Finger joint motion positioning training component and training device
By designing finger joint motion positioning training components and devices, and using rotation and translation mechanisms and sliding adjustment components to simulate the natural movement trajectory of finger joints, the problem that existing rehabilitation methods cannot effectively address hand joint stiffness and excessive muscle tension is solved, achieving a safe and comfortable passive stretching training effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI WEINI MEDICAL INSTR
- Filing Date
- 2025-07-18
- Publication Date
- 2026-07-14
AI Technical Summary
Existing rehabilitation methods cannot effectively address hand joint stiffness, excessive muscle tone, and contractures through targeted passive stretching training. Traditional methods are laborious and lack safety, while intelligent rehabilitation equipment cannot adapt to complex hand joint movements.
A finger joint motion positioning training component and device were designed. It adopts a rotational translation mechanism and a sliding adjustment component to simulate the natural movement trajectory of the finger joint. The joint movement area is covered by circular arc and involute trajectory. Combined with a rotational position compensation drive rod and finger sleeve, it ensures that the joint moves within the physiological curve.
It enables safe and comfortable passive movement of the hand joints, avoiding postoperative swelling and prosthesis loosening caused by non-physiological curves, improving training effectiveness and safety, and is suitable for various hand joint training methods.
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Figure CN224484446U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of surgical medical device technology, and in particular to a finger joint motion positioning training component and training device. Background Technology
[0002] After joint surgery, prolonged immobilization or rest in the hand can cause a series of pathological changes in the joint and surrounding tissues, leading to thickening and contracture of ligaments and joint capsules, joint degeneration, and stiffness and limited movement in the hand and wrist joints. In particular, after stroke or hemiplegia, due to damage to the brain nerves, more than 80% of patients will experience hemiplegia accompanied by spasticity, hypertonia, and other sequelae. Prolonged immobilization, or without active treatment, can lead to permanent hypertonia, joint contractures, and abnormal movement patterns in the fingers and wrist joints.
[0003] Currently, the main methods used to reduce hand joint stiffness, high muscle tone, and flexion contractures are physical therapist manual stretching (PT), continuous passive motion (CPM), and intelligent rehabilitation robot exercise training systems. However, these rehabilitation methods have significant drawbacks. Manual stretching relies heavily on the therapist's physical exertion, and traditional physical stretching is very strenuous. The duration, intensity, and rehabilitation strategies also depend on the therapist's experience and subjective feelings. CPM passive motion rehabilitation machines are mainly used in orthopedics to maintain joint mobility and prevent joint stiffness caused by swelling and hematoma after trauma or surgery. To ensure safety, CPM passive motion rehabilitation machines use a force-resistance operating mode. However, due to factors such as joint swelling and hematoma after trauma or surgery, they often encounter varying degrees of resistance during operation, resulting in a relatively small passive range of motion, and the limb usually cannot move at full angle. Intelligent exercise rehabilitation training systems typically use a primary / passive movement mode with active force and device assistance, generating repetitive combined limb movements, but cannot provide effective targeted passive stretching training for joints with high muscle tone or contractures.
[0004] The hand is the part of the human body with the most and most concentrated joints and the most complex physiological structure. Its functions are delicate, sensitive and complex, which makes the development of hand function rehabilitation robots relatively complicated. How to ensure the safety and effectiveness of hand training is an urgent problem to be solved. Utility Model Content
[0005] Therefore, it is necessary to provide a finger joint motion positioning training component and training device that can simulate the natural motion trajectory of human hand joints for motion training, in order to address the above-mentioned technical problems.
[0006] This application provides a finger joint motion positioning training component, including:
[0007] The transmission rod is configured to be fixedly connected to the side of the sliding adjustment component of the rotational translation mechanism, and is used to transmit rotational circular motion;
[0008] A rotary position compensation drive rod is rotatably connected to the transmission rod, and the rotary position compensation drive rod is perpendicular to the axis of rotation of the rotary translation mechanism;
[0009] An adjustment belt, wherein multiple connection points are distributed along the length direction of the adjustment belt;
[0010] The finger sleeve can be selectively connected to any connection point on the adjustment band to correspond to and fix the finger part to be trained; and the finger sleeve is slidably sleeved on the rotary position compensation drive rod.
[0011] A fixing strap is used to secure the finger sleeve to the connection point.
[0012] This application provides a finger joint movement training device, including the aforementioned finger joint movement positioning training component, and further comprising:
[0013] Bracket, used to support the forearm;
[0014] A rotary drive mechanism is used to provide rotary driving force;
[0015] A rotational translation mechanism is spaced apart from the bracket and detachably connected to the rotary drive mechanism, so that it rotates by a preset first stage angle α under the driving action of the rotary drive mechanism and reaches position A, forming a first stage arc trajectory.
[0016] Furthermore, the rotating translation mechanism has a sliding adjustment component on the side away from the bracket. When the rotating translation mechanism rotates beyond the preset first stage angle a1 and is in the second stage, the sliding adjustment component is configured to be driven to translate in a direction close to the rotation axis of the rotating translation mechanism to form an involute trajectory. The trajectory contracts by an angle b1 along the base circle tangent and reaches the position B of the second stage.
[0017] Among them, the finger joints form different trajectories when they make different natural movements, and the different trajectory envelopes form trajectory regions. The trajectory of the first stage and the trajectory of the second stage cover the trajectory regions.
[0018] The positioning training component is connected to the sliding adjustment component and is used for positioning training of finger joints.
[0019] This application provides a method for designing the trajectory of finger joint movement training, including:
[0020] Record the trajectory formed by the natural movements of the hand joints, and form the trajectory region by the envelope of the trajectory formed by the various natural movements of the finger joints;
[0021] Record the trajectory of the joint movements sequentially from the distal interphalangeal joint, the proximal interphalangeal joint to the metacarpophalangeal joint, forming a trajectory line H, which includes three arcs.
[0022] Record the trajectory of the joint movements sequentially from the metacarpophalangeal joint, proximal interphalangeal joint to the distal interphalangeal joint, forming a trajectory line K, which includes an arc and an involute in sequence.
[0023] The envelopes of trajectory lines H and K form a closed trajectory region;
[0024] In the first stage, the sliding adjustment component of the driving mechanism rotates in space to a preset first stage angle a1, generating an arc trajectory and reaching position A; then, in the second stage when the rotation angle exceeds the first stage angle a1, the sliding adjustment component is driven to move towards the direction closer to the rotation axis. The sliding adjustment component achieves a displacement radially along the rotation axis and gradually approaches the rotation axis. The displacement trajectory contracts b1 along the base circle tangent and forms an involute, reaching position B.
