Acupuncture needle device with micro-current stimulation function
By designing an acupuncture needle device that controls the position of the negative electrode column through a transmission and movement mechanism, the problem of existing equipment being unable to achieve electrical stimulation in specific areas around acupoints has been solved. This has enabled precise electrical stimulation and improved blood flow, thereby enhancing the therapeutic effect of acupuncture.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- 宁海县第一医院
- Filing Date
- 2026-05-18
- Publication Date
- 2026-07-14
AI Technical Summary
Existing acupuncture devices with microcurrent stimulation functions have difficulty achieving accurate electrical stimulation of specific areas around acupoints, affecting the synergistic effect of electrical stimulation.
An acupuncture needle device with microcurrent stimulation function was designed. The position of the negative electrode column is precisely controlled by the transmission mechanism and the moving mechanism. The multi-point electrical stimulation of the negative electrode column is achieved by the top moving mechanism. The stability of the device is ensured by the double fixation of the positive electrode clamp and the permanent magnet block.
It achieves precise electrical stimulation around acupoints, promotes blood circulation, enhances therapeutic effects, and improves the applicability and practicality of the device.
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Figure CN122376449A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to acupuncture techniques, specifically to an acupuncture needle device with microcurrent stimulation function. Background Technology
[0002] Traditional acupuncture, a long-standing and widely used treatment method in Traditional Chinese Medicine, involves precisely inserting acupuncture needles into specific acupoints on the body. The mechanical stimulation generated by the needles activates the flow of Qi and blood in the meridians, thereby achieving the therapeutic goals of harmonizing Yin and Yang, clearing the meridians, and strengthening the body's resistance to pathogens. However, with the continuous development of modern medical technology and people's increasing pursuit of better treatment results, traditional acupuncture has gradually revealed some limitations.
[0003] On the one hand, traditional acupuncture relies solely on the mechanical stimulation generated by needles, and its stimulation method and intensity are relatively simple, making it difficult to adjust flexibly and precisely according to the specific condition of different patients and the characteristics of acupoints. This limitation means that the therapeutic effect may not meet expectations when treating certain complex diseases or diseases with special requirements for stimulation intensity.
[0004] On the other hand, traditional acupuncture has relatively limited effectiveness in promoting blood circulation around acupoints. Good blood circulation is crucial for delivering nutrients, removing metabolic waste, and promoting tissue repair and regeneration. The shortcomings of traditional acupuncture in this regard may, to some extent, affect its therapeutic efficacy for some conditions requiring improved local blood circulation.
[0005] To overcome these limitations of traditional acupuncture, microcurrent stimulation technology has gradually been introduced into the field of acupuncture. Microcurrent stimulation, by applying tiny currents to acupuncture needles, adds a new dimension of stimulation—electrical stimulation—to acupuncture treatment. Electrical stimulation can not only enhance the stimulation effect on acupoints but also more effectively promote blood circulation around acupoints and stimulate the flow of Qi and blood in the meridians, thereby potentially improving the overall therapeutic effect.
[0006] Currently, although some acupuncture devices with microcurrent stimulation functions exist on the market, most of these devices have insufficient functionality. For example, some devices cannot accurately control the position of the negative electrode, making it difficult to achieve accurate electrical stimulation of specific areas around acupoints, thus affecting the synergistic effect of electrical stimulation.
[0007] Therefore, developing a device with microcurrent stimulation capabilities and precise control over the negative electrode position to achieve accurate electrical stimulation of specific areas around acupoints has become a pressing issue in the field of acupuncture. This invention arose from this background and technological need, aiming to provide an innovative solution to improve the efficacy and applicability of acupuncture treatment. Summary of the Invention
[0008] The purpose of this invention is to provide an acupuncture needle device with microcurrent stimulation function to solve the problem in the prior art that it is difficult to achieve accurate electrical stimulation of a specific area around the acupoint, thus affecting the synergistic effect of electrical stimulation.
