very convenient to retrieve. Attached Figure Description
[0014] Figure 1 A three-dimensional view of the overall structure of a component storage device with an anti-drop structure proposed in this utility model;
[0015] Figure 2 This is a side sectional view of the overall structure of a component storage device with an anti-drop structure proposed in this utility model;
[0016] Figure 3 This utility model proposes a component storage device with an anti-drop structure. Figure 2 Enlarged view of the structure at point A in the middle;
[0017] Figure 4 This utility model proposes a component storage device with an anti-drop structure. Figure 2 Enlarged view of the structure at point B;
[0018] Figure 5 This is a partial sectional view of the baffle structure of a component storage device with an anti-fall-off structure proposed in this utility model.
[0019] Legend:
[0020] 1. First groove; 2. Bolt; 3. First fixing block; 4. Positioning groove; 5. Baffle; 6. Insert block; 7. Second fixing block; 8. L-shaped block; 9. Second groove; 10. Connecting block; 11. Slot; 12. Sponge block; 13. Top rod; 14. Support plate; 15. First trapezoidal block; 16. Second trapezoidal block; 17. First slide groove; 18. First slider; 19. Second slide groove; 20. Second slider; 21. First spring; 22. Storage groove; 23. Storage opening; 24. Push plate; 25. Pulley block; 26. Guide plate; 27. Clearance groove; 28. Groove; 29. Third slide groove; 30. Second spring. Detailed Implementation
[0021] 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 protection scope of the present utility model.
[0022] Reference Figures 1 to 5This utility model provides a component storage device with an anti-detachment structure: It includes a second groove 9, one end of which is hinged to a connecting block 10, and the other end of the connecting block 10 is hinged to a first groove 1 with the same internal structure as the second groove 9. Two baffles 5 are symmetrically hinged to the inner side of the second groove 9. An insert 6 is slidably inserted into the interior of one of the baffles 5. An avoidance groove 27 is formed on the outside of the baffle 5, and a lever 25 is slidably connected within the avoidance groove 27. A groove 28 is formed within the avoidance groove 27, and a guide plate 26 is slidably connected within the groove 28. The guide plate 26 is fixedly connected to the lever 25, and the insert 6... The guide plate 26 is fixedly connected, the insert block 6 slides through the groove 28, two third sliding grooves 29 are symmetrically opened in the groove 28, the third slider is slidably connected in the third sliding groove 29, the third slider is fixedly connected to the guide plate 26, the inner wall of the third sliding groove 29 and the third slider are fixed together with the second spring 30, the end of another baffle 5 is opened with a slot 11, multiple equally distributed storage slots 22 are fixedly connected in the second groove 9, a sponge block 12 is fixedly connected in the storage slot 22, the storage port 23 is passed through the sponge block 12, and a material picking component is slidably connected in the second groove 9, the material picking component slides through the storage slot 22;
[0023] Two first fixing blocks 3 are symmetrically fixed at the end of the first groove 1. A positioning groove 4 is opened on the bottom surface of the first fixing block 3. Two second fixing blocks 7 are symmetrically fixed on the outside of the second groove 9. The top surface of the second fixing block 7 passes through the through groove. An L-shaped block 8 is slidably inserted in the through groove. Two fourth sliding grooves are symmetrically opened in the through groove. A fourth slider is slidably connected in the fourth sliding groove. The fourth slider is fixedly connected to the L-shaped block 8. A third spring is fixed between the inner wall of the fourth sliding groove and the fourth slider.
[0024] The material handling component includes a second trapezoidal block 16 slidably connected within the second tank 9. The inclined surface of the second trapezoidal block 16 is fitted with a matching first trapezoidal block 15. A support plate 14 is fixedly connected to the top surface of the first trapezoidal block 15. The support plate 14 is slidably connected within the second tank 9. A push rod 13 is vertically fixed to the top surface of the support plate 14. The push rod 13 slidably penetrates the storage tank 22 and extends into the storage opening 23. A push plate 24 is provided within the storage opening 23 and is fixed to the top surface of the push rod 13. The inner wall of the second tank 9... Two second slide grooves 19 are symmetrically opened, and a second slider 20 is slidably connected in the second slide groove 19. The second slider 20 is fixedly connected to the support plate 14. The inner wall of the second slide groove 19 and the second slider 20 are jointly fixed with the first spring 21. A first slide groove 17 is opened on the bottom surface of the second groove 9, and a first slider 18 is slidably connected in the first slide groove 17. The first slider 18 is fixed to the bottom surface of the second trapezoidal block 16. A bolt 2 is rotatably connected to the side of the second trapezoidal block 16, and the bolt 2 is threaded through the second groove 9.
