A pharmaceutical material storage device
By using temperature sensors and electric dampers to regulate the drying airflow in pharmaceutical raw material storage devices, the problem of insufficient humidity control was solved, intelligent humidity management was achieved, and the quality of raw materials and the safety of pharmaceuticals were ensured.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DANDONG KANGFU PHARM CO LTD
- Filing Date
- 2025-07-23
- Publication Date
- 2026-07-07
AI Technical Summary
Existing pharmaceutical raw material storage devices have deficiencies in humidity control, making it difficult to effectively isolate external moisture, leading to raw material clumping and mold growth, and lacking intelligent monitoring and regulation functions.
A temperature sensor is used to detect humidity levels, and the control system adjusts the opening of the electric damper to regulate the drying airflow, thus achieving intelligent monitoring and regulation.
It effectively prevents pharmaceutical raw materials from clumping and becoming moldy due to changes in humidity, ensuring the quality of raw materials and improving the quality of drug production.
Smart Images

Figure CN224466410U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of pharmaceutical raw material storage devices, specifically a pharmaceutical raw material storage device. Background Technology
[0002] Pharmaceutical raw materials are the core foundation of drug production, and their quality directly determines the safety and efficacy of drugs. With the rapid development of the pharmaceutical industry, the types and quantities of pharmaceutical raw materials are constantly increasing. Different raw materials have significantly different requirements for storage environments, such as temperature, humidity, and light, all of which need to be strictly controlled. Therefore, developing specialized storage devices that are highly targeted and have stable performance has become a key link in ensuring the quality of pharmaceutical raw materials and guaranteeing the compliance of drug production.
[0003] Currently, while most pharmaceutical raw material storage devices on the market possess basic storage functions, they still have significant shortcomings in humidity control during long-term storage. Existing devices often fail to effectively isolate external moisture, leading to problems such as raw materials clumping, mold growth, or changes in chemical properties due to moisture absorption, severely impacting raw material quality and drug production quality. Furthermore, some storage devices lack intelligent monitoring and adjustment functions, failing to detect and respond to environmental changes in real time, further exacerbating the risk of raw material damage. Utility Model Content
[0004] To address the shortcomings of existing technologies, this utility model provides a storage device for pharmaceutical raw materials. Through a temperature sensor, the humidity value sensed in the drying chamber is sent to the control system. The control system then adjusts the opening of the electric damper on the first air inlet branch pipe corresponding to the drying chamber, thereby regulating the flow rate of the drying air according to different humidity levels, achieving intelligent monitoring and regulation functions.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a storage device for pharmaceutical raw materials, comprising:
[0006] The box body has multiple pairs of support plates arranged on its inner wall in the vertical direction;
[0007] Multiple boxes are provided, each of which is horizontally slidably mounted on each pair of support plates, and each of which has multiple ventilation holes at its bottom.
[0008] Multiple upper sealing plates are disposed on the inner wall of the box and located above multiple boxes;
[0009] Multiple lower sealing plates are disposed on the inner wall of the box and located below multiple boxes;
[0010] The drying assembly includes a dryer, an air inlet main pipe, an air outlet main pipe, multiple first air inlet branch pipes, and multiple first air outlet branch pipes. The dryer is located on the top of the housing. The air inlet main pipe is connected to the air outlet of the dryer, and the air outlet main pipe is connected to the air inlet of the dryer. Each first air inlet branch pipe passes through the side wall of the housing and the upper sealing plate, and one end is connected to the air inlet main pipe. Each first air outlet branch pipe passes through the side wall of the housing and the lower sealing plate, and one end is connected to the air outlet main pipe. Electric dampers are provided on both the first air inlet branch pipes and the first air outlet branch pipes. A humidity sensor is provided at the bottom of each upper sealing plate.
[0011] Preferably, each of the support plates has a slide rail on its upper surface, and the bottom of the box has a pair of slide bars, with each slide bar slidably disposed in each slide rail.
[0012] Preferably, a second air inlet branch pipe is connected to one end of each of the first air inlet branch pipes and located below the upper sealing plate, and multiple air outlets are opened at the bottom of each of the second air inlet branch pipes.
[0013] Preferably, a second air outlet branch pipe is connected to one end of each of the first air outlet branch pipes and above the lower sealing plate, and multiple air inlets are opened at the top of each of the second air outlet branch pipes.
[0014] Preferably, each of the first air inlet branch pipes is equipped with an air flow meter.
