A medicine bottle cleaning rotary transmission track and cleaning device
By combining high-pressure airflow and rotating strip cleaning technology, the problem of residual water droplets inside medicine bottles has been solved, improving the cleaning effect and practicality of the medicine bottle cleaning device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN DECHENG ANIMAL HEALTH PROD
- Filing Date
- 2025-04-03
- Publication Date
- 2026-07-07
AI Technical Summary
The small opening of the medicine bottle causes the residual water droplets inside the bottle to flow slowly, which affects the quality of medicine filling.
It uses a combination of a high-pressure air pump and a high-pressure nozzle to impact the inside of the medicine bottle with high-speed airflow. Combined with the flipping action of the flipping strip, it thoroughly removes residual water droplets. The air is filtered through an activated carbon filter layer and a dust filter to prevent impurities from entering the equipment.
It effectively reduces residual moisture in medicine bottles, improves the quality of medicine filling, and enhances the practicality of the device.
Smart Images

Figure CN224463390U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cleaning device technology, specifically to a rotary conveyor track and cleaning device for cleaning medicine bottles. Background Technology
[0002] In the pharmaceutical industry, the quality of medicine bottle cleaning directly affects the quality and safety of medicines, placing extremely high demands on the performance of medicine bottle cleaning equipment. Traditional medicine bottle cleaning relies partly on manual operation, which is not only inefficient but also makes it difficult to guarantee the consistency and cleanliness of the cleaning. For example, when cleaning medicine bottles, due to their small inner diameter, manual cleaning is difficult to thoroughly remove impurities and may even damage the bottles due to improper operation, affecting production efficiency and product quality. Therefore, to improve cleaning efficiency, a rotary conveyor track and cleaning device for medicine bottles is needed.
[0003] Regarding the aforementioned technologies, the applicant proposes a rotary conveyor track and cleaning device for cleaning medicine bottles. In operation, the medicine bottles to be cleaned are first transported by a conveyor belt to a straight section track. The bottles move along the straight section track and smoothly enter the cleaning tank. At this time, an ultrasonic generator installed at the bottom of the cleaning tank begins to operate. The high-frequency vibration emitted by the ultrasonic generator causes a strong cavitation effect in the water within the cleaning tank, effectively impacting the surface of the medicine bottles and removing dirt from both the surface and interior, achieving efficient cleaning. During the continuous transport of the medicine bottles along the straight section track, they pass through a tilting strip area. The tilting strip precisely acts on the medicine bottles, causing them to tilt. This tilting operation accelerates the drainage of residual cleaning water inside the bottles under the influence of gravity. However, because the openings of medicine bottles are generally small, the flow rate of residual water inside the bottles is slow under gravity. Even after the tilting operation, water droplets may still remain inside the bottles, thus reducing the quality of subsequent medicine filling. Utility Model Content
[0004] The purpose of this invention is to provide a rotary conveyor track and cleaning device for cleaning medicine bottles, in order to solve the problem mentioned in the background art that, due to the generally small opening of medicine bottles, the water inside the bottle flows slowly under the action of gravity, resulting in residual water droplets inside the bottle, which reduces the filling quality of subsequent medicines.
[0005] To achieve the above objectives, this utility model provides the following technical solution: This utility model provides a rotary conveyor track for cleaning medicine bottles. The rotary conveyor track for cleaning medicine bottles is used to be installed on the main body of a cleaning tank and includes: a conveying mechanism, which is installed inside the main body of the cleaning tank. The conveying mechanism includes straight sections of track evenly distributed through both ends of the main body of the cleaning tank. A connecting frame is provided at one end of the bottom of the straight section of track, and a base plate is provided at the bottom end of the connecting frame. High-pressure nozzles are evenly distributed at the top of the base plate. An air supply pipe is provided through the bottom end of the base plate and is connected to the bottom end of each high-pressure nozzle. A high-pressure air pump is provided at the end of the air supply pipe away from the high-pressure nozzle, and the output end of the high-pressure air pump is connected to the air supply pipe.