[0009] To achieve the above objectives, the present invention provides the following technical solution: an acupuncture needle device with microcurrent stimulation function, comprising a support frame, a telescopic drive component fixedly connected inside the support frame, an output end of the telescopic drive component connected to a mounting plate, a plurality of mounting boxes provided at the bottom of the mounting plate, a mounting block connected to the top of the mounting box, a first elastic component connected to one side of the mounting block, a positive electrode clamp fixedly connected to one end of the first elastic component, the positive electrode clamp being connected to the positive terminal of a power supply via a wire, and the acupuncture needle body being held inside the positive electrode clamp;
[0010] A mounting ring is rotatably connected to the mounting box. A transmission mechanism connected to the mounting box is driven to the outer surface of the mounting ring. The transmission mechanism is used to drive the mounting ring to rotate horizontally. A transmission block is slidably connected to the bottom of the mounting ring. A moving mechanism connected to the mounting ring is provided on the transmission block. The moving mechanism is used to drive the transmission block to move horizontally. A connecting frame is fixedly connected to the bottom of the transmission block. A transmission column is slidably connected inside the connecting frame. A second elastic element connected to the connecting frame is fixedly sleeved on the outer surface of the transmission column. A negative terminal is connected to the bottom end of the transmission column. The negative terminal is connected to the negative terminal of the power supply through a wire. A jacking mechanism connected to the connecting frame is provided at the top end of the transmission column. The jacking mechanism is used to drive the transmission column to move vertically.
[0011] Furthermore, the transmission mechanism includes a first rotation drive component fixedly connected to the mounting box, the output end of the first rotation drive component is fixedly connected to a drive shaft, the outer surface of the drive shaft is fixedly sleeved with a first gear, and the outer surface of the first gear is meshed with a transmission gear ring fixedly connected to the mounting ring.
[0012] Furthermore, the moving mechanism includes a second rotational drive component fixedly connected to the mounting ring, the output end of the second rotational drive component being fixedly connected to a threaded rod rotatably connected to the mounting ring, the outer surface of the threaded rod being threadedly engaged with the transmission block, and a guide rod fixedly connected to the mounting ring being slidably connected to the transmission block.
[0013] Furthermore, the jacking mechanism includes a first electromagnet block fixedly connected to the transmission block, a connecting block fixedly connected to the top of the transmission column, and a second electromagnet block fixedly connected to the top of the connecting block.
[0014] Furthermore, the negative terminal and the transmission terminal are connected by a thread, and different negative terminals can be replaced according to the actual situation.
[0015] Furthermore, a connecting frame is fixedly connected to the outer surface of the mounting box, a permanent magnet block is fixedly connected to the top of the connecting frame, and an iron plate is fixedly connected to the bottom of the mounting plate.
[0016] Furthermore, the bottom end of the negative electrode post has an inverted arc.
[0017] Furthermore, the bottom of the support frame is fixedly connected with multiple casters.
[0018] Compared with the prior art, the acupuncture needle device with microcurrent stimulation function provided by the present invention has the following beneficial effects:
[0019] The acupuncture needle body is held and fixed by a positive clamp, which is then energized. A transmission mechanism drives the mounting ring to rotate horizontally, which in turn drives the negative electrode column to rotate horizontally. Simultaneously, a moving mechanism moves the transmission block horizontally, achieving horizontal displacement of the negative electrode column. This design allows the negative electrode column to quickly and accurately move to a predetermined position around the acupuncture point on the needle body. Combined with a pushing mechanism, the negative electrode column moves downwards to contact the skin, forming a pathway for electrical stimulation. Furthermore, the position of the negative electrode column can be adjusted multiple times to provide multi-point electrical stimulation around the acupuncture point. Compared to traditional acupuncture methods, this approach can more precisely target the area around the acupuncture point, effectively promoting blood circulation and enhancing the therapeutic effect on the patient.
[0020] During use, the permanent magnet on the connecting frame is attracted to the iron plate on the mounting plate, securing the mounting box and the acupuncture needle body. Simultaneously, the positive clamp holds the acupuncture needle body, providing double fixation to prevent it from falling and ensuring stability during acupuncture. When the positive clamp is energized, the acupuncture needle body provides electrical stimulation to the patient's acupoints, causing the needle to vibrate under the influence of the current. At this time, the first elastic element and the positive clamp provide auxiliary support, ensuring smooth vibration even when the acupuncture needle body is fixed. This vibration stimulation, compared to simple electrical stimulation, more effectively stimulates acupoints, promotes the flow of Qi and blood in the meridians, and enhances the therapeutic effect of acupuncture. Furthermore, the negative terminal is threadedly connected to the transmission terminal, allowing for the replacement of negative terminals of different lengths to suit different patients' skin conditions and acupoint depths, improving the applicability and practicality of the device. Attached Figure Description
[0021] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this invention. For those skilled in the art, other drawings can be obtained based on these drawings.