[0025] In some embodiments, the range of a1 is 78°-82°, and the range of b1 is 98°-102°.
[0026] This application provides a finger joint exercise training method for training the thumb or interphalangeal joints, the method comprising:
[0027] The forearm is placed on the bracket, and the transmission rod is fixedly connected to the side of the sliding adjustment component of the rotation and translation mechanism. The finger sleeve is pre-adjusted to the connection point on the adjustment belt, which corresponds to the finger part to be trained. The finger sleeve is fixed to the connection point using the fixing belt, and the rotational position compensation drive rod is passed through the finger sleeve.
[0028] During forward motion training, the palm joint is placed on the hand support bar, the fingers are inserted into the finger sleeves, and the rotary drive mechanism provides rotary drive force, which drives the entire rotary translation mechanism to rotate to the preset first stage angle a1, reaching position A;
[0029] When the rotation exceeds the preset first stage angle, the sliding adjustment component drives the transmission rod to rotate in space and translate along the direction close to the rotation axis. The displacement trajectory contracts by angle b1 along the base circle tangent and reaches the second stage position B. The trajectory line H formed by the natural movement of the thumb or interphalangeal joint and the trajectory line K form a closed trajectory area. The trajectory of the first stage and the trajectory of the second stage together cover the trajectory area.
[0030] When the transmission rod rotates, the finger part is propelled to move by the rotary position compensation drive rod and the finger sleeve. The finger sleeve slides freely along the rotary position compensation drive rod, while the rotary position compensation drive rod rotates relative to the transmission rod to compensate when the natural movement trajectory of the joint is not synchronized with the movement trajectory of the sliding adjustment component, so that the joint moves along its own natural movement trajectory.
[0031] In some embodiments, the range of a1 is 78°-82°, and the range of b1 is 98°-102°.
[0032] This application provides an automatic control method for a finger joint exercise training device, including:
[0033] Obtain information about the finger joints that need to be exercised;
[0034] Switch the target motion mode based on the joint location information;
[0035] Based on the target motion mode, the rotary drive mechanism is activated to provide rotary driving force, and the sliding adjustment component is rotated at a preset first stage angle to form an arc trajectory;
[0036] And, after being driven to reach the preset first stage angle α, the sliding adjustment component is controlled to rotate while translating along the direction close to the rotation axis, reaching the second stage position B to form an involute trajectory;
[0037] As the positioning training component moves along with the sliding adjustment component, it drives the target hand joint to move, and the movement trajectory includes an arc in the first stage and an involute in the second stage.
[0038] The hand joint rehabilitation training robot of this invention strictly controls limb fixation, force points, and movement trajectories during use, ensuring that the passive joint movement curve conforms to the natural movement trajectory of the hand joint. For complex joint movements, it innovatively adopts a design concept that includes two stages in the force direction and movement trajectory, enabling the hand joint to bend to a normal fist-clenching angle, while ensuring patient comfort and painlessness throughout the entire process.
[0039] Early postoperative exercise training that conforms to the physiological curve allows patients to perform joint movements within a painless range, accelerating the recovery process. This avoids unnecessary medical accidents caused by exercise training that does not conform to the physiological curve, such as significant postoperative joint swelling, increased drainage, and in severe cases, loosening of the implanted prosthesis or wound dehiscence.
[0040] This invention combines a rotating translation mechanism, positioning training components for different joint positions, and a variable bracket installation position, as well as a preset first-stage angle, to be used for various training methods such as interphalangeal joint training and thumb joint training. It is flexible in use and highly functional. Attached Figure Description
[0041] Figure 1 This is a partial structural diagram of a postoperative hand joint movement therapy system provided in one embodiment of this application;
[0042] Figure 2 This is a three-dimensional view of a postoperative hand joint exercise therapy system for interphalangeal joint training provided in one embodiment of this application;
[0043] Figure 3 This is a schematic diagram illustrating the natural movement trajectory of finger joint flexion and extension; where, Figure 3 The consecutive diagrams a, 3b, and 3c illustrate the trajectory of joint movements sequentially from the distal interphalangeal joint, the proximal interphalangeal joint, to the metacarpophalangeal joint. Figure 3 The consecutive diagrams d, 3e, and 3f show the trajectory of joint movements as they proceed sequentially from the metacarpophalangeal joint, proximal interphalangeal joint, to the distal interphalangeal joint.
[0044] Figure 4 This is a schematic diagram of the motion trajectory of the rotary drive mechanism driving the sliding adjustment component when used for interphalangeal joint training.
[0045] Figure 5 This is a schematic diagram of a finger joint training glove;
[0046] Figure 6 This is a side view of the postoperative hand joint exercise therapy system for forearm training provided in one embodiment of this application;
[0047] Figure 7 This is a diagram illustrating internal and external pronation during forearm training exercises.
[0048] Figure 8 A comparison diagram of the usage status of the forearm training handle of this application and the training handle of the prior art;
[0049] Figure 9 This is a schematic diagram of a rotation and translation mechanism provided in one embodiment of this application. Detailed Implementation
[0050] To make the objectives, technical solutions, and advantages of this application clearer, the following detailed description is provided in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the scope of this application.
[0051] To facilitate understanding of the invention, preferred embodiments are shown in the accompanying drawings, which include various specific details to aid this understanding, but these details should be considered merely exemplary. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein. Accordingly, those skilled in the art will recognize that variations and modifications can be made to the various embodiments described herein without departing from the scope of the invention as defined by the appended claims. Furthermore, descriptions of well-known functions and constructions may be omitted for clarity and brevity.
[0052] It will be apparent to those skilled in the art that the following description of various embodiments of the invention is provided for illustrative purposes only and is not intended to limit the invention as defined by the appended claims.
[0053] refer to Figures 1-4 This application provides a postoperative hand joint movement therapy system, comprising:
[0054] Chassis 2;
[0055] Bracket 1 is used to support the forearm;
[0056] A rotary drive mechanism, located in the chassis, is used to provide rotary driving force;
[0057] The rotary translation mechanism 6a is spaced apart from the bracket 1 and detachably connected to the rotary drive mechanism, so that it rotates at a preset first stage angle α under the driving action of the rotary drive mechanism and reaches position A, forming a first stage arc trajectory.
