Palladium chloride crystal sub-packaging bottle
By designing a protective shell structure and discharge control components for palladium chloride crystal dispensing bottles, the problem of existing dispensing bottles being unable to control the size of the discharge port has been solved, achieving higher durability and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YANGZHOU XINLIANG NEW MATERIAL TECHNOLOGY CO LTD
- Filing Date
- 2025-04-24
- Publication Date
- 2026-06-05
AI Technical Summary
Existing palladium chloride crystal dispensing bottles lack effective protection for the bottle body and cannot control the size of the discharge port according to needs, resulting in unsafe operation and easy crystal spillage.
A palladium chloride crystal dispensing bottle was designed, comprising a bottle body, a first protective shell, a second protective shell, a bolt assembly, a rotating shaft, a sealing strip, a first rotating rod, a driven gear, a driving gear, a second rotating rod, a rotating compass, and a dispensing plate. Through the combination of these components, the size of the dispensing port can be controlled and the bottle body can be protected.
It improves the durability of dispensing bottles, reduces the risk of crystal spillage due to improper handling, and enhances the safety and controllability of experimental operations.
Smart Images

Figure CN224324407U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of palladium chloride storage, specifically a palladium chloride crystal dispensing bottle. Background Technology
[0002] Palladium chloride is an important inorganic compound with a variety of applications. It can be used to prepare special catalysts and molecular sieves, as well as for formulating coatings for non-conductive materials, manufacturing gas-sensitive elements, and as an analytical reagent. Its wide application in chemical, electronic, and scientific research fields makes the demand for and use of palladium chloride quite widespread. Using specialized dispensing bottles can provide excellent sealing performance, preventing crystal leakage, avoiding contact and inhalation, and ensuring the safety and health of users. Therefore, a palladium chloride crystal dispensing bottle is needed.
[0003] Existing palladium chloride crystal dispensing bottles lack effective protection for the bottle body during operation and cannot control the size of the discharge port according to needs. Therefore, there is an urgent need for a new palladium chloride crystal dispensing bottle. Utility Model Content
[0004] Therefore, the purpose of this utility model is to provide a palladium chloride crystal dispensing bottle to solve the problem that existing palladium chloride crystal dispensing bottles lack effective protection for the bottle body and cannot control the size of the discharge port according to needs.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a palladium chloride crystal dispensing bottle, comprising a bottle body, a first protective shell installed on the outer wall of the bottle body, a second protective shell installed on the outer wall of the bottle body, a bolt assembly installed on the inner wall of the second protective shell, a rotating shaft installed on the outer wall of the first protective shell, a sealing strip installed on the inner wall of the first protective shell, and a cap installed on the top of the bottle body.
[0006] A first rotating rod is installed on the inner wall of the bottle body. A driven gear is installed on the outer wall of the first rotating rod. A driving gear is installed on the outer wall of the driven gear. A second rotating rod is installed on the outer wall of the driving gear. A rotating compass is installed on the outer wall of the second rotating rod. A discharge plate is installed on the outer wall of the bottle body. A first discharge port, a second discharge port, a third discharge port, a fourth discharge port, and a fifth discharge port are opened on the outer wall of the discharge plate. A discharge plate is installed on the top of the first rotating rod.
[0007] Preferably, the second protective shell forms a rotating structure with the first protective shell via a rotating shaft, and the first protective shell and the second protective shell are threadedly connected.
[0008] Preferably, the outer walls of both the first protective shell and the second protective shell are grooved, and both the first protective shell and the second protective shell are inserted into the sealing strip.
[0009] Preferably, the driving gear forms a rotating structure with the bottle body through the second rotating rod, and the driving gear is meshed with the driven gear.
[0010] Preferably, the discharge plate is movably connected to the bottle body, and the bottle body is movably connected to the first rotating rod.
[0011] Preferably, the first, second, third, fourth, and fifth discharge ports are all circular in shape, and the inner radii of the first, second, third, fourth, and fifth discharge ports are all different.
[0012] Compared with the prior art, the beneficial effects of this utility model are:
[0013] 1. This utility model, through the setting of a first protective shell, a second protective shell, a bolt group, a rotating shaft and a sealing strip, can effectively protect the bottle when it is impacted or dropped, thus improving its durability. By unlocking the bolt group, the second protective shell can be opened, the bottle can be removed, and the first and second protective shells can be cleaned and replaced. At the same time, the sealing strip can block water and impurities that seep in from the gap between the first and second protective shells.
