公开(公告)号：US11690773B2

公开(公告)日：2023-07-04

申请号：US16969198

申请日：2020-06-12

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Yiting Mo ,  Huanhuan Qin ,  Huijun Li ,  Baoguo Xu

IPC: A61H1/00 ,  A61H1/02

CPC classification number: A61H1/0274 ,  A61H2201/1207 ,  A61H2201/165 ,  A61H2201/1628 ,  A61H2201/1635 ,  A61H2201/1659 ,  A61H2201/5061

Abstract: A wearable upper limb rehabilitation training robot with precise force control includes a wearable belt, a multi-degree-of-freedom robot arm, and a control box. The robot is worn on the waist of a person by using a belt, and driven by active actuators, to implement active and passive rehabilitation training in such degrees of freedom as adduction/abduction/anteflexion/extension of left and right shoulder joints and anteflexion/extension of left and right elbow joints. In addition, a force/torque sensor is mounted on a tip of the robot arm, to obtain a force between the tip of the robot arm and the human hand during rehabilitation training as a feedback signal, to adjust an operating state of the robot, thereby realizing the precise force control during the rehabilitation training.

公开(公告)号：US11650117B2

公开(公告)日：2023-05-16

申请号：US16973690

申请日：2020-04-22

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Shuyan Yang ,  Baoguo Xu ,  Ming Wei ,  Chunhui Wang ,  Fan Li ,  Yuhua Yao ,  Yanjun Li ,  Suinan Zhang ,  Qiong Jin

IPC: G01L5/00 ,  G01L5/1627 ,  G01L1/22

CPC classification number: G01L5/1627 ,  G01L1/2262

Abstract: The present invention discloses a six-dimensional force sensor with high sensitivity and low inter-dimensional coupling, including a clockwise or counterclockwise swastika-shaped beam, vertical beams, a rectangular outer frame, and strain gauges; the clockwise or counterclockwise swastika-shaped beam includes a cross-shaped transverse beam and four rectangular transverse beams; a center of the cross-shaped transverse beam is provided with several force application holes used for applying forces and moments; four tail ends of the cross-shaped transverse beam are each connected to one of the rectangular transverse beams to form a clockwise or counterclockwise swastika-shaped structure; a top end of a vertical beam is connected to a tail end of a corresponding rectangular transverse beam, and bottom ends of the vertical beams are connected to the rectangular outer frame; and there are a plurality of strain gauges to form six groups of Wheatstone bridges that are respectively used for measuring an X-direction force, a Y-direction force, a Z-direction force, an X-direction moment, a Y-direction moment, and a Z-direction moment. Strain gauges for measuring the forces are all pasted on the cross-shaped transverse beam, strain gauges for measuring the X-direction moment and the Y-direction moment are all pasted on the four rectangular transverse beams, and strain gauges for measuring the Z-direction moment are all pasted on the four vertical beams. According to the present invention, the structure is simple, and inter-dimensional coupling is low while high sensitivity is ensured.

公开(公告)号：US11491071B2

公开(公告)日：2022-11-08

申请号：US16907182

申请日：2020-06-20

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Ke Shi ,  Hong Zeng ,  Huijun Li ,  Baoguo Xu ,  Xinyu Tang

IPC: A61H1/02 ,  A61B5/103 ,  A61B5/11 ,  A63B21/00 ,  A63B71/06 ,  G06F3/01

Abstract: A virtual scene interactive rehabilitation training robot based on a lower limb connecting rod model and force sense information and a control method thereof are disclosed. The thigh, calf and foot of a leg of a human body are equated to a three-connecting rod series-connected mechanical arm. A human body leg gravity compensation model is constructed. The leg posture of a patient is detected by Kinect. An interaction force between a limb of the patient and a rehabilitation robot is detected by a force sensor on the rehabilitation robot. Then, a progressive rehabilitation training method is designed for the model. According to a set weight reduction ratio, the motion of the rehabilitation robot is controlled by judging plantar force data.