[0058] Furthermore, the rotating translation mechanism 6a has a sliding adjustment component 6a-1 on the side away from the bracket 1. When the rotating translation mechanism 6a rotates beyond the preset first stage angle α and is in the second stage, the sliding adjustment component 6a-1 is configured to be driven to translate in the direction close to the rotation axis 6a-2 of the rotating translation mechanism 6a to form an involute trajectory and reach the position B of the second stage.
[0059] The trajectory of the first stage and the trajectory of the second stage cover the trajectory envelope of the natural movement of the target hand joint.
[0060] The positioning training component 6b is connected to the sliding adjustment component 6a-1 and is used to position the target hand joint that needs to be trained.
[0061] Hand flexion and extension include continuous movements of the metacarpophalangeal and interphalangeal joints, as well as movements of the thumb joint, forearm internal and external rotation, and radial and ulnar deviation of the palm. The inventors discovered that during hand joint training exercises, only a portion of the movements follow a standard circular trajectory. For different hand joints, the trajectory becomes non-standard when the joint moves to a certain angle. Adapting to the free movement trajectories of different joint parts presents a significant challenge to hand motor control.
[0062] Specifically, target hand joints, such as finger joints, form different natural motion trajectories when performing different movements. These different natural motion trajectories encompass a trajectory area. To cover this trajectory area, this application designs a system motion trajectory, namely, the motion trajectory of the positioning training component 6b consists of two parts: an arc trajectory and an involute trajectory. In the first stage, with a preset first stage angle α, an arc motion is performed through rotation; in the second stage, the motion trajectory resembles an involute. This application includes two motion trajectory segments, the first stage and the second stage, which has been verified to theoretically approximate the natural trajectory of the joint. The designed motion trajectory can cover the trajectory area encompassed by all the natural motion trajectories formed by the target hand joints, such as finger joints, when performing different movements. That is, regardless of how the patient's hand joint moves, the trajectory of this embodiment can cover it, and the safety of the connection between the device and the patient can also be guaranteed.
[0063] During operation, the forearm is placed on the bracket 1, and the joint to be exercised is placed on the positioning training component 6b. During forward motion training, the rotary drive mechanism is activated to provide rotary drive force, which drives the rotary translation mechanism 6a to rotate along the arc trajectory to the preset first stage angle α (e.g., 80°), reaching position A. When the rotation exceeds the preset first stage angle, it enters the second stage, which drives the sliding adjustment component 6a-1 on the rotary translation mechanism 6a to translate in the direction close to the rotation axis 6a-2 while rotating, reaching position B.
[0064] The rotation and translation mechanism 6a is a mechanism in the training component. The rotation and translation mechanism 6a itself can rotate around the rotation axis 6a-2 by a first stage angle α (e.g., 80°) to reach position A. When the rotation exceeds the preset first stage angle, the sliding adjustment component 6a-1 of the rotation and translation mechanism 6a is actively driven to rotate while sliding along the radial direction of the rotation axis 6a-2 toward the direction closer to the rotation axis 6a-2. The total movement trajectory includes two stages, which is conducive to corresponding and matching the natural flexion and extension movement trajectory of the human hand joint.
[0065] One end of the positioning training component 6b is mounted on the sliding adjustment component 6a-1 of the rotation and translation mechanism 6a, and the other end is connected to different joints of the patient, driving the patient's hand and wrist joints to perform continuous flexion and extension movements. The movement trajectory of the connected sliding adjustment component 6a-1 and the positioning training component 6b consists of two segments: a circular arc trajectory in the first stage and a composite movement trajectory in the second stage (wherein the composite movement trajectory in the second stage runs according to the trajectory of Archimedes' involute contraction), which is conducive to matching the theoretical natural movement trajectory of the joint.
[0066] The hand joint rehabilitation training robot of this invention strictly controls limb fixation, force points, and movement trajectories during use, ensuring that the passive joint movement curve conforms to the natural movement trajectory of the hand joint. For complex joint movements, it innovatively adopts a design concept that incorporates the direction of force and a two-stage trajectory, allowing the hand to bend to a normal angle, while ensuring patient comfort and painlessness throughout the entire process.
[0067] Early postoperative exercise training that conforms to the physiological curve allows patients to perform joint movements within a painless range, accelerating the recovery process. This avoids unnecessary medical accidents caused by exercise training that does not conform to the physiological curve, such as significant postoperative joint swelling, increased drainage, and in severe cases, loosening of the implanted prosthesis or wound dehiscence.
[0068] This invention combines a rotating translation mechanism 6a, a positioning training component 6b for different joint parts, and a variable bracket 1 installation position. It also allows for the selection of different preset first-stage angles α based on the target hand joint parts. This invention can be used for various training exercises, such as interphalangeal joint training, thumb joint training, metacarpophalangeal joint training, wrist joint training, compound fist clenching training, radial and ulnar lateral deviation training, forearm training, and wrist-palm compound training. It is flexible in use and highly functional.
[0069] For detailed training methods for different body parts, please see the following content.
[0070] Taking the finger joints as an example, this application will be described in detail as follows: The applicant has conducted a tracking study on the natural movement trajectory of finger joint flexion and extension, as detailed in [link to study]. Figure 3 The movement trajectory of the training components needs to cover Figure 3 The area shown is secure, ensuring a safe connection with the patient. Taking a finger joint as an example, the flexion-extension of each hand joint consists of the combined movements of three joints: the distal interphalangeal joint A, the proximal interphalangeal joint B, and the metacarpophalangeal joint C. Due to differences in the location of the injury and the degree of stiffness, the order of rotation of the three joints varies, resulting in different fingertip movement trajectories. Figure 3The continuous schematic diagrams a, 3b, and 3c represent the trajectory of the joint movements starting from 0° horizontally, sequentially from the distal interphalangeal joint, the proximal interphalangeal joint to the metacarpophalangeal joint, and record them to form trajectory line H. Trajectory line H consists of three arc segments, that is, each of the segments is an arc. Figure 3 The consecutive diagrams d, 3e, and 3f illustrate the trajectory of joint movements starting from a horizontal 0° angle and proceeding sequentially from the metacarpophalangeal joint, proximal interphalangeal joint, to the distal interphalangeal joint, forming trajectory line K. Trajectory line K consists of an arc and an involute. Besides the two types of movement mentioned above, the trajectories of other joint movements are all enclosed within the area bounded by trajectory lines H and K.