[0006] By adopting the above technical solution, the high-pressure air pump sprays compressed high-pressure gas through a connected high-pressure nozzle. The high-speed airflow is precisely guided by the nozzle and directly enters the medicine bottle. Thanks to the powerful impact and carrying capacity of the airflow, residual water droplets inside the bottle are completely blown out, greatly reducing residual moisture. Furthermore, by incorporating an activated carbon filter layer, a dust filter, and an air intake, the activated carbon filter layer and dust filter effectively filter the air drawn in by the high-pressure air pump, minimizing the intake of external dust and impurities and improving the device's practicality.
[0007] Preferably, a discharge frame is provided at the end of the straight track away from the high-pressure nozzle, a tilting bar is provided at the end of the discharge frame away from the straight track, a connecting frame is provided at the end of the tilting bar away from the discharge frame, and a feeding frame is provided at the end of the connecting frame away from the tilting bar.
[0008] By adopting the above technical solution, the medicine bottle will pass through the flipping strip area during the continuous transmission along the straight section track. The flipping strip acts precisely on the medicine bottle to make it flip. With the help of this flipping operation, the residual cleaning water in the medicine bottle is discharged more quickly under the action of gravity.
[0009] Preferably, the input end of the high-pressure air pump is provided with an air inlet pipe.
[0010] By adopting the above technical solution, it is convenient to draw external air into the high-pressure air pump.
[0011] This utility model provides a cleaning device, including the rotary conveyor track for cleaning medicine bottles as described above. The cleaning device further includes a collection pool, which is disposed at both ends of the main body of the cleaning pool, and the bottom of the collection pool is connected to the interior of the main body of the cleaning pool.
[0012] By adopting the above technical solution, it is convenient to recycle the water overflowing from the main body of the cleaning pool.
[0013] Preferably, an accessory box is provided at the end of the collection pool near the gas pipeline, and inspection doors are hinged on both sides of the accessory box at the end away from the collection pool.
[0014] By adopting the above technical solution, it is convenient for staff to inspect and maintain the equipment inside the parts box.
[0015] Preferably, the accessory box has an air intake port at one end near the air intake pipe, and the air intake pipe is inserted into the air intake port.
[0016] By adopting the above technical solution, the inhaled air can be easily purified.
[0017] Preferably, an activated carbon filter layer is provided at the end of the air inlet near the air intake pipe, and a dust filter is provided at the end of the air inlet away from the air intake pipe.
[0018] By adopting the above technical solution, the activated carbon filter layer and dust filter can be used to filter the air drawn in by the high-pressure air pump, minimizing the intake of external dust and impurities into the equipment and improving the practicality of the device.
[0019] Preferably, an ultrasonic generator is provided on one side of the main body of the cleaning pool, and a transparent protective cover is provided on the top of the main body of the cleaning pool.
[0020] By adopting the above technical solution, the ultrasonic generator starts working. The high-frequency vibration emitted by the ultrasonic generator drives the water in the main body of the cleaning tank to generate a strong cavitation effect, which effectively impacts the surface of the medicine bottle and removes dirt from the surface and inside of the bottle.
[0021] Compared with the prior art, the beneficial effects of this utility model are:
[0022] The system comprises a conveyor mechanism, a straight track, a high-pressure air pump, and a cleaning tank. As the medicine bottle exits from the cleaning tank via the straight track, the high-pressure air pump activates, spraying compressed high-pressure gas through a connected high-pressure nozzle. The high-speed airflow is precisely guided by the nozzle and directly into the medicine bottle. Thanks to the powerful impact and carrying capacity of the airflow, residual water droplets inside the bottle are thoroughly blown out, significantly reducing residual moisture. Furthermore, an activated carbon filter layer, a dust filter, and an air intake are incorporated. The activated carbon filter and dust filter effectively filter the air drawn in by the high-pressure air pump, minimizing the intake of external dust and impurities and enhancing the system's practicality. Attached Figure Description
[0023] Figure 1 This is a schematic diagram of the overall three-dimensional structure of the present invention;
[0024] Figure 2This is a three-dimensional structural diagram of the accessory box of this utility model;
[0025] Figure 3 This utility model Figure 1 Enlarged structural diagram at point A in the middle;
[0026] Figure 4 This is a schematic diagram of the internal structure of the accessory box of this utility model;
[0027] Figure 5 This utility model Figure 4 Enlarged structural diagram at point B.
