Chemical additive collecting device based on rapid discharge
By combining a vibratory flow guide and discharge module with a spiral flow guide, the problem of slow discharge speed in chemical additive collection devices is solved, achieving rapid discharge and anti-clogging, making it suitable for efficient collection of chemical additives.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-07-10
- Publication Date
- 2026-07-07
Smart Images

Figure CN224467055U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of chemical additive collection technology, and in particular to a chemical additive collection device based on rapid discharge. Background Technology
[0002] Chemical reagents are relative standard substances used in chemical research and component analysis. They are widely used in the synthesis, separation, qualitative and quantitative analysis of substances. In medicine, excipients are defined as excipients and additives used in the production of pharmaceuticals and the preparation of prescriptions.
[0003] Current chemical additive collection devices cause chemical additives to form a fluid state inside the discharge hopper when discharging internal additives, resulting in a large amount of additives accumulating and clogging inside the discharge hopper, thus leading to a slow discharge rate. Utility Model Content
[0004] This utility model discloses a chemical additive collection device based on rapid discharge, which aims to solve the technical problem of slow discharge speed in existing chemical additive collection devices.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: a chemical additive collection device based on rapid discharge, comprising: two support frames and a collection box, the collection box being located between the two support frames, a discharge hopper being provided at the bottom of the collection box, and a discharge port being provided at the bottom of the discharge hopper; a fixed flipping module, movable inside the support frames, and the fixed flipping module being provided on both outer walls of the collection box; and a vibrating guide discharge module, partly located inside the collection box and partly located at the bottom of the collection box, with the part located inside the collection box located above the discharge port at the bottom of the discharge hopper.
[0006] In a preferred embodiment, the vibratory flow guide and discharge module includes: a movable shaft disposed inside the collection box, with two stirring blades fixedly connected to the outer wall of the movable shaft; and a servo motor fixed to the top of the collection box, with the drive end of the servo motor connected to one end of the movable shaft via a coupling.
[0007] In a preferred embodiment, the vibratory flow guiding and discharging module further includes: a connecting spring, one end of which is fixed inside the movable shaft, and the other end of the connecting spring is provided with a spiral guide, which is located above the discharge port at the bottom of the discharge hopper.
[0008] In a preferred embodiment, the vibrating guide discharge module further includes: multiple vibrating springs, one end of which is fixed to one side of the discharge hopper, and the other end of which is located at the bottom of the collection box. Two of the vibrating springs are provided with limit posts inside, and the top of the limit posts is fixedly connected to the top of the discharge hopper; two mounting plates are located at the bottom of the collection box, and an extension seat is fixedly connected to the top of the mounting plates.
[0009] In a preferred embodiment, the vibration-type flow guiding and discharge module further includes: two electric telescopic rods, both disposed on the top of the extension seat, with a fitting fixedly connected to the drive end of the electric telescopic rod, and the fitting fixedly connected to the inside of the limiting post.
[0010] In a preferred embodiment, the fixed flipping module includes: two hydraulic rods, each fixed to the top of the support frame, with a mounting base at the drive end of each hydraulic rod; and two fixing rings, each fixed to the outer wall of the collection box, with a rotating shaft inside each fixing ring.
[0011] In a preferred embodiment, the fixed flipping module further includes two flipping motors, each disposed inside the mounting base, with the drive end of the flipping motors connected to one end of the rotating shaft via a coupling.
[0012] As can be seen from the above, the chemical additive collection device based on rapid discharge provided by this utility model utilizes a vibrating guide discharge module to achieve the function of vibration and anti-blocking in the discharge hopper during the discharge process, and the spiral guide can apply impact force to the additives inside the discharge hopper. The two work together to prevent the chemical additives from forming a fluid state inside, thereby reducing the accumulation and blockage of a large amount of additives inside the discharge hopper and improving the discharge speed. Attached Figure Description
[0013] Figure 1 This is a schematic diagram of the overall structure of a chemical additive collection device based on rapid discharge proposed in this utility model;
[0014] Figure 2 A cross-sectional structural diagram of the movable shaft in the collection box and the vibrating guide discharge module of a chemical additive collection device based on rapid discharge proposed in this utility model.
[0015] Figure 3 This is a schematic diagram of the structure of a conventional chemical additives collection device with a slow discharge speed, which is proposed in this utility model as a chemical additives collection device based on rapid discharge.
[0016] Figure 4 This is a cross-sectional structural diagram of the support frame and the mounting base in the fixed flipping module of a chemical additive collection device based on rapid discharge proposed in this utility model.