[0071] Therefore, a motion trajectory needs to be designed that can cover trajectory line H, trajectory line K, and all other trajectory forms enveloped by H and K. Specifically, the motion trajectory design of the positioning training component 6b is as follows: First, the applicant discovered through research that when used for thumb or interphalangeal joint training, the thumb or interphalangeal joint can rotate downwards from a horizontal position along a circular trajectory with a maximum rotation angle a1 (approximately 80°, 78°-82°). Therefore, in the first stage, the transmission rod 17 can be rotated in space from 0° horizontally to a1, for example, 80° via the sliding adjustment component 6a-1 of the driving action mechanism 6a, generating a circular arc trajectory with a fixed radius. Figure 4 a) and reach position A; then, in the second stage when the rotation angle exceeds 80°, the sliding adjustment component 6a-1 is driven to move toward the direction closer to the rotation axis 6a-2. Based on Archimedes' involute principle, the sliding adjustment component 6a-1 achieves a displacement radially toward the rotation axis 6a-2 and gradually moves closer to the rotation axis 6a-2. Figure 4 b) The displacement trajectory contracts within an angle range b1 (98°-102°) along the tangent of the base circle. For example, after contracting by 100°, it reaches position B at 180°. The expansion and contraction of the involute trajectory can be achieved by resetting the elastic element. Figure 4 c shows the entire motion trajectory of the sliding adjustment component 6a-1 when the rotary drive mechanism drives it to rotate 180°.
[0072] This embodiment has the following advantages compared to the prior art:
[0073] (1) The motion trajectory of the positioning training component 6b consists of two parts: a circular arc trajectory and an involute trajectory. In the first stage within the rotation angle a1, circular arc motion is performed by rotation; when the rotation angle is greater than a1, the motion trajectory is similar to an involute. This application includes two motion trajectories, the first stage and the second stage, which theoretically approximate the natural trajectory of the joint. The designed motion trajectory can cover the range encompassed by the natural motion trajectory lines H and K in the above two extreme cases. That is, no matter how the patient's hand joint moves, the trajectory of the device in this embodiment can be covered, and the safety of the connection between the device and the patient can also be guaranteed. It is worth noting that the above description of tracking and recording the natural motion trajectory and the training system design trajectory is based on the finger joint as an example. When other joints are selected as the target hand joint, the above concept is also applicable.
[0074] When used for thumb or interphalangeal joint training, the thumb or interphalangeal joint starts from a horizontal position and moves downwards. The applicant believes that the motion trajectory designed in this application consists of two segments: a circular arc trajectory and an involute trajectory. Following this trajectory theoretically helps to approximate the natural motion trajectory and physiological curve. Existing passive movements that do not conform to the physiological curve, and incorrect force direction, can interfere with the rolling-sliding of the joint, causing excessive load on the joint surfaces, compressing the articular cartilage, and even leading to postoperative joint swelling and increased drainage. In the long term, this can also cause damage to the joint surfaces. For joints with high joint surface congruence, it may also lead to symptoms such as joint swelling, ossification, and arthritis. This embodiment overcomes the above problems, helping to make the finger joint movements closer to the natural motion trajectory and reducing damage to the finger joints during training.
[0075] The device described in this application can effectively apply external force to stiff finger joints, simultaneously maintaining the flexion position of the proximal and distal interphalangeal joints, and gently stretching the metacarpophalangeal joints to straightness, resulting in significant training and rehabilitation effects.
[0076] Based on the above embodiments, the applicant further discovered that the natural physiological movement trajectory of actual hand joints is diverse, and although it is close to the standard movement trajectory of the sliding adjustment component 6a-1 as a whole, it is not synchronous. Therefore, in order to avoid the device restricting joint movement or even directly applying strong impact force to the joints during system operation, improve the effectiveness and safety of training movements, and enable the finger joints to always move along the natural physiological movement trajectory while bearing the driving force, refer to Figure 2 and Figure 5 In some embodiments, a positioning training component 6b is provided that better matches the natural movement trajectory of finger joints, specifically including:
[0077] An adjusting belt 72, wherein multiple connection points 72a are distributed along the length direction of the adjusting belt 72;
[0078] The finger sleeve 71 can be selectively connected to any connection point 72a on the adjustment band 72, and the finger sleeve 71 is slidably sleeved on the rotary position compensation drive rod 18;
[0079] The fixing strap 76 is used to fix the finger sleeve 71 to the connection point 72a;
[0080] The transmission rod 17 is fixedly connected to the side of the sliding adjustment component 6a-1 and is used to transmit rotational circular motion;
[0081] The rotary position compensation drive rod 18 is rotatably connected to the transmission rod 17 and is perpendicular to the axis of the rotation axis 6a-2 of the rotary support plate 37.
[0082] In this embodiment, the transmission rod 17 is a connector between the sliding adjustment component 6a-1 and the rotary position compensation drive rod 18, used to transmit the movement of the sliding adjustment component 6a-1 to the rotary position compensation drive rod 18, and then to the finger connected to the rotary position compensation drive rod 18.
[0083] In this embodiment, the rotary position compensation drive rod 18 can rotate freely 360° relative to the transmission rod 17; the finger sleeve 71 is used to connect the patient's finger and can slide freely along the rotary position compensation drive rod 18 to adapt to the continuous change in the distance between the finger sleeve 71 and the transmission rod 17 during movement. Through structural fit, it can adapt to changes in the spatial direction of the finger sleeve and the continuous change in the distance between the finger sleeve and the palm, thereby adapting to the continuous changes in the distance and direction of the fingertip to the palm during hand joint flexion and extension, ensuring the safety of the connection between the training component and the patient.
[0084] Specifically, such as Figure 4 d and Figure 2 , Figure 5 When used for thumb or interphalangeal joint training, the finger sleeve 71 is adjusted to the connection point 72a on the adjustment strap 72, which corresponds to the finger part to be trained; the finger sleeve 71 is fixed to the connection point using the fixing strap 76; the rotary position compensation drive rod 18 is passed through the finger sleeve 71 (the finger sleeve can slide along the rotary position compensation drive rod 18, which provides support and guidance for the sliding of the finger sleeve).
[0085] During training, taking 80° as an example, the palm joint is placed on the hand support rod 16, and the fingers are inserted into the finger sleeves 71. The rotary drive mechanism provides rotary drive force, which drives the rotary translation mechanism 6a to rotate 80° as a whole. When it exceeds 80°, the sliding adjustment component 6a-1 of the rotary translation mechanism 6a drives the transmission rod 17 to rotate in space and translate at a preset speed. At the same time, the rotary position compensation drive rod 18 and the finger sleeves 71 push the finger joint to move.