[0015] This utility model provides a storage device for pharmaceutical raw materials, which has the following beneficial effects:
[0016] This invention uses a temperature sensor to send the humidity value sensed in the drying chamber to the control system. The control system then adjusts the opening of the electric damper on the first air inlet branch pipe corresponding to the drying chamber, thereby regulating the flow rate of the drying air according to different humidity levels, achieving intelligent monitoring and regulation. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the internal structure of the present invention;
[0018] Figure 2 This is the front view of the present invention.
[0019] In the diagram: 1. Box body; 2. Support plate; 3. Slide rail; 4. Slide bar; 5. Box body; 6. Ventilation hole; 7. Upper sealing plate; 8. Lower sealing plate; 9. Main air inlet pipe; 10. First air inlet branch pipe; 11. Second air inlet branch pipe; 12. Main air outlet pipe; 13. First air outlet branch pipe; 14. Second air outlet branch pipe; 15. Dryer; 16. Electric damper; 17. Air flow meter; 18. Humidity sensor. Detailed Implementation
[0020] 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.
[0021] Please see Figure 1-2 This utility model provides a technical solution: a storage device for pharmaceutical raw materials, comprising:
[0022] Box 1, the inner wall of box 1 is provided with multiple pairs of support plates 2 in the vertical direction, and each pair of support plates 2 has the same vertical height;
[0023] Multiple boxes 5 are horizontally slidably mounted on each pair of support plates 2. Each box 5 has multiple ventilation holes 6 at its bottom and a handle on each box 5 so that people can pull the box 5 out of the box 1.
[0024] Multiple upper sealing plates 7 are disposed on the inner wall of the box 1 and located above multiple boxes 5;
[0025] Multiple lower sealing plates 8 are disposed on the inner wall of the housing 1 and located below multiple boxes 5;
[0026] Specifically, each upper sealing plate 7 and lower sealing plate 8 divides the interior of the box into independent drying chambers, so that each box 5 is set in a drying chamber alone, so as to facilitate temperature control in each drying chamber;
[0027] The drying assembly includes a dryer 15, an air inlet main pipe 9, an air outlet main pipe 12, multiple first air inlet branch pipes 10, and multiple first air outlet branch pipes 13. The dryer 15 is located on the top of the housing 1. The air inlet main pipe 9 is connected to the air outlet of the dryer 15, and the air outlet main pipe 12 is connected to the air inlet of the dryer 15. Each first air inlet branch pipe 10 passes through the side wall of the housing 1 and the upper sealing plate 7, and one end is connected to the air inlet main pipe 9. Each first air outlet branch pipe 13 passes through the side wall of the housing 1 and the lower sealing plate 8, and one end is connected to the air outlet main pipe 12. Electric dampers 16 are provided on the first air inlet branch pipes 10 and the first air outlet branch pipes 13. A humidity sensor 18 is provided at the bottom of each upper sealing plate 7.
[0028] Specifically, the dryer 15 provides hot air for drying, which is blown from the main air inlet pipe 9 into multiple first air inlet branch pipes 10, then into multiple drying chambers, and then out through multiple first air outlet branch pipes 13 and the main air outlet pipe 12 for circulation. A drying device can be installed on the main air inlet pipe 9 or the main air outlet pipe 12 to remove moisture from the drying air. The temperature sensor can send the humidity value it senses in the drying chamber to the control system. The control system then adjusts the opening of the electric damper 16 on the first air inlet branch pipe 10 corresponding to the drying chamber, thereby regulating the flow rate of the drying air according to different humidity levels, achieving the function of intelligent monitoring and regulation.
[0029] As an embodiment of this utility model, a slide rail 3 is provided on the upper surface of each support plate 2, and a pair of slide bars 4 are provided on the bottom of the box body 5. Each slide bar 4 is slidably disposed in each slide rail 3, and the slide rail 3 limits the slide bar 4 to prevent the slide bar 4 and the box body 5 from deviating during movement.
[0030] As an embodiment of the present invention, a second air inlet branch pipe 11 is connected to one end of each first air inlet branch pipe 10 and below the upper sealing plate 7. Multiple air outlets are opened at the bottom of each second air inlet branch pipe 11, and the multiple air outlets can make the drying air evenly distributed when it enters the drying chamber.