公开(公告)号：US12064884B2

公开(公告)日：2024-08-20

申请号：US17774317

申请日：2022-01-06

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Jianwei Lai ,  Huijun Li ,  Hong Zeng ,  Baoguo Xu

IPC: B25J9/16

CPC classification number: B25J9/1692

Abstract: The present disclosure discloses an automated calibration system and calibration method for a flexible robot actuator. The calibration system includes a support frame. A visual positioning system, a pressure measuring system and a pneumatic pressure control system are respectively installed on the support frame. The visual positioning system is configured to measure a relative displacement and an angle between two ends of the flexible actuator. The pneumatic pressure control system is configured to charge air into an actuating end of the flexible actuator and measure an input pneumatic pressure of the flexible actuator. The pressure measuring system includes a pressure gauge installed on the support frame through a vertical axis motor system, and the flexible actuator to be calibrated installed on the support frame through a horizontal axis motor system and a rotating motor system. The rotating motor system is installed on the support frame through the horizontal axis motor system, the actuating end of the flexible actuator is fixed on the rotating motor system, and a free end of the flexible actuator is in contact with a measuring end of the pressure gauge to carry out pressure measurement. The calibration system is high in accuracy and simple to use.

公开(公告)号：US11771613B2

公开(公告)日：2023-10-03

申请号：US16970631

申请日：2020-08-18

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Yiting Mo ,  Huanhuan Qin ,  Huijun Li ,  Baoguo Xu

IPC: A61H1/02 ,  A63B21/00 ,  A63B23/12

CPC classification number: A61H1/0274 ,  A63B21/00178 ,  A63B23/12 ,  A61H1/0277 ,  A61H1/0281 ,  A61H2201/1207 ,  A61H2201/165 ,  A61H2201/1638 ,  A61H2201/1659 ,  A61H2201/5007 ,  A61H2201/5043 ,  A61H2201/5061 ,  A61H2201/5069 ,  A61H2230/625

Abstract: A robot system for active and passive upper limb rehabilitation training based on a force feedback technology includes a robot body and an active and passive training host computer system. Active and passive rehabilitation training may be performed at degrees of freedom such as adduction/abduction and flexion/extension of left and right shoulder joints, and flexion/extension of left and right elbow joints according to a condition of a patient. In a passive rehabilitation training mode, the robot body drives the upper limb of the patient to move according to a track specified by the host computer, to gradually restore a basic motion function of the upper limb. In an active rehabilitation training mode, the patient holds the tail ends of the robot body with both hands to interact with a rehabilitation training scene, and can feel real and accurate force feedback.

公开(公告)号：US11454560B2

公开(公告)日：2022-09-27

申请号：US16467032

申请日：2018-05-23

Applicant: Southeast University

Inventor： Aiguo Song ,  Mingxin Leng ,  Baoguo Xu ,  Huijun Li

IPC: G01L5/169 ,  G01B7/00 ,  G01L1/22 ,  G01R33/07 ,  B25J19/02 ,  G01D11/24

Abstract: A whisker sensor includes an upper circuit board, a lower circuit board, a flexible whisker, and a magnet. The magnet is fixed to the flexible whisker through a central through hole, and the location of the magnet changes with the swinging of the whisker; the upper and lower circuit boards are identical in shape and size, and are connected through an upright column. A circular hole is formed at the center of the upper circuit board, four Hall sensors are symmetrically distributed on the edge of the circular hole, and the displacement of the whisker in X and Y directions can be obtained by detecting the change in magnetic field generated by the change in location of the magnet; a contact sensor is mounted on the lower circuit board, and is connected to the whisker through a connecting piece, to detect displacement of the whisker in the Z direction.

公开(公告)号：US11016598B1

公开(公告)日：2021-05-25

申请号：US16768636

申请日：2018-05-23

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Mingxin Leng ,  Huijun Li ,  Hong Zeng ,  Baoguo Xu ,  Lifeng Zhu

IPC: G06F3/041 ,  G06F3/044 ,  G06F3/0354

Abstract: An artificial fingertip sliding tactile sensor includes a PVDF film, a rubber fingertip, a filling liquid, a sealing plug, a hydraulic sensor, a housing, an inner framework, and strain gauges. The rubber fingertip is a hemispherical cavity. The PVDF film is attached to the outside of the rubber fingertip. The sealing plug seals the rubber fingertip, and the hydraulic sensor is installed at the bottom of the sealing plug. The main body of the housing is a rigid cylindrical structure. The top of the housing is provided with a circular opening, and the bottom of the housing is a flange-like structure. Four circular through holes are uniformly distributed on the flange-like structure. The inner framework includes a cylindrical head, a vertical strain rod and a base. The strain gauges are respectively attached on four sides of the vertical strain rod and adjacent to the base.