[0022] Figure 1 This is a first perspective view of the external structure of the present invention;
[0023] Figure 2 This is a second perspective view of the external structure of the present invention;
[0024] Figure 3 This is a perspective view of the internal structure of the mounting box of the present invention;
[0025] Figure 4 For the present invention Figure 2 Enlarged view of A in the middle;
[0026] Figure 5 For the present invention Figure 3 A magnified view of B in the middle.
[0027] Explanation of reference numerals in the attached figures:
[0028] 1. Support frame; 2. Telescopic drive component; 3. Mounting plate; 4. Mounting box; 5. Mounting block; 6. First elastic component; 7. Positive clamp; 8. Acupuncture needle body; 9. Mounting ring; 10. Transmission block; 11. Connecting frame; 12. Transmission column; 13. Second elastic component; 14. Negative column; 21. First rotation drive component; 22. Drive shaft; 23. First gear; 24. Transmission gear ring; 31. Second rotation drive component; 32. Threaded rod; 33. Guide rod; 41. First electromagnet block; 42. Connecting block; 43. Second electromagnet block; 51. Connecting frame; 52. Permanent magnet block; 53. Iron plate; 61. Universal wheel. Detailed Implementation
[0029] To enable those skilled in the art to better understand the technical solution of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings.
[0030] Example
[0031] Please see Figures 1 to 5 As shown, the present invention provides an acupuncture needle device with microcurrent stimulation function, including a support frame 1, a telescopic drive component 2 fixedly connected inside the support frame 1, an output end of the telescopic drive component 2 connected to a mounting plate 3, a plurality of mounting boxes 4 provided at the bottom of the mounting plate 3, a mounting block 5 connected to the top of the mounting box 4, a first elastic component 6 connected to one side of the mounting block 5, the first elastic component 6 being a spring, a positive electrode clip 7 fixedly connected to one end of the first elastic component 6, the positive electrode clip 7 being connected to the positive electrode of a power supply via a wire, and an acupuncture needle body 8 held inside the positive electrode clip 7;
[0032] Mounting ring 9 is rotatably connected to mounting box 4. A transmission mechanism connected to mounting box 4 is driven to the outer surface of mounting ring 9. The transmission mechanism is used to drive mounting ring 9 to rotate horizontally. A transmission block 10 is slidably connected to the bottom of mounting ring 9. A moving mechanism connected to mounting ring 9 is provided on transmission block 10. The moving mechanism is used to drive transmission block 10 to move horizontally. A connecting frame 11 is fixedly connected to the bottom of transmission block 10. A transmission column 12 is slidably connected inside connecting frame 11. A second elastic element 13 connected to connecting frame 11 is fixedly sleeved on the outer surface of transmission column 12. The second elastic element 13 is a spring. A negative terminal 14 is connected to the bottom end of transmission column 12. The negative terminal 14 is connected to the negative terminal of power supply through an electric wire. A jacking mechanism connected to connecting frame 11 is provided at the top end of transmission column 12. The jacking mechanism is used to drive transmission column 12 to move vertically.
[0033] The transmission mechanism includes a first rotation drive component 21 fixedly connected to the mounting box 4. The first rotation drive component 21 is a servo motor. The servo motor is controlled by a PLC programming program, which can control the servo motor to rotate forward and backward and rotate at different angles. The output end of the first rotation drive component 21 is fixedly connected to a drive shaft 22. A first gear 23 is fixedly sleeved on the outer surface of the drive shaft 22. A transmission gear ring 24 fixedly connected to the mounting ring 9 is meshed on the outer surface of the first gear 23. The first rotation drive component 21 drives the drive shaft 22 to rotate, and the drive shaft 22 drives the transmission gear ring 24 and the mounting ring 9 to rotate through the first gear 23.
