CN111938998A

CN111938998A - Knee joint rehabilitation robot

Info

Publication number: CN111938998A
Application number: CN202010950891.2A
Authority: CN
Inventors: 包倪荣; 杨凯; 韩雅慧; 陈万群
Original assignee: Nanjing Aitirui Precision Machinery Co ltd
Current assignee: Eastern Theater General Hospital of PLA
Priority date: 2020-09-11
Filing date: 2020-09-11
Publication date: 2020-11-17

Abstract

The invention discloses a knee joint rehabilitation robot, and relates to the technical field of medical rehabilitation equipment. The system comprises an MCU circuit, a power supply module, a human-computer interaction module, a stepping motor driving module, an ESP-M1 wireless module, a motor current detection module, a motor speed measurement module, a myoelectric current acquisition module and an HMI serial port touch screen; the ESP-M1 wireless module is used for connecting the HMI serial port touch screen with the MCU in a communication way through an RS-485 bus; the man-machine interaction module is used for visual interaction between a human and a machine and selection of a training mode. The rehabilitation strategy of the rehabilitation robot is selected in a visual human-computer interaction mode, and the patient directly selects three modes of passive training, active training and active impedance training through the touch display screen, so that the patient can finish the rehabilitation training without going out, the trouble of the patient going to a hospital for rehabilitation is avoided, the pain of the patient is relieved, and the medical cost is reduced.

Description

Knee joint rehabilitation robot

Technical Field

The invention belongs to the technical field of medical rehabilitation equipment, and particularly relates to a knee joint rehabilitation robot.

Background

Cerebral apoplexy is also called cerebrovascular accident or apoplexy, and is the sudden nerve function damage caused by cerebrovascular abnormality, including cerebral infarction, cerebral hemorrhage and subarachnoid hemorrhage. The main clinical manifestations are hemiplegia, visual impairment, aphasia and cognitive impairment. The stroke has the characteristics of high morbidity, high disability rate, high mortality rate and the like, and brings heavy burden to families and society. According to the relevant statistics, the following results show that: the number of patients suffering from cerebral apoplexy reaches 200 million in China every year, 700 million patients suffering from apoplexy survive at present, wherein 450 million patients lose labor force to different degrees or even cannot take care of themselves, and the disability rate reaches 75 percent. Meanwhile, patients who have suffered from stroke are also prone to relapse, and are aggravated once every relapse, so that effective measures need to be taken for prevention.

Related studies in recent years have shown that hemiplegia caused by stroke can be treated by rehabilitation using plasticity of the central nervous system of the human body. The reason is that nerve cells and tissues are necrotized after the stroke patient is ill, so that various hemiplegic symptoms of the patient are caused, the stem cells are easily regenerated cells, the transplanted stem cells can be self-distinguished and migrate to the injured nerve part, and the dead or injured nerve cells of the body are replaced through the cell replacement effect, so that the damaged nerve network is repaired. Therefore, for the cerebral apoplexy patient, the timely rehabilitation training can not only reduce the loss of central nerves and reduce the occurrence of complications, but also can restore the normal motor function early, remold the confidence of the patient and reduce the pressure of family life.

Patients with stroke have different treatment methods according to different symptoms and rehabilitation stages. There are several clinical treatments: physical therapy, operation therapy, speech therapy, psychological therapy and traditional therapy. Physical therapy includes motor therapy, including neuromuscular facilitation techniques (restoring brain's motor control of paralyzed limbs) such as brunstrom's technique, limb active motor control training, muscle stretching therapy, joint range of motion training, muscle strength training, balance training, weight loss training, standing and walking training, etc., and electrical therapy, including electronic biofeedback, electrotherapy, phototherapy, hydrotherapy, cold thermal therapy, acupuncture, oxygen therapy, vascular instruments, etc. The operation therapy aims at the dysfunction of the patient after the cerebral apoplexy and the difficulty in daily life activities, designs and selects some purposeful activities, and treats and trains the patient. The speech therapy aims at the patients with hearing disorder and aphasia, comprehensively applies a one-to-one or stimulation promotion method, improves the language understanding and expression ability, recovers the communication function of the patients, and creates conditions for returning to the society. Psychotherapy is a method of speaking, music or biofeedback, and is used for treating patients with psychology, spirit, emotion and behavior abnormality after stroke in a targeted way, so that positive psychology against diseases is encouraged to be established and strengthened. The traditional therapy uses traditional Chinese medicines, acupuncture and moxibustion, massage and other methods to achieve the functions of dredging channels and collaterals, balancing yin and yang, regulating blood and qi and coordinating internal organs. The stroke treatment method has certain application in clinic, but is mainly based on the exercise therapy of a patient assisted by a rehabilitation doctor, and is assisted by other treatment methods.