[0031] As an embodiment of the present invention, a second air outlet branch pipe 14 is connected to one end of each first air outlet branch pipe 13 and above the lower sealing plate 8. Multiple air inlets are opened at the top of each second air outlet branch pipe 14, and the multiple air inlets enable the air in the drying chamber to quickly enter into the first air outlet branch pipe and be extracted.
[0032] As an embodiment of the present invention, each first air inlet branch pipe 10 is provided with an air flow meter 17, which is used to detect the drying air flow in each drying chamber.
[0033] Those skilled in the art should connect all electrical components and their compatible power supplies in this case via wires, and should select appropriate controllers according to actual conditions to meet control requirements. The specific connection and control sequence should refer to the working principle described below, where the electrical connections between the various electrical components are completed in sequence. The detailed connection methods are well-known technologies in the field. The following mainly introduces the working principle and process, and will not describe the electrical control further.
[0034] The working principle and usage process of this utility model are as follows: During use, each box 5 is removed, and the pharmaceutical raw materials are placed in multiple boxes 5. The boxes 5 are then pushed into the housing 1. During drying, the dryer 15 is started. Each humidity sensor 18 senses the humidity in its respective drying chamber and transmits this humidity value to the control system. The control system then adjusts the opening of the corresponding electric damper 16. The dryer 15 blows drying air sequentially from the main air inlet pipe 9, the first air inlet branch pipe 10, and the second air inlet branch pipe 11 into each drying chamber. After drying the pharmaceutical raw materials in the boxes 5, the air flows from the ventilation holes 6 at the bottom of the boxes 5 into the second air outlet branch pipe 14, the first air outlet branch pipe 13, and the main air outlet pipe 12 before re-entering the drying chamber for circulation. This utility model uses a temperature sensor to send the humidity value sensed in its respective drying chamber to the control system. The control system then adjusts the opening of the electric damper 16 on the first air inlet branch pipe 10 corresponding to that drying chamber, thereby regulating the flow rate of the drying air according to different humidity levels, achieving intelligent monitoring and adjustment functions.
[0035] 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 storage device for pharmaceutical raw materials, characterized in that, include: Box (1), the inner wall of the box (1) is provided with multiple pairs of support plates (2) in the vertical direction; Multiple boxes (5), each of the boxes (5) is horizontally slidably disposed on each pair of support plates (2), and each of the boxes (5) has multiple ventilation holes (6) at its bottom; Multiple upper sealing plates (7) are disposed on the inner wall of the box (1) and located above multiple boxes (5); Multiple lower sealing plates (8) are disposed on the inner wall of the box (1) and located below multiple boxes (5); The drying assembly includes a dryer (15), an air inlet main pipe (9), an air outlet main pipe (12), multiple first air inlet branch pipes (10) and multiple first air outlet branch pipes (13). The dryer (15) is located on the top of the housing (1). The air inlet main pipe (9) is connected to the air outlet of the dryer (15). The air outlet main pipe (12) is connected to the air inlet of the dryer (15). Each first air inlet branch pipe (10) passes through the side wall of the housing (1) and the upper sealing plate (7) and is connected to the air inlet main pipe (9) at one end. Each first air outlet branch pipe (13) passes through the side wall of the housing (1) and the lower sealing plate (8) and is connected to the air outlet main pipe (12) at one end. Electric dampers (16) are provided on the first air inlet branch pipe (10) and the first air outlet branch pipe (13). A humidity sensor (18) is provided at the bottom of each upper sealing plate (7).
2. The pharmaceutical raw material storage device according to claim 1, characterized in that, Each of the support plates (2) has a slide rail (3) on its upper surface, and a pair of slide bars (4) are provided at the bottom of the box body (5). Each slide bar (4) is slidably disposed in each slide rail (3).
3. A storage device for pharmaceutical raw materials according to claim 1, characterized in that, Each of the first air inlet branch pipes (10) has a second air inlet branch pipe (11) connected at one end and below the upper sealing plate (7), and each of the second air inlet branch pipes (11) has multiple air outlets at its bottom.
4. A storage device for pharmaceutical raw materials according to claim 1, characterized in that, Each of the first air outlet branch pipes (13) has a second air outlet branch pipe (14) connected to one end above the lower sealing plate (8), and each of the second air outlet branch pipes (14) has multiple air inlets at the top.
5. A storage device for pharmaceutical raw materials according to claim 1, characterized in that, An air flow meter (17) is installed on each of the first air inlet branch pipes (10).