[0034] The moving mechanism includes a second rotation drive 31 fixedly connected to the mounting ring 9. The second rotation drive 31 is a servo motor, which is controlled by a PLC programming program. The servo motor can be controlled to rotate forward and backward and rotate at different angles. The output end of the second rotation drive 31 is fixedly connected to a threaded rod 32 that is rotatably connected to the mounting ring 9. The outer surface of the threaded rod 32 is threadedly engaged with the transmission block 10. A guide rod 33 that is fixedly connected to the mounting ring 9 is slidably connected to the transmission block 10. The second rotation drive 31 drives the threaded rod 32 to rotate, and the threaded rod 32 drives the transmission block 10 to move.
[0035] The jacking mechanism includes a first electromagnet block 41 fixedly connected to the transmission block 10, a connecting block 42 fixedly connected to the top of the transmission column 12, and a second electromagnet block 43 fixedly connected to the top of the connecting block 42.
[0036] The negative terminal 14 is threadedly connected to the transmission terminal 12. The negative terminal 14 of different lengths can be replaced according to the actual situation.
[0037] A connecting frame 51 is fixedly connected to the outer surface of the mounting box 4. A permanent magnet block 52 is fixedly connected to the top of the connecting frame 51, and an iron plate 53 is fixedly connected to the bottom of the mounting plate 3.
[0038] The bottom of the negative electrode post 14 is rounded, which reduces the irritation of the negative electrode post 14 to the patient's skin.
[0039] The bottom of the support frame 1 is fixedly connected with multiple casters 61, which facilitate the movement of the support frame.
[0040] First, the doctor performs acupuncture on the patient. After the needles are inserted, the medical staff moves the support frame 1 to the required position. Then, the telescopic drive 2 moves the mounting plate 3 downwards to the appropriate position. Next, the mounting box 4 is moved, and the acupuncture needle body 8 is inserted into it. At the same time, the permanent magnet block 52 on the connecting frame 51 is attracted to the iron plate 53 on the mounting plate 3, fixing the connecting frame 51 and the mounting box 4. Then, the positive clamp 7 clamps the acupuncture needle body 8 to hold and fix it. Simultaneously, the corresponding length of the negative pole 14 is screwed and fixed to the transmission pole 12. Then, the next acupuncture needle body 8 is clamped and fixed, and the mounting box 4 is fixed, thus allowing multiple needles to be inserted. The acupuncture needle body 8 is clamped and fixed to prevent it from falling off, and a positive connection is made. After the connection is completed, the positive clamp 7 on each mounting box 4 is energized. At this time, the positive clamp 7 energizes the acupuncture needle body 8, and the acupuncture needle body 8 provides electrical stimulation to the patient's acupoints. This causes the muscles to contract rhythmically under electrical stimulation, thereby causing the acupuncture needle body to vibrate. With the assistance of the first elastic element 6 and the positive clamp 7, the acupuncture needle body 8 can vibrate even when fixed, promoting the stimulation of acupoints. At the same time, during the energization process, the first rotation drive 21 drives the drive shaft 22 to rotate. The drive shaft 22 is connected to the first... A gear 23 drives the transmission gear ring 24 and the mounting ring 9 to rotate. The mounting ring 9 drives the transmission block 10, the connecting frame 11, the transmission column 12, and the negative electrode column 14 to rotate. Simultaneously, the second rotation drive component 31 drives the threaded rod 32 to rotate. The threaded rod 32 drives the transmission block 10 to move, thereby moving the negative electrode column 14 to a set position around the acupuncture needle body 8. Then, the first electromagnet block 41 on the connecting frame 11 is energized, and the second electromagnet block 43 is simultaneously supplied with opposite currents. At this time, a repulsive force is generated between the first electromagnet block 41 and the second electromagnet block 43, thereby driving the second electromagnet block 43 to move downward. 3. The connecting block 42 and the transmission column 12 are moved. The transmission column 12 drives the negative electrode column 14 to move downward, so that the negative electrode column 14 contacts the skin around the acupuncture needle body 8. At this time, a passage is formed between the acupuncture needle body 8 and the negative electrode column 14. At this time, electrical stimulation is applied to the acupoints around the acupuncture needle body 8. Then, the negative electrode column 14 is moved to the next position and contacts the skin, thereby realizing electrical stimulation around the acupoints of each acupuncture needle body 8, further promoting blood circulation around the acupoints and further improving the acupuncture effect on the patient. When the first electromagnet block 41 is de-energized, the transmission column 12 is driven to move upward under the action of the second elastic element 13.
