Oral liquid processing sterilization device

By combining high-temperature steam and ultraviolet lamps inverted on the aeration tube, the problems of incomplete sterilization of the inner wall of oral liquid bottles and improper placement in existing technologies are solved, achieving efficient and comprehensive sterilization.

CN224474573UActive Publication Date: 2026-07-10JIANGSU JURONG PHARM GRP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU JURONG PHARM GRP CO LTD
Filing Date
2025-05-30
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing sterilization equipment is insufficient for effectively sterilizing the inner walls of oral liquid bottles, and the bottles are difficult to place conveniently and neatly during the sterilization process, affecting the efficiency and comprehensiveness of sterilization.

Method used

An oral liquid processing and sterilization device was designed. It adopts an upside-down method on the aeration tube and uses high-temperature steam and ultraviolet lamps to simultaneously sterilize the inner and outer walls of the oral liquid bottle. The oral liquid bottle can be conveniently and neatly placed by the cooperation of the storage plate and the moving plate.

Benefits of technology

It achieves precise and efficient sterilization of the inner and outer walls of oral liquid bottles, improving the efficiency and comprehensiveness of sterilization, and avoiding the problem of incomplete sterilization caused by the accumulation and unevenness of bottles.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224474573U_ABST
    Figure CN224474573U_ABST
Patent Text Reader

Abstract

The utility model belongs to oral liquid processing technical field, specifically is a kind of oral liquid processing sterilization device, including box, the box inside is sterilization room, the cavity is established in the box side wall inside, multiple fixed rings are fixedly installed on the inner wall of sterilization room, the fixed ring is assembled with gas duct, multiple aeration pipes are installed on the gas duct, multiple diaphragms are installed on the aeration pipe, multiple ultraviolet lamp tubes are installed on the sterilization room top plate, by oral liquid bottle is inverted and is placed on aeration pipe, the tiny self-closing hole on aeration pipe is automatically opened under the pressure of high-temperature steam, high-temperature steam is sprayed from aeration pipe, and accurately sprayed on the inner wall of oral liquid bottle, this structure can be accurate and efficient sterilization to the inner wall of oral liquid bottle, while ultraviolet lamp tube irradiates oral liquid bottle outer wall, the high-temperature sterilization of oral liquid bottle outer wall, this structure can be high-temperature sterilization to the inner wall and outer wall of oral liquid bottle, it is beneficial to improve the high efficiency of device sterilization.
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Description

Technical Field

[0001] This utility model relates to the field of oral liquid processing technology, specifically an oral liquid processing sterilization device. Background Technology

[0002] Oral liquid is a dosage form in which drugs or nutrients are dissolved and suspended in a liquid. It has the characteristics of rapid absorption, convenient administration, and accurate dosage. In the process of processing oral liquid, it is necessary to fill the oral liquid. Before filling, the oral liquid bottles need to be cleaned by a bottle washing machine and then sent to a sterilization device for high-temperature sterilization.

[0003] A Chinese patent with authorization announcement number CN 209290851 U discloses a sterilization and disinfection device for oral liquid production, including a box, a disinfection lamp, and a fan. A drawer is installed at the bottom of the front surface of the box. The disinfection lamp is installed at the top inside the box. The fan is installed at both ends of the box. A second support plate is installed above a first support plate, and the left ends of the first and second support plates are connected by hinges. The right ends of the first and second support plates are connected by pins. Fixed plates are evenly distributed at the ends of the crossbars, and the outer ends of the fixed plates have limiting holes with connecting rods installed inside the limiting holes. A fixing block is installed on the rear side of the crossbar. Rollers are installed at both ends of the bottom of the box. This sterilization and disinfection device for oral liquid production not only facilitates the rapid draining of water from the bottling bottles but also ensures uniform heating of the bottling bottles, improving the sterilization effect.