[0086] As mentioned above, the natural physiological movement trajectory of the hand joint is not synchronized with the standard movement trajectory of the sliding adjustment component 6a-1 as a whole. To avoid restricting joint movement or even directly applying strong impact force to the joint during system operation, and to ensure the effectiveness and safety of training movements, such as... Figure 4 Figure e shows the initial state of the finger joint being driven by the sliding adjustment component 6a-1 to perform flexion and extension training movements. Since the finger sleeve 71 can slide freely along the rotational position compensation drive rod 18, and the rotational position compensation drive rod 18 can rotate flexibly relative to the transmission rod 17, when the finger joint is pushed by the sliding adjustment component 6a-1 to perform movements, the rotation of the rotational position compensation drive rod 18 and the sliding of the finger sleeve 71 form a buffer mechanism. This mechanism can compensate for the incomplete synchronization between the natural movement trajectory of the hand joint and the overall standard movement trajectory of the sliding adjustment component 6a-1 (the standard movement trajectory is constant). This ensures that the joint can still move according to its own physiological trajectory when being driven, and avoids the direct impact of the device on the joint during movement, thus ensuring the safety of the connection between the patient's body and the positioning training component 6b.
[0087] like Figure 4 Figure f shows a schematic diagram of the state changes of the interphalangeal joint being driven by the sliding adjustment component 6a-1 to perform flexion and extension training movements. During finger flexion and extension training, the spatial angle direction of the fingertip (finger sleeve 71) will change. At this time, the free and flexible rotation of the rotary position compensation drive rod 18 relative to the transmission rod 17 can serve as a buffer for direction adjustment, providing adaptive buffer compensation for the adjustment of the fingertip (finger sleeve 71) direction. Moreover, during finger flexion and extension training, the distance from the fingertip to the palm will also change uncertainly. At this time, the free sliding of the finger sleeve 71 along the rotary position compensation drive rod 18 can serve as a buffer for this distance adjustment, providing adaptive buffer compensation for the real-time change of the distance from the fingertip to the palm. This adjustment and compensation can then be adjusted to adapt to the formation of the actual physiological movement trajectory, achieving direction and distance compensation, so that the designed movement trajectory of the positioning training component 6b can adapt to the natural movement trajectory of all hand joints within the envelope range between H and K.
[0088] This embodiment has the following advantages compared to the prior art:
[0089] The design incorporates a mechanical linkage mechanism including a finger sleeve 71, an adjustment strap 72, a fixing strap 76, a rotary position compensation drive rod 18, and a transmission rod 17. Since the finger sleeve 71 can slide freely along the rotary position compensation drive rod 18, and the rotary position compensation drive rod 18 can rotate flexibly relative to the transmission rod 17, when the finger joint is pushed by the sliding adjustment component 6a-1 to perform an action, the rotation of the rotary position compensation drive rod 18 and the sliding of the finger sleeve 71 along the length of the rotary position compensation drive rod 18 form a buffer adaptation mechanism. This mechanism can compensate for and adjust when the natural movement trajectory of the hand joint is not completely synchronized with the overall standard movement trajectory of the sliding adjustment component 6a-1 (the standard movement trajectory is always constant). This ensures that the joint can still move freely according to its own physiological trajectory when forced to flex and extend, thereby avoiding direct impact from the device during joint movement and ensuring training comfort and the safety of the connection between the patient's body and the positioning training component 6b.
[0090] During training, the spatial angle of the fingertips and the distance from the fingertips to the palm undergo continuous and uncertain changes. The free sliding of the finger sleeve 71 along the rotational position compensation drive rod 18 provides adjustment support for these changes, offering adaptive buffering support to compensate for real-time variations in the fingertip-palm distance. Thus, the buffering mechanism, composed of rotation and sliding mechanisms, dynamically and adaptively connects and compensates with the device, helping to adapt to the flexible and continuous rotation of the fingers during flexion and extension of the hand joints and the continuous changes in the distance from the fingertips to the palm. This allows for dynamic adjustment when the natural physiological movement trajectory of the fingertips and hand joints is not completely synchronized with the movement trajectory of the training components, enabling flexible rotational changes of the hand joints during flexion and extension, thus avoiding injury to the patient. Furthermore, the device of this application can effectively apply external force to stiff finger joints while maintaining the flexion position of the proximal and distal interphalangeal joints, gently stretching the metacarpophalangeal joints to straightness, resulting in significant training and rehabilitation effects.
[0091] refer to Figures 1-2 In some embodiments, when used for interphalangeal joint training, the length direction of the transmission rod 17 intersects with the sliding direction of the sliding adjustment component 6a-1;
[0092] There are two or more rotary position compensation drive rods 18, which are arranged at intervals along the length of the transmission rod 17, and each rotary position compensation drive rod 18 is rotatably connected to the transmission rod 17.
[0093] Specifically, there are two or more rotary position compensation drive rods 18 to accommodate multiple fingers. Each rotary position compensation drive rod 18 is rotatably connected to the transmission rod 17, and each rotary position compensation drive rod 18 is slidably fitted with a finger sleeve 71. Thus, multiple fingers can achieve the same training effect when performing interphalangeal joint training, and the comfort and safety of each finger can be guaranteed.
[0094] refer to Figure 5 In some embodiments, the positioning training component 6b further includes:
[0095] Palm block 74, connected to the adjustment belt, is used to position the palm.
[0096] The palm strap 73 is connected to the palm block 74 and is used to bind the palm to the palm block 74.
[0097] A wristband 75 is connected to the palm block 74 and is used to bind the wrist to the palm block 74.
[0098] Specifically, before training, the palm can be placed on the palm block 74. Since the palm block 74 is connected to the adjustment strap, the position of the palm can be positioned. The palm strap 73 and wrist strap 75 respectively bind the palm and wrist to the palm block 74, thus forming a finger joint training glove, which helps to ensure the stability of the hand position during training and avoids the hand slipping during exercise and causing safety accidents.
[0099] refer to Figures 1-2 In some embodiments, a scale disk 13 is also included, which is coaxially arranged with the rotating shaft 6a-2; the scale disk 13 has rotating scales 10 distributed around its surface, and multiple rotation limit switches 9 are provided on the circumference of the scale disk 13.