[0028] In the diagram: 1. Conveying mechanism; 101. Feeding frame; 102. Connecting frame; 103. Accessory box; 104. Straight track; 105. Discharge frame; 106. Tilting bar; 107. Air supply pipe; 108. Inspection door; 109. Connecting frame; 110. Base plate; 111. High-pressure nozzle; 112. High-pressure air pump; 113. Air inlet pipe; 114. Activated carbon filter layer; 115. Dust filter screen; 116. Air intake port; 2. Collection tank; 3. Ultrasonic generator; 4. Cleaning tank body; 5. Transparent protective cover. Detailed Implementation
[0029] 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.
[0030] Example 1
[0031] Please see Figures 1 to 5 This embodiment provides a technical solution: On one hand, this utility model provides a rotary conveyor track for cleaning medicine bottles. The rotary conveyor track for cleaning medicine bottles is used to be set on the main body 4 of the cleaning pool and includes: a conveying mechanism 1. The conveying mechanism 1 is set inside the main body 4 of the cleaning pool. The conveying mechanism 1 includes a straight section track 104 that is evenly arranged through both ends of the main body 4 of the cleaning pool, which can facilitate the conveying of medicine bottles. One end of the bottom of the straight section track 104 is fixedly connected to a connecting frame 109, which can provide load-bearing capacity. The bottom end of the connecting frame 109 is fixedly connected to a base plate 110.
[0032] High-pressure nozzles 111 are evenly distributed at the top of the base plate 110. The working principle of the high-pressure nozzles 111 is as follows: the gas entering the high-pressure nozzles 111 first passes through a gradually narrowing channel. This channel gradually reduces the cross-sectional area of the gas flow, and based on the principle of fluid continuity, initially increases the gas velocity, preparing for further acceleration. After the narrowing channel, the high-pressure nozzles 111 have a nozzle with a very small diameter. When high-pressure gas passes instantaneously through the narrow nozzle from the channel with a larger cross-sectional area, according to Bernoulli's principle, the pressure energy of the gas is converted into kinetic energy, resulting in a sharp increase in velocity. This allows the high-speed airflow to be injected into the interior of the medicine bottle. When selecting a nozzle, the appropriate model should be chosen according to actual needs. All the components required within the high-pressure nozzles 111 are existing technologies and will not be described in detail below.
[0033] A gas delivery pipe 107 is installed through the bottom end of the base plate 110 to facilitate gas delivery. The gas delivery pipe 107 is connected to the bottom end of the high-pressure nozzle 111. A high-pressure air pump 112 is fixedly connected to the end of the gas delivery pipe 107 away from the high-pressure nozzle 111. The working principle of the high-pressure air pump 112 is that the internal motor drives the pump shaft and blades to rotate at high speed. The blades and the pump body wall form a variable volume air chamber. At the air inlet, the volume of the air chamber increases, creating a negative pressure. Outside air enters the air chamber through the air inlet under the action of atmospheric pressure. As the blades continue to rotate, the volume of the air chamber decreases, the air is compressed, and the pressure increases. The high-pressure gas is delivered to the high-pressure nozzle 111 through the gas delivery pipe 107. To ensure stable gas output, the air pump is equipped with a pressure stabilizing device. In addition, the motor continuously supplies power to the air pump, and the control circuit adjusts the motor speed based on system pressure feedback to ensure that the air pump output pressure meets the requirements of the cleaning device. When selecting the appropriate model, the appropriate model should be selected according to the actual needs. All the components required in the high-pressure air pump 112 mentioned above are existing technologies and will not be described in detail below.
[0034] The output end of the high-pressure air pump 112 is connected to the air supply pipe 107, and the input end of the high-pressure air pump 112 is fixedly connected to the air inlet pipe 113, which can facilitate the intake of external air.