[0004] Existing sterilization devices typically use a single sterilization method when sterilizing oral liquid bottles, and it is difficult to efficiently sterilize the inner wall of the oral liquid bottle, resulting in poor sterilization efficiency. Therefore, an oral liquid processing sterilization device is proposed to address the above problems. Utility Model Content

[0005] In order to overcome the shortcomings of the existing technology and solve the problems existing in the existing technology, this utility model proposes an oral liquid processing sterilization device.

[0006] The technical solution adopted by this utility model to solve its technical problem is an oral liquid processing sterilization device, including a box body with two doors installed on the box body. One door has a control panel installed on it. An air inlet pipe is installed on the side wall of the box body, and a solenoid valve is installed on the air inlet pipe. The interior of the box body is a sterilization chamber. A cavity is formed inside the side wall of the box body, and the air inlet pipe extends into the cavity. Multiple fixing rings are fixedly installed on the inner wall of the sterilization chamber, and air guide pipes are assembled inside the fixing rings. Multiple round holes are formed on the side wall of the cavity. One end of the air guide pipe passes through the round hole and extends into the cavity. Multiple aeration pipes are installed on the air guide pipes, and multiple aeration pipes are installed on the aeration pipes. Each membrane is made of rubber and has tiny self-closing pores. Multiple ultraviolet lamps are installed on the top plate of the sterilization chamber. These lamps are connected to a control panel via internal circuitry. By inverting the oral liquid bottle onto the aeration tube, the tiny self-closing pores on the aeration tube automatically open under the pressure of high-temperature steam. The high-temperature steam is then ejected from the aeration tube and accurately sprayed onto the inner wall of the oral liquid bottle. This structure allows for precise and efficient sterilization of the inner wall of the oral liquid bottle. Simultaneously, the ultraviolet lamps irradiate the outer wall of the oral liquid bottle, sterilizing it at high temperatures. This structure allows for simultaneous high-temperature sterilization of both the inner and outer walls of the oral liquid bottle, improving the overall sterilization efficiency of the device.

[0007] Preferably, a storage plate is placed on the bottom plate of the box, and multiple placement slots are opened on the storage plate. Four slots are opened in the fixing ring, and the included angle between two adjacent slots is °. Two plate slots are symmetrically opened on the outer wall of the air guide pipe, and a movable plate is installed in the plate slot. Multiple springs are installed between the movable plate and the inner wall of the plate slot. A locking block is installed on the outer wall of the movable plate. An exhaust pipe is installed on the side wall of the box, and an exhaust valve is installed on the exhaust pipe. The exhaust valve and the solenoid valve are connected to the control panel through an internal circuit. By quickly placing multiple oral liquid bottles in the placement slots of the storage plate, with the aeration pipe in a horizontal state, aligning the multiple oral liquid bottles on the storage plate with the aeration pipe, and placing the oral liquid bottles on the aeration pipe, the direction of the air guide pipe is reversed so that the aeration pipe on it returns to a vertical state. At this time, the oral liquid bottles are upside down on the aeration pipe, realizing convenient and neat placement of multiple oral liquid bottles. This structure can avoid the stacking of oral liquid bottles, which is beneficial to improving the neatness of oral liquid bottles and improving the comprehensiveness of oral liquid bottle sterilization.

[0008] The advantages of this utility model are:

[0009] 1. This utility model involves inverting an oral liquid bottle onto an aeration tube. The tiny self-closing holes on the aeration tube automatically open under the pressure of high-temperature steam, allowing the high-temperature steam to spray out and accurately onto the inner wall of the oral liquid bottle. This structure enables precise and efficient sterilization of the inner wall of the oral liquid bottle. Simultaneously, an ultraviolet lamp irradiates the outer wall of the oral liquid bottle, sterilizing it at high temperature. This structure allows for simultaneous high-temperature sterilization of both the inner and outer walls of the oral liquid bottle, thus improving the sterilization efficiency of the device.