[0100] Specifically, the scale 10 is arranged around the scale disc 13 to intuitively display the angle of joint movement training; the rotation limit switch 9 can preset the rotation angle range according to different training parts, and control the reduction motor 23 to stop rotating when the preset first stage angle position is reached, so as to avoid excessive rotation and ensure safe use.
[0101] It is worth pointing out that, for reference Figure 1When used for thumb joint training, one rotary position compensation drive rod 18 is sufficient. The training method is the same as the interphalangeal joint training method described above, except that the finger sleeve 71 is used to fix the thumb, and the rotary position compensation drive rod 18 and hand support rod 16 are designed to be shorter. During training, taking 80° as an example, the palm joint is placed on the hand support rod 16, the thumb is inserted into the finger sleeve 71, and the rotary drive mechanism provides rotary driving force, driving the rotary translation mechanism 6a to rotate 80° as a whole; when it exceeds 80°, the sliding adjustment component 6a-1 of the rotary translation mechanism 6a drives the transmission rod 17 to rotate in space and translate at a preset speed. At the same time, the rotary position compensation drive rod 18 and the finger sleeve 71 push the thumb joint to perform flexion and extension training movements. During this process, the finger sleeve 71 can adaptively slide along the rotary position compensation drive rod 18, and the rotary position compensation drive rod 18... The 8 can rotate flexibly in space relative to the transmission rod 17. Therefore, when the thumb joint is pushed by the sliding adjustment component 6a-1 to make a movement, the rotation of the rotational position compensation drive rod 18 and the sliding of the finger sleeve 71 form a buffer mechanism. It can compensate and adjust when the natural movement trajectory of the thumb joint is not completely synchronized with the standard movement trajectory of the sliding adjustment component 6a-1 (the standard movement trajectory is constant). This ensures that the joint can still move according to its own physiological trajectory when it is driven, and avoids the direct impact of the device when the joint moves, thus ensuring the safety of the connection between the patient's body and the positioning training component 6b.
[0102] During thumb flexion and extension training, the spatial angle of the fingertip (finger sleeve 71) will change. At this time, the free and flexible rotation of the rotary position compensation drive rod 18 relative to the transmission rod 17 can serve as a buffer for directional adjustment, providing adaptive buffer compensation for the adjustment of the thumb tip (finger sleeve 71) direction. Moreover, during thumb flexion and extension training, the distance from the thumb tip to the palm will also change uncertainly. At this time, the free sliding of the finger sleeve 71 along the rotary position compensation drive rod 18 can serve as a buffer for this distance adjustment, providing adaptive buffer compensation for the real-time change of the distance from the fingertip to the palm. This adjustment and compensation can then be adjusted to adapt to the formation of the actual physiological movement trajectory, achieving directional and distance compensation. This allows the designed movement trajectory of the positioning training component 6b to adapt to the natural movement trajectory of all hand joints within the envelope between H and K.
[0103] In addition, this embodiment can achieve at least the same effect as the above-described interphalangeal joint training, as detailed in the above description of interphalangeal joint training, which will not be repeated here.
[0104] refer to Figures 6-7 In some embodiments, the base 11 further includes a plug-in interface located below the rotating shaft 6a-2 for inserting the bottom support rod 1d and making the central axis of the bracket 1 parallel to the rotating shaft 6a-2;
[0105] It also includes a forearm training handle 6c, which is connected to the rotary drive mechanism; the forearm training handle 6c includes a bracket, a rotating handshake 6c-2 and a strap 6c-3. The bracket is connected to the rotary drive mechanism and includes a long side 6c-1 and a short side 6c-4. The two ends of the rotating shaft 6c-2 are respectively connected to the ends of the long side 6c-1 and the short side 6c-4. The strap 6c-3 fits against the back of the hand and cooperates with the rotating handshake 6c-2 to fix the hand. The short side 6c-4 is configured near the web of the hand.
[0106] Specifically, the forearm training handle 6c is connected to the rotary drive mechanism, and the bottom support rod 1d is then inserted into the connector. At this time, the central axis of the bracket 1 is parallel to the rotation axis 6a-2. The forearm is placed on the bracket 1, and the forearm training handle 6c is held. After the rotary drive mechanism is activated, it provides rotary driving force, causing the forearm training handle 6c to rotate. The thumb at the base of the hand is positioned on the short side, and the training hand grips the rotation axis 6C-2. The strap 6C-3 is tightened. When the rotary drive mechanism rotates, the rotation axis 6C-2 rotates, thereby pushing the entire palm for external rotation training. When the rotary drive mechanism rotates in the opposite direction, the strap 6C-3 pushes the back of the hand for internal rotation training. This expands the functionality of this application and can be applied to the training of more arm joints.
[0107] refer to Figure 8 After the training hand grips the rotation axis 6c-2 of the forearm training handle 6c, compared to the rotation axis 6d-1 of the existing training handle 6d, the short side 6c-4 is configured closer to the web of the hand, and the entire rotation axis 6c-2 is closer to the center of the palm. During forearm supination training, the rotation axis 6c-2 can act on the entire metacarpal bone, thereby effectively pushing the entire palm for training.
[0108] This application also provides an automatic control method for a postoperative hand joint motion therapy system, including:
[0109] The system acquires information about the target hand joints to be trained, for example by placing image sensors or other devices on the side of the system to collect image information of the positioning training components and compares it with images stored in the system. The system automatically identifies the type of positioning training component (the rotating position compensation drive rod 18 has one or four components) and automatically identifies the corresponding target hand joints to be trained (interphalangeal joints or thumb joints).
[0110] Based on the joint information, the target motion mode is switched. The target motion mode has pre-stored specific parameter values of the first stage angle α, movement speed and position A and position B. Different target motion modes correspond to the corresponding positioning training components and target hand joints.
[0111] Based on the target motion mode, the rotary drive mechanism is activated to provide rotary driving force, and the sliding adjustment component 6a-1 is rotated by a preset first stage angle α to form an arc trajectory.
[0112] And, after being driven to reach the preset first stage angle α, the sliding adjustment component 6a-1 is controlled to rotate while translating along the direction close to the rotation axis 6a-2, reaching the second stage position B to form an involute trajectory.
[0113] As the positioning training component 6b moves along with the sliding adjustment component 6a-1, it drives the target hand joint to move, and the movement trajectory includes an arc in the first stage and an involute in the second stage.