[0035] The overall effect of this embodiment is as follows: the high-pressure air pump 112 delivers compressed high-pressure gas through the air supply pipe 107 to the high-pressure nozzle 111, and then sprays it out through the high-pressure nozzle 111. The high-speed airflow is precisely guided by the high-pressure nozzle 111 and directly enters the medicine bottle. With the powerful impact and carrying capacity of the airflow, the residual water droplets inside the medicine bottle are completely blown out, greatly reducing the residual moisture inside the bottle.
[0036] Example 2
[0037] A discharge frame 105 is fixedly connected to the end of the straight section track 104 away from the high-pressure nozzle 111. A tilting bar 106 is fixedly connected to the end of the discharge frame 105 away from the straight section track 104. A connecting frame 102 is fixedly connected to the end of the tilting bar 106 away from the discharge frame 105. A feed frame 101 is fixedly connected to the end of the connecting frame 102 away from the tilting bar 106.
[0038] The effect achieved by the entire second embodiment is as follows: during the continuous transmission of the medicine bottle along the straight track 104, it will pass through the area of the flip bar 106. The flip bar 106 acts precisely on the medicine bottle, causing it to flip. With the help of this flipping operation, the residual cleaning water in the medicine bottle is discharged more quickly under the action of gravity.
[0039] Example 3
[0040] This embodiment also provides a cleaning device, including a rotary conveyor track for cleaning medicine bottles. The cleaning device also includes a collection pool 2, which is fixedly connected to both ends of the cleaning pool body 4. The bottom of the collection pool 2 is connected to the interior of the cleaning pool body 4, allowing for water recycling. A parts box 103 is fixedly connected to one end of the collection pool 2 near the gas pipe 107, which can facilitate the protection of the internal equipment. Both sides of the parts box 103 away from the collection pool 2 are hinged with inspection doors 108, which facilitates the maintenance of the equipment inside the parts box 103 by the staff.
[0041] The accessory box 103 has an air intake 116 at one end near the air intake pipe 113. The air intake pipe 113 is inserted into the air intake 116. An activated carbon filter layer 114 is provided at the end of the air intake 116 near the air intake pipe 113. A dust filter 115 is fixedly connected to the end of the air intake 116 away from the air intake pipe 113.
[0042] An ultrasonic generator 3 is fixedly connected to one side of the main body 4 of the cleaning tank. The working principle of the ultrasonic generator 3 is to rectify and filter the power into DC through the internal power circuit, and then the oscillation circuit modulates the DC power at a frequency of 20kHz-1000kHz to generate a high-frequency alternating voltage signal to power the ultrasonic waves. The high-frequency electrical signal is transmitted to the piezoelectric transducer at the bottom of the main body 4 of the cleaning tank. The piezoelectric material undergoes periodic expansion and contraction deformation due to the alternating voltage, which drives the surrounding medium to vibrate mechanically, converting the electrical signal into ultrasonic mechanical vibration waves, which propagate in the cleaning fluid in the form of longitudinal waves. When the ultrasonic waves propagate in the liquid, they form a compression-sparse wave. During the negative pressure half-cycle, the distance between liquid molecules increases, forming bubble nuclei that gradually grow; during the positive pressure half-cycle, the bubble nuclei collapse, generating local high temperature and high pressure and micro-jet impact, peeling off the dirt from the medicine bottle and completing the cleaning. When selecting the appropriate model, the appropriate model should be selected according to the actual needs. The components required in the high-pressure air pump 112 are all existing technologies and will not be described in detail below. A transparent protective cover 5 is installed at the top of the main body 4 of the cleaning tank.
[0043] The effect achieved by the entire embodiment 3 is that by utilizing the activated carbon filter layer 114 and the dust filter 115, the air drawn in by the high-pressure air pump 112 can be filtered, minimizing the intake of external dust and impurities into the equipment, thus improving the practicality of the device.