[0010] 2. This utility model allows for the quick placement of multiple oral liquid bottles in the storage slot of a storage plate, with the aeration tube in a horizontal position. The bottles are aligned with the aeration tube on the storage plate, and then placed on the aeration tube. The direction of the air guide tube is then reversed to restore the aeration tube to a vertical position, at which point the oral liquid bottles are inverted on the aeration tube. This achieves convenient and neat placement of multiple oral liquid bottles. This structure avoids the accumulation of oral liquid bottles, improves their neatness, and enhances the comprehensiveness of sterilization. Attached Figure Description

[0011] 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 these drawings without creative effort.

[0012] Figure 1 This is a first-person perspective 3D structural diagram;

[0013] Figure 2 This is a schematic diagram of the three-dimensional structure of the cavity.

[0014] Figure 3 This is a schematic diagram of the three-dimensional structure of the aeration pipe;

[0015] Figure 4 This is a schematic diagram of the internal three-dimensional structure of the sterilization chamber;

[0016] Figure 5 This is a schematic diagram of the internal three-dimensional structure of the air duct.

[0017] In the diagram: 1. Chamber; 2. Chamber door; 3. Control panel; 4. Air inlet pipe; 5. Solenoid valve; 6. Exhaust pipe; 7. Exhaust valve; 8. Sterilization chamber; 9. Cavity; 10. Fixing ring; 11. Air duct; 12. Aeration pipe; 13. Membrane; 14. Micro self-closing orifice; 15. Ultraviolet lamp; 16. Storage plate; 17. Placement slot; 18. Card slot; 19. Plate slot; 20. Moving plate; 21. Spring; 22. Locking block. 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. 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.

[0019] Please see Figure 1-3 As shown, an oral liquid processing sterilization device includes a housing 1 with two doors 2 installed on it. One door 2 has a control panel 3 installed on it. An air inlet pipe 4 is installed on the side wall of the housing 1, and a solenoid valve 5 is installed on the air inlet pipe 4. The interior of the housing 1 is a sterilization chamber 8. A cavity 9 is formed inside the side wall of the housing 1, and the air inlet pipe 4 extends into the cavity 9. Multiple fixing rings 10 are fixedly installed on the inner wall of the sterilization chamber 8, and air guide pipes 11 are fitted inside the fixing rings 10. Multiple... A circular hole is formed, and one end of the air guide tube 11 passes through the circular hole and extends into the cavity 9. Multiple aeration tubes 12 are installed on the air guide tube 11, and multiple membranes 13 are installed on the aeration tubes 12. The membranes 13 are made of rubber and have tiny self-closing holes 14 inside. Multiple ultraviolet lamps 15 are installed on the top plate of the sterilization chamber 8, and the ultraviolet lamps 15 are connected to the control panel 3 through an internal circuit. During operation, existing sterilization devices typically use one method to sterilize oral liquid bottles. Sterilization is difficult, and it is hard to effectively sterilize the inner wall of the oral liquid bottle, resulting in poor sterilization efficiency of the device. By inverting the oral liquid bottle onto the aeration tube 12, with the bottle opening facing downwards and the tiny self-closing orifice 14 on the aeration tube 12 facing the inner wall of the oral liquid bottle, high-temperature steam is introduced into the air inlet tube 4. The high-temperature steam enters the cavity 9 and then enters the aeration tube 12 through the air guide tube 11. The tiny self-closing orifice 14 on the aeration tube 12 then automatically opens under the pressure of the high-temperature steam. Steam is ejected from the aeration pipe 12 and accurately sprayed onto the inner wall of the oral liquid bottle. If the high-temperature steam disappears, the tiny self-closing hole 14 on the aeration pipe 12 will automatically close to prevent water from flowing back into the aeration pipe 12. This structure can accurately and efficiently sterilize the inner wall of the oral liquid bottle. At the same time, the ultraviolet lamp 15 irradiates the outer wall of the oral liquid bottle to sterilize it at high temperature. This structure can sterilize both the inner and outer walls of the oral liquid bottle at high temperature at the same time, which helps to improve the sterilization efficiency of the device.