[0014] 2. This utility model, through the arrangement of a first rotating rod, a driven gear, a driving gear, a second rotating rod, a rotating compass, a discharge plate, a first discharge port, a second discharge port, a third discharge port, a fourth discharge port, a fifth discharge port, and a discharge plate, controls the discharge size by rotating the rotating compass, which moves the opening on the discharge plate above the first, second, third, fourth, or fifth discharge port on the discharge plate. This allows experimental personnel to better control the discharge amount and speed of crystals during the dispensing process, making the operation more relaxed, reducing the risk of crystal spillage or other accidents due to improper operation, and improving the safety and controllability of experimental operations. Attached Figure Description
[0015] Figure 1 This is a perspective view of the present utility model;
[0016] Figure 2 This is a structural schematic diagram of the second protective shell fixing method of this utility model;
[0017] Figure 3 This is a schematic diagram of the internal components of the bottle body of this utility model;
[0018] Figure 4 This utility model Figure 3 Enlarged structural diagram at point A in the middle.
[0019] In the diagram: 1. Bottle body; 2. First protective shell; 3. Second protective shell; 4. Bolt assembly; 5. Rotating shaft; 6. Sealing strip; 7. Cap; 8. First rotating rod; 9. Driven gear; 10. Driving gear; 11. Second rotating rod; 12. Rotating compass; 13. Discharge plate; 14. First discharge port; 15. Second discharge port; 16. Third discharge port; 17. Fourth discharge port; 18. Fifth discharge port; 19. Discharge plate. Detailed Implementation
[0020] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain the present invention, and should not be construed as limiting the present invention.
[0021] The embodiments of this utility model will be described below based on its overall structure.
[0022] Please see Figures 1-4 A palladium chloride crystal dispensing bottle includes a bottle body 1, a first protective shell 2 installed on the outer wall of the bottle body 1, a second protective shell 3 installed on the outer wall of the bottle body 1, a bolt assembly 4 installed on the inner wall of the second protective shell 3, a rotating shaft 5 installed on the outer wall of the first protective shell 2, a sealing strip 6 installed on the inner wall of the first protective shell 2, and a cap 7 installed on the top of the bottle body 1. The second protective shell 3 forms a rotating structure with the first protective shell 2 via the rotating shaft 5, and the first protective shell 2 and the second protective shell 3 are threaded together. The outer walls of both the first protective shell 2 and the second protective shell 3 are slotted, and both the first protective shell 2 and the second protective shell 3 are inserted into the sealing strip 6. When using the device, the first protective shell 2 and the second protective shell 3 can effectively protect the bottle 1. When the bottle 1 is impacted or dropped, the risk of the bottle 1 breaking or being damaged by external forces such as collisions and drops is reduced. Especially for dispensing bottles made of fragile materials such as glass, it can effectively improve their durability. Then, by unlocking the bolt group 4 and rotating the shaft 5, the second protective shell 3 can be opened, the bottle 1 can be taken out, and the first protective shell 2 and the second protective shell 3 can be cleaned and replaced. At the same time, the sealing strip 6 can prevent water and impurities from seeping in from the gap between the first protective shell 2 and the second protective shell 3.
[0023] Please see Figures 1-4A palladium chloride crystal dispensing bottle has a first rotating rod 8 installed on the inner wall of the bottle body 1, a driven gear 9 installed on the outer wall of the first rotating rod 8, a driving gear 10 installed on the outer wall of the driven gear 9, a second rotating rod 11 installed on the outer wall of the driving gear 10, a rotating compass 12 installed on the outer wall of the second rotating rod 11, a dispensing plate 13 installed on the outer wall of the bottle body 1, a first dispensing port 14 and a second dispensing port 15 on the outer wall of the dispensing plate 13. The outer wall of the discharge plate 13 has a third discharge port 16, the outer wall of the discharge plate 13 has a fourth discharge port 17, the outer wall of the discharge plate 13 has a fifth discharge port 18, the top of the first rotating rod 8 is equipped with a discharge plate 19, the driving gear 10 forms a rotating structure with the bottle body 1 through the second rotating rod 11, and the driving gear 10 is meshed with the driven gear 9, the discharge plate 19 is movably connected to the bottle body 1, and the bottle body 1 is movably connected to the first rotating rod 8, the first discharge port 14, the second discharge port 15. The third discharge port 16, the fourth discharge port 17, and the fifth discharge port 18 are all circular in shape, and the inner diameter radii of the first discharge port 14, the second discharge port 15, the third discharge port 16, the fourth discharge port 17, and the fifth discharge port 18 are all different. When using the device, by rotating the rotating compass 12, the second rotating rod 11 is rotated, causing the driving gear 10 to rotate. Under the meshing drive, the driven gear 9 is rotated, which in turn drives the second rotating rod 11 to rotate, causing the discharge plate 19 to rotate. This moves the opening on the discharge plate 19 to above the first discharge port 14, the second discharge port 15, the third discharge port 16, the fourth discharge port 17, or the fifth discharge port 18 on the discharge plate 13, thereby controlling the discharge size. This allows the experimenter to better control the discharge amount and speed of the crystals during the dispensing process, making the operation more relaxed, reducing the risk of crystal spillage or other accidents due to improper operation, and improving the safety and controllability of the experimental operation.
