Artemisia argyi column forming device
By using a pressure sensor to monitor the stamping force and control the baffle retraction in the moxa stick forming device, the problem of over-stamping is solved, ensuring the quality of moxa stick forming.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-06-30
- Publication Date
- 2026-07-10
AI Technical Summary
Existing moxa stick forming equipment, due to its fixed stroke during the stamping process, is prone to over-stamping due to factors such as the dryness or wetness of the material, which affects the quality of the moxa stick.
A pressure sensor is used to monitor the real-time pressure of the stamping rod on the material, and the baffle is controlled to retract when the set pressure value is reached to avoid over-stamping. The formed Ai-zhu is then ejected by the stamping rod.
This achieves effective control over the moxa stick forming process, avoids over-stamping, and ensures the quality of the moxa sticks.
Smart Images

Figure CN224476627U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of moxa stick forming device, and in particular to a moxa stick forming device for processing mugwort. Background Technology
[0002] In traditional Chinese medicine theory, mugwort possesses various medicinal properties and is beneficial to human health. With societal progress, mugwort-processed products on the market are mainly mugwort sticks, which are convenient to use and often employed in moxibustion. Currently, the production process of mugwort sticks often relies on molds and stamping components for forming. However, existing stamping components have a fixed stroke during the stamping process, which can sometimes lead to over-stamping of the material due to factors such as the dryness or wetness of the material, thus affecting the quality of the mugwort sticks. To address this issue, this application proposes a mugwort stick forming device for processing mugwort, which effectively controls the compaction degree of the mugwort sticks, thereby solving the aforementioned problem. Utility Model Content
[0003] To address the above issues and overcome the shortcomings of existing technologies, this utility model provides a mugwort stick forming device for mugwort processing. The solution includes a base plate with a controller fixedly connected to it. The base plate has a support fixedly connected to its upper end, and a conical material cylinder fixedly connected to the support. A forming part is integrally connected to the bottom of the material cylinder, and the forming part has two forming cavities symmetrically arranged about its axis. A guide rail is fixedly connected to the bottom of the forming part, and a baffle for sealing the bottom of the forming cavities is slidably connected to the guide rail longitudinally. A vertical reciprocating mechanism is fixedly connected to the side wall of the material cylinder, and the vertical reciprocating mechanism drives a vertical moving rod. Two stamping rods corresponding to the forming cavities are fixedly connected to the vertical moving rod. A support plate is fixedly connected to the upper end of the base plate, and an electronic telescopic rod electrically connected to the controller is fixedly connected to the support plate. The telescopic end of the electronic telescopic rod is fixedly connected to the rear end of the baffle. A pressure sensor corresponding to the forming cavity on the right side and electrically connected to the controller is embedded in the upper end of the baffle.
[0004] Preferably, the vertical reciprocating mechanism includes a lower support plate fixedly connected to the side wall of the barrel, a guide rod fixedly connected to the lower support plate and slidably connected to the vertical moving rod, an upper support plate fixedly connected to the upper end of the guide rod, an active rod arranged parallel to the guide rod rotatably connected to the opposite end of the upper support plate and the lower support plate, the active rod being integrally connected to a reciprocating screw threadedly connected to the vertical moving rod, and a motor for driving the active rod fixedly connected to the upper support plate.
[0005] Preferably, the vertical moving rod is integrally formed with a threaded sleeve that is threadedly connected to the reciprocating lead screw, and the vertical moving rod is integrally formed with a guide sleeve that is slidably connected to the guide rod.
[0006] The beneficial effects of this utility model are:
[0007] This application features a simple structure, ease of use, and strong practicality. It uses a pressure sensor to monitor the pressure of the material in the forming cavity in real time. When the set pressure value is reached, the baffle can be controlled to remove the seal on the bottom of the forming cavity in time, so that the formed moxibustion column can be pushed out by the stamping rod. This avoids excessive pressure on the material in the forming cavity by the stamping rod, which would affect the quality of the moxibustion column. Attached Figure Description
[0008] Figure 1 This is a first-person perspective three-dimensional sectional view of the present invention.