[0020] Please see Figure 4-5As shown, a storage plate 16 is placed on the bottom plate of the box 1. Multiple placement slots 17 are provided on the storage plate 16. Four slots 18 are provided inside the fixing ring 10, with an included angle of 90° between adjacent slots 18. Two symmetrical slots 19 are provided on the outer wall of the air duct 11. A movable plate 20 is installed inside the slot 19. Multiple springs 21 are installed between the movable plate 20 and the inner wall of the slot 19. A locking block 22 is installed on the outer wall of the movable plate 20. An exhaust pipe 6 is installed on the side wall of the box 1, and an exhaust valve 7 is installed on the exhaust pipe 6. The exhaust valve 7 and... Solenoid valve 5 is connected to control panel 3 via internal circuitry. During operation, existing sterilization devices typically stack oral liquid bottles, making convenient and orderly placement difficult and resulting in poor bottle neatness, thus affecting the overall sterilization process. By quickly placing multiple oral liquid bottles into the placement slot 17 of storage plate 16, and then pressing the two movable plates 20 on the air duct 11, the two movable plates 20 move synchronously relative to each other. The two movable plates 20 interact with two rows of springs 2... 1. Compression is performed, and the two moving plates 20 drive the two locking blocks 22 on them to move out of the two horizontal locking slots 18. Then, the air guide pipe 11 is rotated, which drives the multiple aeration pipes 12 on it to rotate, so that the aeration pipes 12 are in a horizontal state. Then, the two moving plates 20 are released, and under the pushing force of the two rows of springs 21, the two locking blocks 22 are locked into the two vertical locking slots 18. At this time, the air guide pipe 11 is in a fixed state, and the horizontally placed aeration pipes 12 are in a fixed state. Then, the multiple oral liquid bottles on the storage plate 16 are connected to the aeration pipes 12. Align the air tubes 12, place the oral liquid bottle on the aeration tube 12, and then rotate the air guide tube 11 in the opposite direction to restore the aeration tube 12 to a vertical position. At this time, the oral liquid bottle is upside down on the aeration tube 12, which realizes the convenient and neat placement of multiple oral liquid bottles. Repeat the above steps to place oral liquid bottles on all the aeration tubes 12. This structure can avoid the stacking of oral liquid bottles and can conveniently and neatly place the oral liquid bottles, which is conducive to improving the neatness of the oral liquid bottles and improving the comprehensiveness of the sterilization of oral liquid bottles.