公开(公告)号：US10959863B2

公开(公告)日：2021-03-30

申请号：US16475680

申请日：2018-05-23

Applicant: SOUTHEAST UNIVERSITY

Inventor： Aiguo Song ,  Xuhui Hu ,  Hong Zeng ,  Baoguo Xu ,  Huijun Li

IPC: A61F2/72 ,  G16H50/20 ,  A61F2/58 ,  G06F3/01 ,  A61F2/70

Abstract: The present invention discloses a multi-dimensional surface electromyogram signal prosthetic hand control method based on principal component analysis. The method comprises the following steps. Wear an armlet provided with a 24-channel array electromyography sensor to a front arm of a subject, and respectively wear five finger joint attitude sensors at a distal phalanx of a thumb and at middle phalanxes of remaining fingers of the subject. Perform independent bending and stretching training on the five fingers of the subject, and meanwhile, collect data of an array electromyography sensor and data of the finger joint attitude sensors. Decouple the data of the array electromyography sensor by principal component analysis to form a finger motion training set. Perform data fitting on the finger motion training set by a neural network method, and construct a finger continuous motion prediction model. Predict a current bending angle of the finger through the finger continuous motion model.

公开(公告)号：US12269161B2

公开(公告)日：2025-04-08

申请号：US17628753

申请日：2020-06-03

Applicant: Southeast University

Inventor： Aiguo Song ,  Xuhui Hu ,  Zhikai Wei ,  Huijun Li ,  Baoguo Xu ,  Hong Zeng

IPC: A61F2/68 ,  A61F2/72 ,  B25J9/16 ,  B60K6/365

Abstract: Provided are a multi-degree-of-freedom myoelectric artificial hand control system and a method for using same. The system comprises a robotic hand, a robotic wrist (2), a stump receiving cavity (1) and a data processor (3), wherein the robotic hand and the stump receiving cavity (1) are respectively mounted on two ends of the robotic wrist (2); a multi-channel myoelectric array electrode oversleeve, a control unit circuit board, and a battery are connected in the stump receiving cavity (1); and the other end of the control unit circuit board is connected to the robotic hand and the robotic wrist (2). The method for using the system comprises the following steps: (S1) a user wearing a multi-channel myoelectric array electrode oversleeve, and connecting a battery and a control unit circuit board; (S2) the user completing a gesture, collecting a surface electromyography signal and then uploading same to a data processor (3); (S3) the data processor (3) receiving the surface electromyography signal and inputting same into a neural network algorithm to generate a gesture prediction model; and (S4) the user controlling the multi-degree-of-freedom movement of the robotic wrist (2) and the robotic hand. By means of the system, continuous gestures and the gesture strength thereof can be identified, and multi-degree-of-freedom gestures can be made.

公开(公告)号：US12109162B2

公开(公告)日：2024-10-08

申请号：US17279608

申请日：2020-07-10

Applicant: Southeast University

Inventor： Huijun Li ,  Yunxia Ouyang ,  Aiguo Song

IPC: A61H1/02 ,  B33Y80/00

CPC classification number: A61H1/0288 ,  B33Y80/00 ,  A61H2201/149 ,  A61H2201/1638 ,  A61H2201/165

Abstract: A rope-driven soft hand function rehabilitation device includes four finger exoskeleton mechanisms, a thumb exoskeleton mechanism, and a soft rubber glove. An index-finger exoskeleton mechanism includes an index-finger distal phalanx loop, an index-finger middle phalanx loop, and an index-finger proximal phalanx loop which are mutually connected via a hinge structure. The thumb exoskeleton mechanism includes a thumb proximal phalanx loop and a thumb distal phalanx loop which are connected via a hinge structure. The rope is fastened to the hand function rehabilitation device via an aluminum sleeve which prevents the rope from slipping off during finger flexion/extension and abduction/adduction when the fingers are pulled by the rope at the palm and the hand back.