[0009] Figure 2 This is an enlarged view of region A in the first-view perspective stereoscopic sectional view of this utility model.
[0010] Figure 3 This is a second-view perspective stereoscopic view of the present invention.
[0011] Figure 4 This is an enlarged view of region B in the second-view stereoscopic view of this utility model.
[0012] Figure 5 This is a third-person perspective stereoscopic view of the present invention.
[0013] Figure Labels
[0014] 1. Base plate, 2. Controller, 3. Support, 4. Barrel, 5. Forming section, 6. Forming cavity, 7. Guide rail, 8. Baffle, 9. Vertical reciprocating mechanism, 10. Vertical moving rod, 11. Stamping rod, 12. Support plate, 13. Electronic telescopic rod, 14. Pressure sensor, 15. Lower support plate, 16. Guide rod, 17. Upper support plate, 18. Driving rod, 19. Reciprocating screw, 20. Motor, 21. Threaded sleeve, 22. Guide sleeve. Detailed Implementation
[0015] The following is in conjunction with the appendix Figure 1-5 The specific embodiments of this utility model will be described in further detail.
[0016] In the first embodiment, the technical solution is as follows: When using this application, an appropriate amount of moxa stick forming material is placed in a cone-shaped cylinder 4 to allow the material to collapse into the forming cavity 6 on the forming section 5. The motor 20 of the vertical reciprocating mechanism 9 is activated, driving the drive rod 18 to rotate. This rotation of the motor 20, via the reciprocating screw 19, causes the vertical moving rod 10 to move vertically reciprocally along the guide rod 16. As the vertical moving rod 10 moves downwards along the guide rod 16, the pressing rod 11 moves downwards accordingly and acts on the material in the cylinder 4, thereby pressing the material in the cylinder 4 into the forming cavity 6. As the vertical moving rod 10 continues to move downwards, the pressing rod 11 will also move downwards. The rod extends into the forming cavity 6, further compressing the material in the forming cavity 6, causing the material to form in the forming cavity 6. The pressure sensor 14 on the baffle 8 can monitor the pressure of the stamping rod 11 on the material in the forming cavity 6 in real time. When the set pressure value is reached, the pressure sensor 14 transmits this information to the controller 2 in real time. After receiving this information, the controller 2 will activate the electronic telescopic rod 13 to retract and drive the baffle 8 to move backward, so that the baffle 8 can be released from the blockage of the forming cavity 6. This allows the formed moxa stick to be pushed out from the bottom of the forming cavity 6 as the stamping rod 11 continues to move downward, avoiding excessive pressure from the stamping rod 11 on the material in the forming cavity 6, which would affect the quality of the moxa stick.
[0017] In Example 2, based on Example 1, specifically, in use, the material cylinder 4 is fixed to the base plate 1 by the bracket 3. An electronic telescopic rod 13 is also installed on the base plate 1 via a support plate 12. Initially, the electronic telescopic rod 13 is as shown in the accompanying drawings. Figure 3 and Figure 5 As shown, in the extended state, the material cylinder 4 is first filled with a sufficient amount of material for forming the moxa stick. Then, the motor 20 of the vertical reciprocating mechanism 9 is started and rotates at a set speed. The start of the motor 20 drives the active rod 18, which is rotatably connected between the upper support plate 17 and the lower support plate 15, to rotate. Consequently, the reciprocating screw 19 will rotate synchronously. The rotation of the reciprocating screw 19 will drive the vertical moving rod 10 through the threaded sleeve 21. The vertical moving rod 10 is restricted by the sliding connection between the guide sleeve 22 and the guide rod. Thus, under the action of the reciprocating screw 19, the vertical moving rod 10 will move vertically reciprocally along the guide rod.