[0114] refer to Figure 9 In some embodiments, the rotation and translation mechanism 6a includes:
[0115] The collar 33 is sleeved on the rotary drive mechanism and can rotate with the rotary drive mechanism;
[0116] The hand support rod 16 is connected to the bushing via the swing disk 4 and rotates with the bushing to support the hand;
[0117] The rotating support plate 37 is connected to the collar 33;
[0118] The sliding adjustment component 6a-1 is slidably connected to the surface of the rotating support plate 37 and is driven to slide relative to the surface of the rotating support plate 37. The sliding direction of the sliding adjustment component 6a-1 is perpendicular to the axial direction of the rotation axis 6a-2 of the rotating support plate 37.
[0119] Elastic element 35 is connected between the end of the rotating support plate 37 near the bracket 1 and the sliding adjustment member 6a-1, and is configured to be compressed and store potential energy when the sliding adjustment member 6a-1 moves.
[0120] Specifically, the hand support rod 16 is used to support the hand during training to prevent limb injury due to unstable hand position during training.
[0121] Place the forearm on the bracket 1 and the palm on the hand support rod 16. Place the joint to be exercised on the positioning training component 6b. After the rotary drive mechanism is activated, it provides rotary driving force, which drives the hand support rod 16, the rotating support plate 37, and the sliding adjustment component 6a-1 to rotate through the collar 33. When the angle exceeds the preset first stage angle α, the power device drives the sliding adjustment component 6a-1 to translate in the direction close to the rotation axis 6a-2 (in the radial direction of the rotation axis 6a-2) while rotating. The sliding adjustment component 6a-1 undergoes a compound motion and generates an Archimedean involute trajectory. The positioning training component 6b is installed on the sliding adjustment component 6a-1, and the other end is connected to a specific part of the patient's hand, which can drive the different joints of the patient's hand to perform continuous flexion and extension movements.
[0122] The elastic element 35 stores force and has a tendency to rebound during the movement of the sliding adjustment component 6a-1, which helps to promote the reciprocating motion of the joint in both directions. Furthermore, the elastic element 35 resets, thus enabling the expansion and contraction of the movement trajectory.
[0123] refer to Figure 9 In some embodiments, the rotation and translation mechanism 6a further includes a guide limiting rod 34, the length direction of which is perpendicular to the axial direction of the rotation axis 6a-2 of the rotation support plate, and the sliding adjustment component 6a-1 is sleeved on the guide limiting rod 34; the elastic element 35 is sleeved on the guide limiting rod 34, and the two ends of the elastic element 35 abut against the end of the rotation support plate 37 near the bracket 1 and the sliding adjustment component 6a-1, respectively.
[0124] Specifically, the guide limit rod 34 is used to guide the translation of the sliding adjustment component 6a-1 and the deformation direction of the elastic element 35, so as to avoid the reduction of the movement effect or even the creation of safety hazards due to the deviation of the movement direction of the sliding adjustment component 6a-1 during the movement.
[0125] refer to Figure 9 In some embodiments, the rotation and translation mechanism 6a further includes a cable 38 connecting the collar and the sliding adjustment component 6a-1. The cable 38 can limit the sliding adjustment component 6a-1, preventing it from moving excessively away from the rotation axis 6a-2 and increasing safety risks.
[0126] refer to Figure 9 In some embodiments, the sliding adjustment component 6a-1 includes:
[0127] The movable body 36 is slidably connected to the surface of the rotating support plate 37 via a guide rail, and the sliding direction of the movable body 36 is perpendicular to the axis of the rotating shaft 6a-2;
[0128] The motion connection platform 14 is fixedly connected to the moving body 36 by bolts, and the motion connection platform 14 is provided with a connection hole 14a for connecting the positioning training component 6b.
[0129] Specifically, the motion connection platform 14 and the moving body 36 are fixedly connected by bolts, which makes it easy to replace the motion connection platform 14 of different specifications to meet the training needs of patients with different physiques; the motion connection platform 14 may be provided with connection holes 14a at the ends near the rotation axis 6a-2 and away from the rotation axis 6a-2, respectively, for connecting different types of positioning training components 6b at different positions.
[0130] In some embodiments, the rotary drive mechanism includes:
[0131] Gear motor;
[0132] The rotary output shaft is connected to the main shaft of the geared motor via a bushing and is mounted on the chassis via bearings.
[0133] Specifically, the control unit can process control signals such as angle range and running speed into output execution signals for the geared motor, which is the actuator for the angle range and average angular velocity. The main shaft of the geared motor is connected to the rotary output shaft through a bushing, and the rotary output shaft is detachably connected to the rotary translation mechanism 6a. Thus, when the geared motor starts, it can drive the rotary output shaft and the rotary translation mechanism 6a to rotate, thereby achieving rotary motion control.
[0134] In some embodiments, a limiting rod is fixedly connected to the outer circumference of the bushing. This is used to prevent the bushing, the rotary output shaft, and the rotary translation mechanism from rotating excessively, thereby avoiding safety accidents.
[0135] refer to Figure 2 In some embodiments, a touch unit 2a is also included, connected to the rotary drive mechanism, and the touch unit 2a stores control parameters. System control parameters are input through the HMI touch unit 2a, such as preset first-stage angle α, running speed, safety protection level, and extended parameters corresponding to different training areas. Different positioning training components 6b are components that directly contact the patient, and their movement trajectories simulate the natural flexion and extension trajectories of human hand and wrist joints. Therefore, they need to be set within a safe range of motion to safely drive the patient's metacarpophalangeal joints, wrist joints, and wrist-palm composite passive movements.
[0136] The translation of the sliding adjustment component 6a-1 can be driven by a power drive component connected to it, including but not limited to electric or hydraulic rods.
[0137] refer to Figure 1 In some embodiments, the bracket 1 includes:
[0138] Base 11;
[0139] The bottom support rod 1d is movably connected to the base 11 via connecting bolt 1c;
[0140] The telescopic support rod 1f is hinged to the bottom support rod 1d through the gear meshing point 1e;
[0141] The tray 1a is hinged to the telescopic support rod 1f via a gear engagement point 1b.
[0142] Specifically, the vertical tilt angle of the tray 1a can be adjusted by adjusting the gear meshing point 1b, the tilt angle of the telescopic support rod 1f can be changed by adjusting the gear meshing point 1e, thereby changing the height of the tray 1a, and the spatial distance between the tray 1a and the rotation and translation mechanism 6a can be adjusted by adjusting the telescopic support rod 1f. Thus, the position of the bracket 1 can be adjusted according to the length of the patient's arm, so that the patient is in the most comfortable state when connected to the equipment.