[0017] In the attached diagram: 1. Support frame; 2. Fixed tilting module; 201. Hydraulic rod; 202. Mounting base; 203. Tilting motor; 204. Rotating shaft; 205. Fixing ring; 3. Collection box; 4. Vibrating guide and discharge module; 401. Servo motor; 402. Movable shaft; 403. Stirring blade; 404. Connecting spring; 405. Spiral guide component; 406. Limiting post; 407. Mounting plate; 408. Extension seat; 409. Electric telescopic rod; 410. Fitting component; 411. Vibrating spring; 5. Discharge hopper. Detailed Implementation
[0018] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.
[0019] The chemical additive collection device based on rapid discharge disclosed in this utility model is mainly applied to scenarios where the discharge speed of existing chemical additive collection devices is slow.
[0020] Reference Figures 1-4 A chemical additive collection device based on rapid discharge includes: two support frames 1 and a collection box 3, the collection box 3 being located between the two support frames 1, a discharge hopper 5 being provided at the bottom of the collection box 3, and a discharge port being provided at the bottom of the discharge hopper 5; a fixed flipping module 2, which is movable inside the support frame 1 and is provided on both outer walls of the collection box 3; and a vibrating guide discharge module 4, which is partially provided inside the collection box 3 and partially provided at the bottom of the collection box 3, with the part provided inside the collection box 3 located above the discharge port at the bottom of the discharge hopper 5.
[0021] The device utilizes the vibration-guided discharge module 4 to achieve the vibration and anti-blocking function of the discharge hopper 5 during the discharge process, and the spiral guide 405 can apply impact force to the additives inside the discharge hopper 5. The two work together to prevent the chemical additives from forming a fluid state inside, thereby reducing the accumulation and blockage of a large amount of additives inside the discharge hopper 5 and improving the discharge speed.
[0022] Reference Figure 1 , Figure 2 and Figure 3 In a preferred embodiment, the vibratory guide discharge module 4 includes: a movable shaft 402, which is disposed inside the collection box 3, and two stirring blades 403 are fixedly connected to the outer wall of the movable shaft 402; a servo motor 401, which is fixed to the top of the collection box 3, and the drive end of the servo motor 401 is connected to one end of the movable shaft 402 through a coupling.
[0023] In this scheme, the vibration-type guide discharge module 4 also includes: a connecting spring 404, one end of which is fixed inside the movable shaft 402, and the other end of the connecting spring 404 is provided with a spiral guide 405, which is located above the bottom discharge port of the discharge hopper 5.
[0024] In this scheme, the vibration-type guide and discharge module 4 also includes: multiple vibration springs 411, one end of which is fixed to one side of the discharge hopper 5, and the other end of each vibration spring 411 is located at the bottom of the collection box 3. Two vibration springs 411 are provided with limit posts 406 inside, and the top of the limit posts 406 is fixedly connected to the top of the discharge hopper 5; two mounting plates 407 are located at the bottom of the collection box 3, and the top of the mounting plates 407 is fixedly connected to the extension seat 408.
[0025] In this solution, the vibration-type guide and discharge module 4 also includes: two electric telescopic rods 409, both of which are set on the top of the extension seat 408. The driving end of the electric telescopic rod 409 is fixedly connected to a fitting 410, and the fitting 410 is fixedly connected to the inside of the limiting post 406.
[0026] Specifically, the stirring blade 403 prevents the accumulation of additives in the initial stage of discharge, ensuring their fluidity and smooth discharge; the spiral guide 405 moves up and down inside the discharge hopper 5 during the discharge process, ensuring the fluidity of the chemical additives inside the discharge hopper 5, preventing them from accumulating and clogging inside the discharge hopper 5, optimizing the distribution of additives inside, thereby improving the discharge speed of additives.
[0027] Reference Figure 1 and Figure 4 In a preferred embodiment, the fixed flipping module 2 includes: two hydraulic rods 201, which are respectively fixed to the top of the support frame 1, and each of the driving ends of the two hydraulic rods 201 is provided with a mounting base 202; two fixing rings 205, which are both fixed to the outer wall of the collection box 3, and each of the two fixing rings 205 is provided with a rotating shaft 204 inside.
[0028] In this solution, the fixed flip module 2 also includes two flip motors 203, which are respectively set inside the mounting base 202. The drive end of the flip motor 203 is connected to one end of the rotating shaft 204 through a coupling.
[0029] Specifically, the flipping motor 203 flips the collection box 3, making it easier to clean its interior, enabling the collection box 3 to be reused and suitable for holding different additives.