[0025] Working principle: In use, multiple components are stored in the storage openings 23 of the sponge blocks 12 within the first and second slots 1 and 9. Then, the two pairs of baffles 5 are rotated, and simultaneously, the insert block 6 is pushed into the groove 28 by the lever 25. The second spring 30 is compressed, causing the two baffles 5 to merge together, protecting the first and second slots 1 and 9. Then, the lever 25 is released, and the compressed second spring 30 returns to its original position, allowing the positioning block to be inserted into the slot 11. Then, the L-shaped block 8 is pushed downwards, making its top surface flush with the top surface of the second fixing block 7. At the same time, the third spring is compressed, and the first and second slots 9 merge together. Then, the L-shaped block 8 is released, and the compressed third spring returns to its original position, allowing the L-shaped block 8 to be inserted into the slot 11. The components are stored in the positioning groove 4 of the first fixed block. When they need to be removed, the L-shaped block 8 is pushed down to separate it from the first fixed block 3. Then, the first groove 1 is flipped open. Next, the insert 6 is pulled from the slot 11 into the groove 28 by the pusher 25. Then, the baffle 5 is flipped open. Then, the bolt 2 is rotated, which moves the second trapezoidal block 16. The inclined surface of the second trapezoidal block 16 drives the first trapezoidal block 15 to rise. The first trapezoidal block 15 drives the support plate 14 to rise. The support plate 14 drives the top rod 13 and the push plate 24 to rise, so that the push plate 24 pushes the components in the storage port 23 of the sponge block 12 out to a certain height. Then, the components that have been pushed out can be taken out from the storage port 23 of the sponge block 12.
[0026] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A component storage device with anti-falling structure, comprising a second groove body (9), characterized in that: One end of the second trough (9) is hinged to a connecting block (10), and the other end of the connecting block (10) is hinged to a first trough (1) with the same internal structure as the second trough (9). Two baffles (5) are symmetrically hinged to the inner side of the second trough (9). An insert (6) is slidably inserted inside one of the baffles (5), and a slot (11) is opened at the end of the other baffle (5). Multiple storage slots (22) are fixedly connected inside the second trough (9). A sponge block (12) is fixedly connected inside the storage slot (22). A storage opening (23) is penetrated through the sponge block (12). A material picking device is slidably connected inside the second trough (9). The material picking device slidably penetrates the storage slot (22).
2. The component storage device with an anti-drop structure according to claim 1, characterized in that: Two first fixing blocks (3) are symmetrically fixed at the end of the first groove (1). A positioning groove (4) is opened on the bottom surface of the first fixing block (3). Two second fixing blocks (7) are symmetrically fixed on the outside of the second groove (9). The top surface of the second fixing block (7) passes through the through groove. An L-shaped block (8) slides through the through groove. Two fourth sliding grooves are symmetrically opened in the through groove. A fourth slider is slidably connected in the fourth sliding groove. The fourth slider is fixedly connected to the L-shaped block (8). A third spring is fixed between the inner wall of the fourth sliding groove and the fourth slider.
3. The component storage device with an anti-drop structure according to claim 1, characterized in that: The baffle (5) has an clearance groove (27) on its outside. A lever (25) is slidably connected in the clearance groove (27). A groove (28) is opened in the clearance groove (27). A guide plate (26) is slidably connected in the groove (28). The guide plate (26) is fixedly connected to the lever (25). The insert (6) is fixedly connected to the guide plate (26). The insert (6) slides through the groove (28).
4. A component storage device with an anti-drop structure according to claim 3, characterized in that: Two third sliding grooves (29) are symmetrically opened in the groove (28). A third slider is slidably connected in the third sliding groove (29). The third slider is fixedly connected to the guide plate (26). The second spring (30) is fixed between the inner wall of the third sliding groove (29) and the third slider.
5. A component storage device with an anti-drop structure according to claim 1, characterized in that: The material handling component includes a second trapezoidal block (16) slidably connected in the second groove (9), the inclined surface of the second trapezoidal block (16) is fitted with a matching first trapezoidal block (15), the top surface of the first trapezoidal block (15) is fixedly connected to a support plate (14), the support plate (14) is slidably connected in the second groove (9), the top surface of the support plate (14) is vertically fixed with a top rod (13), the top rod (13) slidably passes through the storage groove (22) and extends into the storage opening (23), the storage opening (23) is provided with a push plate (24), the push plate (24) is fixed to the top surface of the top rod (13).
6. A component storage device with an anti-drop structure according to claim 5, characterized in that: The inner wall of the second groove (9) is symmetrically provided with two second sliding grooves (19). The second sliding groove (19) is slidably connected to the second slider (20). The second slider (20) is fixedly connected to the support plate (14). The inner wall of the second sliding groove (19) and the second slider (20) are fixed together with the first spring (21).
7. A component storage device with an anti-drop structure according to claim 5, characterized in that: The bottom surface of the second groove (9) is provided with a first sliding groove (17), and a first slider (18) is slidably connected in the first sliding groove (17). The first slider (18) is fixed on the bottom surface of the second trapezoidal block (16). The side of the second trapezoidal block (16) is rotatably connected with a bolt (2), and the bolt (2) is threaded through the second groove (9).