[0041] Working principle:
[0042] Preliminary preparations and device positioning:
[0043] The doctor first performed routine acupuncture on the patient, inserting the needles.
[0044] Medical staff move the support frame 1 to the required position. Multiple casters 61 fixedly connected to the bottom of the support frame 1 facilitate its flexible movement.
[0045] Activate the telescopic drive component 2, which drives the mounting plate 3 to move downwards, moving it to a suitable position to prepare for the subsequent installation of the acupuncture needle body 8 and related components.
[0046] Fixing and positive electrode connection between the acupuncture needle body 8 and the mounting box 4:
[0047] The acupuncture needle body 8 is inserted into the mounting box 4. At the same time, the permanent magnet block 52 on the connecting frame 51 fixedly connected to the outer surface of the mounting box 4 is attracted to the iron plate 53 fixedly connected to the bottom of the mounting plate 3, thus fixing the connecting frame 51 and the mounting box 4.
[0048] The positive electrode clip 7 clamps the acupuncture needle body 8, holding and fixing the acupuncture needle body 8 to achieve positive electrode connection.
[0049] According to the actual situation, the corresponding length of the negative terminal 14 is screwed and fixed on the transmission post 12 (the negative terminal 14 and the transmission post 12 are threaded together, which makes it convenient to replace the negative terminal 14 of different lengths).
[0050] Following the above procedures, clamp and fix the multiple acupuncture needle bodies 8 in sequence and install the negative electrode post 14, and then fix the corresponding mounting box 4 to prevent the acupuncture needle bodies 8 from falling off.
[0051] The acupuncture needle body is electrically and vibrates to stimulate acupoints:
[0052] When the positive clamp 7 on each mounting box 4 is energized, the positive clamp 7 conducts the current to the acupuncture needle body 8, at which time the acupuncture needle body 8 stimulates the acupoints of the patient with current.
[0053] When the muscle is subjected to an electric current, it causes the acupuncture needle to vibrate. Due to the auxiliary effect of the first elastic element 6 and the positive electrode clamp 7 connected to one side of the mounting block 5, the acupuncture needle body 8 can also vibrate even when it is fixed, thereby promoting the stimulation of acupoints.
[0054] Adjustment of the position of negative terminal 14:
[0055] Horizontal rotation adjustment: Start the first rotation drive component 21 (servo motor, controlled by PLC programming program to rotate forward and backward and rotate angle) in the transmission mechanism. The first rotation drive component 21 drives the drive shaft 22 to rotate. The first gear 23 on the outer surface of the drive shaft 22 rotates accordingly. The first gear 23 drives the transmission gear ring 24 fixedly connected to the mounting ring 9 to rotate, thereby causing the mounting ring 9 to rotate in the horizontal direction. The mounting ring 9 drives the transmission block 10, the connecting frame 11, the transmission column 12 and the negative pole column 14 to rotate together.
[0056] Horizontal movement adjustment: Start the second rotation drive 31 (servo motor, controlled by PLC programming program to rotate forward and backward and rotate angle) in the moving mechanism. The second rotation drive 31 drives the threaded rod 32 to rotate. Since the threaded rod 32 is threadedly engaged with the transmission block 10, and the transmission block 10 is guided by the guide rod 33 (fixedly connected to the mounting ring 9), the threaded rod 32 drives the transmission block 10 to move horizontally, thereby driving the negative electrode column 14 to move horizontally, so that the negative electrode column 14 moves to the set position around the acupuncture needle body 8.
[0057] The negative electrode post 14 forms a pathway and provides electrical stimulation upon contact with the skin.