[0030] Working principle: When the chemical additive collection device discharges material, the servo motor 401 is activated. The servo motor 401 drives the movable shaft 402 and the stirring blades 403 on its outer wall to rotate, ensuring the fluidity of the additives. During the stirring process, the additives flow and contact the spiral guide 405, causing the connecting spring 404 to drive the spiral guide 405 to move up and down inside the discharge hopper 5, above its bottom discharge port. At the same time, the electric telescopic rod 409 is activated. The electric telescopic rod 409 drives the fitting part 410 and the limiting post 406 to overcome the elasticity of the vibration spring 411 and compress downwards, causing the discharge hopper 5 to move down. When it is compressed to the predetermined position, the electric telescopic rod 409 stops working. When the electric telescopic rod 409 is in operation, it can quickly retract. Under the restoring force of the vibration spring 411, it drives the discharge hopper 5 and the limiting post 406 on it to vibrate, so as to avoid the accumulation and blockage of chemical additives inside. After the chemical additives inside the collection device are used up, in order to facilitate cleaning and realize the recycling of the collection box 3 and make it suitable for holding different additives, the hydraulic rod 201 is activated. The hydraulic rod 201 moves the collection box 3 to a suitable height through the mounting base 202. The tilting motor 203 is activated. The tilting motor 203 causes the rotating shaft 204 to drive the fixing ring 205 to rotate, thereby realizing the tilting of the collection box 3, which is convenient for cleaning the residual additives inside.
[0031] The above description is merely a preferred embodiment of this utility model, but the protection scope of this utility model is not limited thereto. The substitutions may be replacements of some structures, devices, or method steps, or they may be complete technical solutions. Equivalent substitutions or modifications made based on the technical solution and inventive concept of this utility model should all be covered within the protection scope of this utility model.
Claims
1. A chemical additive collection device based on rapid discharge, characterized in that, include: Two support frames (1) and a collection box (3), the collection box (3) is located between the two support frames (1), the bottom of the collection box (3) is provided with a discharge hopper (5), and the bottom of the discharge hopper (5) is provided with a discharge port; a fixed flipping module (2) is movable inside the support frame (1), and the fixed flipping module (2) is set on the outer walls of both sides of the collection box (3); a vibrating guide discharge module (4) is partially set inside the collection box (3), partially set at the bottom of the collection box (3), and the part set inside the collection box (3) is located above the discharge port at the bottom of the discharge hopper (5).
2. The chemical additive collection device based on rapid discharge according to claim 1, characterized in that, The vibratory guide discharge module (4) includes: a movable shaft (402) located inside the collection box (3), with two stirring blades (403) fixedly connected to the outer wall of the movable shaft (402); and a servo motor (401) fixed to the top of the collection box (3), with the drive end of the servo motor (401) connected to one end of the movable shaft (402) via a coupling.
3. The chemical additive collection device based on rapid discharge according to claim 2, characterized in that, The vibration-type guide discharge module (4) further includes: a connecting spring (404), one end of which is fixed inside the movable shaft (402), and the other end of the connecting spring (404) is provided with a spiral guide (405), which is located above the bottom discharge port of the discharge hopper (5).
4. The chemical additive collection device based on rapid discharge according to claim 1, characterized in that, The vibrating guide discharge module (4) further includes: multiple vibrating springs (411), one end of which is fixed to one side of the discharge hopper (5), and the other end of the multiple vibrating springs (411) is set at the bottom of the collection box (3). Among them, the interior of two vibrating springs (411) is provided with limit posts (406), and the top of the limit posts (406) is fixedly connected to the top of the discharge hopper (5); two mounting plates (407) are set at the bottom of the collection box (3), and the top of the mounting plates (407) is fixedly connected with an extension seat (408).
5. A chemical additive collection device based on rapid discharge according to claim 4, characterized in that, The vibration-type flow guide and discharge module (4) also includes: two electric telescopic rods (409), both of which are set on the top of the extension seat (408). The driving end of the electric telescopic rod (409) is fixedly connected to a fitting (410), and the fitting (410) is fixedly connected to the inside of the limiting post (406).
6. A chemical additive collection device based on rapid discharge according to claim 1, characterized in that, The fixed flipping module (2) includes: two hydraulic rods (201), which are fixed to the top of the support frame (1), and the driving ends of the two hydraulic rods (201) are provided with mounting seats (202); two fixing rings (205), which are fixed to the outer wall of the collection box (3), and the interior of the two fixing rings (205) is provided with a rotating shaft (204).
7. A chemical additive collection device based on rapid discharge according to claim 6, characterized in that, The fixed flip module (2) further includes two flip motors (203), which are respectively set inside the mounting base (202). The drive end of the flip motor (203) is connected to one end of the rotating shaft (204) through a coupling.