[0018] During the reciprocating movement of the vertical moving rod 10, when the vertical moving rod 10 moves downward, the stamping rod 11 will move downward accordingly and force the material into the stamping cavity. Until the stamping rod 11 enters the stamping cavity, it will further stamp and shape the material in the stamping cavity. As the stamping rod 11 continues to go deeper into the stamping cavity, the material in the stamping cavity will be further subjected to the action of the stamping rod 11 to ensure the forming effect. At the same time, the pressure sensor 14 on the baffle 8 will also monitor the pressure of the stamping rod 11 on the material in real time and transmit it to the controller 2. When the pressure sensor 14 detects that the pressure reaches the set value, the pressure sensor 14 transmits this information to the controller 2. The controller 2 will control the electronic telescopic rod 13 to retract. The retraction of the electronic telescopic rod 13 will drive the baffle 8 to slide backward along the guide rail 7, and then the guide rail 7 will disengage from the bottom of the forming cavity 6. After that, as the stamping rod 11 continues to press down, the formed column will be pushed out of the bottom of the forming cavity 6 by the stamping rod 11.
[0019] After the electronic telescopic rod 13 slides backward and stays for a set time under the action of the controller 2, the controller 2 will control the electronic telescopic rod 13 to extend and drive the baffle 8 to reset forward along the guide rail 7. Then the baffle 8 will block the bottom of the forming cavity 6 again. At this time, the stamping rod 11 will move upward and reset along the vertical moving rod 10. During the upward movement and reset of the stamping rod 11, the material in the material cylinder 4 will automatically collapse into the forming cavity 6 so that the stamping rod 11 can be stamped when it moves downward again, thereby completing the forming operation of the Aizhu.
Claims
1. A device for forming moxa sticks for processing mugwort, comprising a base plate (1), wherein a controller (2) is fixedly connected to the base plate (1), characterized in that, A bracket (3) is fixedly connected to the upper end of the base plate (1). A conical material cylinder (4) is fixedly connected to the bracket (3). A forming part (5) is integrally connected to the bottom of the material cylinder (4). The forming part (5) has two forming cavities (6) arranged symmetrically about its axis. A guide rail (7) is fixedly connected to the bottom of the forming part (5). A baffle (8) for sealing the bottom of the forming cavity (6) is slidably connected to the guide rail (7) longitudinally. A vertical reciprocating mechanism (9) is fixedly connected to the side wall of the material cylinder (4). The system is driven by a vertical moving rod (10), which is fixedly connected to two stamping rods (11) that correspond one-to-one with the forming cavity (6). The upper end of the base plate (1) is fixedly connected to a support plate (12), which is fixedly connected to an electronic telescopic rod (13) that is electrically connected to the controller (2). The telescopic end of the electronic telescopic rod (13) is fixedly connected to the rear end of the baffle (8). The upper end of the baffle (8) is fitted with a pressure sensor (14) that corresponds to the forming cavity (6) on the right side and is electrically connected to the controller (2).
2. The mugwort processing moxa stick forming device according to claim 1, characterized in that, The vertical reciprocating mechanism (9) includes a lower support plate (15) fixedly connected to the side wall of the cylinder (4). The lower support plate (15) is fixedly connected to a guide rod (16) arranged vertically and slidably connected to the vertical moving rod (10). The upper end of the guide rod (16) is fixedly connected to an upper support plate (17). The upper support plate (17) and the lower support plate (15) are rotatably connected to an active rod (18) arranged parallel to the guide rod (16). The active rod (18) is integrally connected to a reciprocating screw (19) threadedly connected to the vertical moving rod (10). The upper support plate (17) is fixedly connected to a motor (20) for driving the active rod (18).
3. The mugwort processing moxa stick forming device according to claim 2, characterized in that, The vertical moving rod (10) is integrally formed with a threaded sleeve (21) that is threadedly connected to the reciprocating lead screw (19), and the vertical moving rod (10) is integrally formed with a guide sleeve (22) that is slidably connected to the guide rod (16).