[0058] When opposite currents are simultaneously applied to the first electromagnet block 41 and the second electromagnet block 43 in the jacking mechanism, the first electromagnet block 41 is fixedly connected to the transmission block 10, and a connecting block 42 is fixedly connected to the top of the transmission column 12. The second electromagnet block 43 is fixedly connected to the top of the connecting block 42. At this time, a repulsive force is generated between the first electromagnet block 41 and the second electromagnet block 43, which drives the second electromagnet block 43 to move downward. The second electromagnet block 43 drives the connecting block 42 and the transmission column 12 to move downward. The transmission column 12 drives the negative electrode column 14 to move downward, so that the negative electrode column 14 contacts the skin around the acupuncture needle body 8. At this time, a circuit is formed between the acupuncture needle body 8 and the negative electrode column 14, and electrical stimulation is applied to the acupuncture needle body 8 around the acupuncture point. When the first electromagnet block 41 is de-energized, the transmission column 12 moves upward under the action of the second elastic element 13.
[0059] Multi-point electrical stimulation:
[0060] Repeat the above operation of adjusting the position of the negative electrode post 14 and forming a pathway with the skin, moving the negative electrode post 14 to the next position and making contact with the skin, thereby achieving multi-point electrical stimulation around the acupuncture points of each acupuncture needle body 8, further promoting blood circulation around the acupuncture points and improving the acupuncture effect on the patient.
[0061] The foregoing has only described certain exemplary embodiments of the present invention by way of illustration. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the foregoing drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.
Claims
1. An acupuncture needle device with microcurrent stimulation function, characterized in that, Includes a support frame (1), a telescopic drive component (2) is fixedly connected inside the support frame (1), an installation plate (3) is connected to the output end of the telescopic drive component (2), a plurality of installation boxes (4) are provided at the bottom of the installation plate (3), an installation block (5) is connected to the top of the installation box (4), a first elastic component (6) is connected to one side of the installation block (5), a positive electrode clip (7) is fixedly connected to one end of the first elastic component (6), the positive electrode clip (7) is connected to the positive terminal of the power supply through a wire, and the acupuncture needle body (8) is held inside the positive electrode clip (7). A mounting ring (9) is rotatably connected to the mounting box (4). A transmission mechanism connected to the mounting box (4) is driven to the outer surface of the mounting ring (9). The transmission mechanism is used to drive the mounting ring (9) to rotate horizontally. A transmission block (10) is slidably connected to the bottom of the mounting ring (9). A moving mechanism connected to the mounting ring (9) is provided on the transmission block (10). The moving mechanism is used to drive the transmission block (10) to move horizontally. The bottom of the transmission block (10) is fixedly connected to... A connecting frame (11) is connected, and a transmission column (12) is slidably connected inside the connecting frame (11). A second elastic element (13) connected to the connecting frame (11) is fixedly sleeved on the outer surface of the transmission column (12). A negative pole (14) is connected to the bottom end of the transmission column (12). The negative pole (14) is connected to the negative pole of the power supply through a wire. A jacking mechanism connected to the connecting frame (11) is provided at the top end of the transmission column (12). The jacking mechanism is used to drive the transmission column (12) to move vertically.
2. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The transmission mechanism includes a first rotating drive member (21) fixedly connected to the mounting box (4), the output end of the first rotating drive member (21) is fixedly connected to a drive shaft (22), the outer surface of the drive shaft (22) is fixedly sleeved with a first gear (23), and the outer surface of the first gear (23) is meshed with a transmission gear ring (24) fixedly connected to the mounting ring (9).
3. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The moving mechanism includes a second rotation drive (31) fixedly connected to the mounting ring (9). The output end of the second rotation drive (31) is fixedly connected to a threaded rod (32) rotatably connected to the mounting ring (9). The outer surface of the threaded rod (32) is threadedly engaged with the transmission block (10). The transmission block (10) is slidably connected to a guide rod (33) fixedly connected to the mounting ring (9).
4. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The jacking mechanism includes a first electromagnet block (41) fixedly connected to the transmission block (10), a connecting block (42) fixedly connected to the top of the transmission column (12), and a second electromagnet block (43) fixedly connected to the top of the connecting block (42).
5. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The negative terminal (14) is threadedly connected to the transmission terminal (12).
6. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The outer surface of the mounting box (4) is fixedly connected to a connecting frame (51), the top of the connecting frame (51) is fixedly connected to a permanent magnet block (52), and the bottom of the mounting plate (3) is fixedly connected to an iron plate (53).
7. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The bottom of the negative electrode post (14) is curved.
8. The acupuncture needle device with microcurrent stimulation function according to claim 1, characterized in that, The bottom of the support frame (1) is fixedly connected with multiple casters (61).