[0044] Working principle: First, the power is turned on. The medicine bottle to be cleaned is first conveyed to the straight track 104 by the external conveyor belt. The medicine bottle moves forward along the straight track 104 and smoothly enters the main body of the cleaning tank 4. At this time, the ultrasonic generator 3 starts to work. The high-frequency vibration emitted by the ultrasonic generator 3 drives the water in the main body of the cleaning tank 4 to generate a strong cavitation effect, which effectively impacts the surface of the medicine bottle and removes dirt from the surface and inside of the bottle, achieving efficient cleaning. As the medicine bottle continues to be conveyed along the straight track 104, it will pass through the area of the flipping bar 106. The flipping bar 106 acts precisely on the medicine bottle, causing it to flip. With the help of this flipping operation, the residual cleaning water in the medicine bottle is accelerated to be discharged under the action of gravity.
[0045] Secondly, the medicine bottle enters the straight track 104 via the flip bar 106. When the medicine bottle is output from the collection pool 2 via the straight track 104, the high-pressure air pump 112 starts working. The high-pressure air pump 112 delivers compressed high-pressure gas to the high-pressure nozzle 111 through the air supply pipe 107, and then sprays it out through the high-pressure nozzle 111. The high-speed airflow is precisely guided by the high-pressure nozzle 111 and directly rushes into the inside of the medicine bottle. With the powerful impact and carrying force of the airflow, the water droplets remaining inside the medicine bottle are completely blown out, greatly reducing the residual moisture inside the bottle.
[0046] Finally, when the high-pressure air pump 112 is working, it can draw in external air through the air intake 116. By utilizing the activated carbon filter layer 114 and the dust filter 115, the air drawn in by the high-pressure air pump 112 can be filtered, minimizing the intake of external dust and impurities into the equipment, thus improving the practicality of the device.
[0047] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installed," "equipped with," "connected," etc., should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. For those skilled in the art, the specific meaning of the above terms in this utility model can be understood according to the specific circumstances.
[0048] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A rotary conveyor track for cleaning medicine bottles, characterized in that: The aforementioned rotary conveyor track for cleaning medicine bottles is installed on the main body of the cleaning tank and includes: The conveying mechanism is located inside the main body of the cleaning pool. The conveying mechanism includes straight rails that are evenly distributed through both ends of the main body of the cleaning pool. A connecting frame is provided at one end of the bottom of the straight rails. A base plate is provided at the bottom of the connecting frame. High-pressure nozzles are evenly distributed at the top of the base plate. An air supply pipe is provided through the bottom of the base plate. The air supply pipe is connected to the bottom of the high-pressure nozzles. A high-pressure air pump is provided at the end of the air supply pipe away from the high-pressure nozzles. The output end of the high-pressure air pump is connected to the air supply pipe.
2. The rotary conveyor track for cleaning medicine bottles according to claim 1, characterized in that: A discharge frame is provided at the end of the straight track away from the high-pressure nozzle. A tilting bar is provided at the end of the discharge frame away from the straight track. A connecting frame is provided at the end of the tilting bar away from the discharge frame. A feeding frame is provided at the end of the connecting frame away from the tilting bar.
3. The rotary conveyor track for cleaning medicine bottles according to claim 1, characterized in that: The high-pressure air pump is equipped with an air inlet pipe at its input end.
4. A cleaning device, characterized in that: The rotary conveyor track for cleaning medicine bottles, as described in any one of claims 1-3, further includes: A collection pool is provided at both ends of the main body of the cleaning pool, and the bottom of the collection pool is connected to the interior of the main body of the cleaning pool.
5. A cleaning device according to claim 4, characterized in that: A parts box is provided at the end of the collection pool near the gas pipeline, and inspection doors are hinged on both sides of the parts box away from the collection pool.
6. A cleaning device according to claim 5, characterized in that: The accessory box has an air intake port at one end near the air intake pipe, and the air intake pipe is inserted into the air intake port.
7. A cleaning device according to claim 6, characterized in that: An activated carbon filter layer is provided at the end of the air inlet near the air intake pipe, and a dust filter is provided at the end of the air inlet away from the air intake pipe.
8. A cleaning device according to claim 4, characterized in that: An ultrasonic generator is installed on one side of the main body of the cleaning pool, and a transparent protective cover is installed on the top of the main body of the cleaning pool.