[0024] Working principle: In use, first move the device to a suitable position, then place the bottle 1 into the first protective shell 2, then place the sealing strip 6 into the groove of the first protective shell 2, and then use the rotating shaft 5 to rotate the second protective shell 3 to cover and close the bottle 1. Then use the bolt group 4 to fix the second protective shell 3 to the first protective shell 2. When it is necessary to control the size of the discharge port, simply rotate the rotating compass 12 to make the second rotating rod 11 drive the driving gear 10 to rotate, which in turn drives the driven gear 9 and the second rotating rod 11 to rotate, and drives the opening on the discharge plate 19 to rotate on the discharge plate 13. According to the requirements, rotate the opening on the discharge plate 19 sequentially to the top of the first discharge port 14, the second discharge port 15, the third discharge port 16, the fourth discharge port 17 or the fifth discharge port 18 to adjust to the appropriate outlet size. This completes the use of the device. The contents not described in detail in this specification are existing technologies known to those skilled in the art.
[0025] Although the present invention 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 invention should be included within the protection scope of the present invention.
Claims
1. A dispensing bottle for palladium chloride crystals, comprising a bottle body (1), characterized in that: The outer wall of the bottle body (1) is equipped with a first protective shell (2), the outer wall of the bottle body (1) is equipped with a second protective shell (3), the inner wall of the second protective shell (3) is equipped with a bolt group (4), the outer wall of the first protective shell (2) is equipped with a rotating shaft (5), the inner wall of the first protective shell (2) is equipped with a sealing strip (6), and the top of the bottle body (1) is equipped with a cap (7). The inner wall of the bottle body (1) is equipped with a first rotating rod (8), the outer wall of the first rotating rod (8) is equipped with a driven gear (9), the outer wall of the driven gear (9) is equipped with a driving gear (10), the outer wall of the driving gear (10) is equipped with a second rotating rod (11), the outer wall of the second rotating rod (11) is equipped with a rotating compass (12), the outer wall of the bottle body (1) is equipped with a discharge plate (13), the outer wall of the discharge plate (13) is provided with a first discharge port (14), the outer wall of the discharge plate (13) is provided with a second discharge port (15), the outer wall of the discharge plate (13) is provided with a third discharge port (16), the outer wall of the discharge plate (13) is provided with a fourth discharge port (17), the outer wall of the discharge plate (13) is provided with a fifth discharge port (18), and the top of the first rotating rod (8) is equipped with a discharge plate (19).
2. The palladium chloride crystal dispensing bottle according to claim 1, characterized in that: The second protective shell (3) forms a rotating structure with the first protective shell (2) through a rotating shaft (5), and the first protective shell (2) and the second protective shell (3) are threadedly connected.
3. The palladium chloride crystal dispensing bottle according to claim 1, characterized in that: The outer walls of the first protective shell (2) and the second protective shell (3) are both slotted, and the first protective shell (2) and the second protective shell (3) are both inserted into the sealing strip (6).
4. The palladium chloride crystal dispensing bottle according to claim 1, characterized in that: The driving gear (10) forms a rotating structure with the bottle body (1) through the second rotating rod (11), and the driving gear (10) meshes with the driven gear (9).
5. A palladium chloride crystal dispensing bottle according to claim 1, characterized in that: The discharge plate (19) is movably connected to the bottle body (1), and the bottle body (1) is movably connected to the first rotating rod (8).
6. A palladium chloride crystal dispensing bottle according to claim 1, characterized in that: The first discharge port (14), the second discharge port (15), the third discharge port (16), the fourth discharge port (17) and the fifth discharge port (18) are all circular in shape, and the inner diameter radii of the first discharge port (14), the second discharge port (15), the third discharge port (16), the fourth discharge port (17) and the fifth discharge port (18) are all different.