[0143] Throughout the specification and claims of this application, the words “comprising” and “including,” as well as variations thereof, such as “comprising of” and “including,” mean “including but not limited to,” and are not intended to exclude other components, elements, or steps. Features, elements, or characteristics described in connection with a particular aspect, embodiment, or example of the invention are to be understood as applicable to any other aspect, embodiment, or example described herein, unless incompatible therewith.
[0144] It should be understood that the singular forms “a,” “an,” and “the” include plural references unless the context explicitly specifies otherwise. The expressions “comprising” and / or “may comprise” as used in this invention are intended to indicate the presence of a corresponding function, operation, or element, and are not intended to limit the presence of one or more functions, operations, and / or elements. Furthermore, in this invention, the terms “comprising” and / or “having” are intended to indicate the presence of the features, quantities, operations, elements, and components disclosed in the applications, or combinations thereof. Therefore, the terms “comprising” and / or “having” should be understood as implying the additional possibility of one or more other features, quantities, operations, elements, and components, or combinations thereof.
[0145] In this invention, the expression "or" includes any or all combinations of the words listed together. For example, "A or B" can include either A or B, or it can include both A and B.
[0146] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. It should also be understood that terms (such as those defined in common dictionaries) should be interpreted as having the meaning consistent with the relevant field and the context of this specification, and should not be interpreted in an idealized or overly formal sense unless expressly defined herein. The term “and / or” as used herein includes any and all combinations of one or more of the associated listed items.
[0147] The embodiments described above are merely illustrative of several implementation methods of this application, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the invention patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this application, and these all fall within the protection scope of this application. Therefore, the protection scope of this patent application should be determined by the appended claims.
Claims
1. A finger joint motion positioning training component, characterized in that, include: The transmission rod is configured to be fixedly connected to the side of the sliding adjustment component of the rotational translation mechanism, and is used to transmit rotational circular motion; A rotary position compensation drive rod is rotatably connected to the transmission rod, and the rotary position compensation drive rod is perpendicular to the axis of rotation of the rotary translation mechanism; An adjustment belt, wherein multiple connection points are distributed along the length direction of the adjustment belt; The finger sleeve can be selectively connected to any connection point on the adjustment band to correspond to and fix the finger part to be trained; and the finger sleeve is slidably sleeved on the rotary position compensation drive rod. A fixing strap is used to secure the finger sleeve to the connection point.
2. The finger joint motion positioning training component according to claim 1, characterized in that, The length direction of the transmission rod intersects with the sliding direction of the sliding adjustment component; The rotary position compensation drive rod has one to four rods, which are arranged at intervals along the length of the transmission rod, and each rotary position compensation drive rod is rotatably connected to the transmission rod.
3. The finger joint motion positioning training component according to claim 1, characterized in that, The positioning training component further includes: The palm block, connected to the adjustment belt, is used to position the palm. A palm strap, connected to the palm block, is used to bind the hand to the palm block; A wristband, connected to the palm block, is used to secure the wrist to the palm block.
4. A finger joint exercise training device, characterized in that, The finger joint motion positioning training component according to any one of claims 1-3 further includes: Bracket, used to support the forearm; A rotary drive mechanism is used to provide rotary driving force; A rotational translation mechanism is spaced apart from the bracket and connected to the rotary drive mechanism, so that it rotates at a preset first stage angle α under the driving action of the rotary drive mechanism and reaches position A, forming a first stage arc trajectory. Furthermore, the rotating translation mechanism has a sliding adjustment component on the side away from the bracket. When the rotating translation mechanism rotates beyond the preset first stage angle a1 and is in the second stage, the sliding adjustment component is configured to be driven to translate in a direction close to the rotation axis of the rotating translation mechanism to form an involute trajectory. The trajectory contracts by an angle b1 along the base circle tangent and reaches the position B of the second stage. Among them, the finger joints form different trajectories when they make different natural movements, and the different trajectory envelopes form trajectory regions. The trajectory of the first stage and the trajectory of the second stage cover the trajectory regions. The positioning training component is connected to the sliding adjustment component and is used for positioning training of finger joints.
5. The finger joint exercise training device according to claim 4, characterized in that, The transmission rod is synchronously driven by the sliding adjustment component. The transmission rod pushes the rotary position compensation drive rod, the finger sleeve, and the finger part to move. The finger sleeve slides along the rotary position compensation drive rod, while the rotary position compensation drive rod rotates relative to the transmission rod to compensate when the natural movement trajectory of the joint is not synchronized with the movement trajectory of the sliding adjustment component, so that the joint moves along its own natural movement trajectory.
6. The finger joint exercise training device according to claim 4, characterized in that, in, In the first stage, the sliding adjustment component of the drive mechanism drives the transmission rod to rotate in space to a1 = 78°-82°, generating an arc trajectory and reaching position A; in the second stage, the sliding adjustment component drives the transmission rod to move towards the direction closer to the rotation axis, and the displacement trajectory shrinks along the base circle tangent at an angle b1 = 98°-102°, reaching position B.
7. The finger joint exercise training device according to claim 4, characterized in that, The rotation and translation mechanism includes: A collar is fitted onto the rotary drive mechanism and can rotate with the rotary drive mechanism; A hand support rod is connected to the bushing and rotates with the bushing to support the hand. A rotating support plate is connected to the collar. A sliding adjustment component is slidably connected to the surface of the rotating support plate and is driven to slide relative to the surface of the rotating support plate. The sliding direction of the sliding adjustment component is perpendicular to the axial direction of the rotation axis of the rotating support plate. An elastic element is connected between the end of the rotating support plate near the bracket and the sliding adjustment component.
8. The finger joint exercise training device according to claim 7, characterized in that, The rotation and translation mechanism further includes a guide limiting rod, the length direction of which is perpendicular to the axial direction of the rotation axis of the rotation support plate, and the sliding adjustment component is sleeved on the guide limiting rod; The elastic element is sleeved on the guide limiting rod, and the two ends of the elastic element abut against the end of the rotating support plate near the bracket and the sliding adjustment component, respectively.
9. The finger joint exercise training device according to claim 1, characterized in that, The sliding adjustment component includes: The movable body is slidably connected to the surface of the rotating support plate via a guide rail, and the sliding direction of the movable body is perpendicular to the axis of the rotating shaft; The motion connection platform is fixedly connected to the moving body by bolts, and the motion connection platform is provided with connection holes for connecting positioning training components.