[0021] Working principle: Existing sterilization devices typically use a single method to sterilize oral liquid bottles, which is insufficient for effectively sterilizing the inner wall of the bottle, resulting in poor sterilization efficiency. By inverting the oral liquid bottle onto the aeration tube 12 with the bottle opening facing downwards and the tiny self-closing orifice 14 on the aeration tube 12 facing the inner wall of the bottle, high-temperature steam is introduced into the air inlet tube 4. The high-temperature steam enters the cavity 9 and then flows into the aeration tube 12 through the air guide tube 11. Under the pressure of the high-temperature steam, the tiny self-closing orifice 14 on the aeration tube 12 automatically opens, and the high-temperature steam is ejected from the aeration tube 12, accurately spraying onto the bottle opening. On the inner wall of the oral liquid bottle, once the high-temperature steam disappears, the tiny self-closing holes 14 on the aeration tube 12 will automatically close, preventing water from flowing back into the aeration tube 12. This structure allows for precise and efficient sterilization of the inner wall of the oral liquid bottle. Simultaneously, the ultraviolet lamp 15 irradiates the outer wall of the oral liquid bottle, sterilizing it at high temperature. This structure allows for simultaneous high-temperature sterilization of both the inner and outer walls of the oral liquid bottle, improving the efficiency of the sterilization process. In existing sterilization devices, oral liquid bottles are typically stacked during sterilization. Due to the difficulty in convenient and neat placement of the bottles, their neatness is poor, affecting the sterilization process. To ensure comprehensiveness, multiple oral liquid bottles are quickly placed into the placement slots 17 of the storage plate 16. Then, the two movable plates 20 on the air guide tube 11 are pressed, causing them to move synchronously relative to each other. The two movable plates 20 compress the two rows of springs 21, and the two movable plates 20 drive the two locking blocks 22 on them to move out of the two horizontal locking slots 18. Then, the air guide tube 11 is rotated, causing the multiple aeration tubes 12 on it to rotate, making the aeration tubes 12 horizontal. Then, the two movable plates 20 are released, and under the pushing force of the two rows of springs 21, the two locking blocks 22 engage with the two vertical locking slots 18. At this point, the air guide tube 11... In a fixed state, the horizontally placed aeration tube 12 is in a fixed state. Then, the multiple oral liquid bottles on the storage plate 16 are aligned with the aeration tube 12, and the oral liquid bottles are placed on the aeration tube 12. Then, the direction of the air guide tube 11 is reversed so that the aeration tube 12 on it is restored to a vertical state. At this time, the oral liquid bottles are upside down on the aeration tube 12, which realizes the convenient and neat placement of multiple oral liquid bottles. Repeat the above steps to place oral liquid bottles on all the aeration tubes 12. This structure can avoid the stacking of oral liquid bottles and can conveniently and neatly place the oral liquid bottles, which is conducive to improving the neatness of the oral liquid bottles and improving the comprehensiveness of the sterilization of oral liquid bottles.

[0022] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model.

Claims

1. An oral liquid processing and sterilization apparatus, characterized in that: The enclosure includes a housing (1) with two doors (2) installed on it. One of the doors (2) has a control panel (3) installed on it. An air inlet pipe (4) is installed on the side wall of the housing (1), and a solenoid valve (5) is installed on the air inlet pipe (4). The interior of the housing (1) is a sterilization chamber (8). A cavity (9) is opened inside the side wall of the housing (1), and the air inlet pipe (4) extends into the cavity (9). Multiple fixing rings (10) are fixedly installed on the inner wall of the sterilization chamber (8), and air guide tubes are assembled inside the fixing rings (10). (11) Multiple round holes are provided on the side wall of the cavity (9). One end of the air guide tube (11) passes through the round hole and extends into the cavity (9). Multiple aeration tubes (12) are installed on the air guide tube (11). Multiple membranes (13) are installed on the aeration tubes (12). The membranes (13) are made of rubber material. Small self-closing holes (14) are provided in the membranes (13). Multiple ultraviolet lamps (15) are installed on the top plate of the sterilization chamber (8). The ultraviolet lamps (15) are connected to the control panel (3) through the internal circuit.

2. The oral liquid processing and sterilization apparatus according to claim 1, characterized in that: A storage board (16) is placed on the bottom plate of the box (1), and multiple placement slots (17) are provided on the storage board (16).

3. The oral liquid processing and sterilization apparatus according to claim 1, characterized in that: The fixing ring (10) has four slots (18) inside, and the included angle between two adjacent slots (18) is 90°.

4. The oral liquid processing and sterilization apparatus according to claim 1, characterized in that: Two symmetrical slots (19) are opened on the outer wall of the air duct (11), and a movable plate (20) is installed in the slot (19).

5. The oral liquid processing and sterilization apparatus according to claim 4, characterized in that: Multiple springs (21) are installed between the movable plate (20) and the inner wall of the plate groove (19), and a locking block (22) is installed on the outer wall of the movable plate (20).

6. The oral liquid processing and sterilization apparatus according to claim 1, characterized in that: An exhaust pipe (6) is installed on the side wall of the housing (1), and an exhaust valve (7) is installed on the exhaust pipe (6). The exhaust valve (7) and the solenoid valve (5) are connected to the control panel (3) through an internal circuit.