When assisting a patient to perform rehabilitation treatment, a rehabilitation doctor mainly assists the patient to complete a series of specific actions in a one-to-one mode by hands or by means of certain instruments, but the rehabilitation doctor has more limitations: firstly, the skill level of a rehabilitation doctor directly influences the training effect in the whole training process, and meanwhile, factors such as physical condition, emotion and the like of the rehabilitation doctor also have certain influence; secondly, for the stroke patient, the same actions are passively repeated, so that the initiative and the enthusiasm of the training are not easy to mobilize, and meanwhile, the stroke also easily causes language and cognitive dysfunction, so that inconvenience is caused to the communication between doctors and patients; finally, because of the large population base in China, many stroke patients who need rehabilitation are in need of rehabilitation, but the number of rehabilitation doctors is seriously insufficient, so that a large number of patients cannot be treated in time, and the best rehabilitation opportunity is missed.

The rehabilitation robot system is a new technology in the field of cerebral apoplexy rehabilitation, the original one-to-one relationship between doctors and patients is greatly improved due to the adoption of the rehabilitation robot system, and the patients who are not enough can also carry out rehabilitation training. The rehabilitation robot can form good complementation with a rehabilitation doctor, can release the rehabilitation doctor from heavy rehabilitation treatment, selects different types of rehabilitation robots according to the diseased symptoms of different patients, formulates different rehabilitation strategies and improves the working efficiency of the rehabilitation doctor. In addition, the rehabilitation robot can be compatible with advanced technologies in various fields, various novel sensors are utilized to detect physiological and functional indexes of patients, and objective data are provided for rehabilitation doctors to revise training plans; utilize man-machine interface technique, adjust training intensity and training mode according to patient's health state, such intelligent mechanism is favorable to improving the blood supply state of patient's brain, excites the pathological change part of brain, has the promotion effect to improving muscle reflex arc, is favorable to mobilizing the recovered enthusiasm of patient, makes patient's muscle obtain abundant exercise. Therefore, in order to enable more patients to recover early, research on a rehabilitation robot and a control technique thereof has great social and human significance.

Disclosure of Invention

The invention aims to provide a knee joint rehabilitation robot, which selects a rehabilitation strategy of the rehabilitation robot in a visual man-machine interaction mode, adjusts training intensity and a training mode according to the body state of a patient by using a man-machine interface technology, records human body data in real time, manages health data, and solves the problems that the existing patient needs to go to a hospital for rehabilitation training, a rehabilitation scheme cannot be customized, and the rehabilitation effect is poor.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a knee joint rehabilitation robot which comprises an MCU circuit, a power supply module, a human-computer interaction module, a stepping motor driving module, an ESP-M1 wireless module, a motor current detection module, a motor speed measurement module, a myoelectric current acquisition module and an HMI serial port touch screen;

the ESP-M1 wireless module is used for realizing wireless communication and transmitting data; the ESP-M1 wireless module is used for connecting the HMI serial port touch screen with the MCU in a communication way through an RS-485 bus; the human-computer interaction module is used for visual interaction between a human and a machine and selection of a training mode; the stepping motor driving module is used for driving a stepping motor to realize the control of the motor motion mode;

the MUC is respectively connected with the power supply module, the man-machine interaction module, the stepping motor driving module, the ESP-M1 wireless module, the motor current detection module, the motor speed measurement module and the myoelectric current acquisition module through serial ports.

Preferably, the MCU selects STM32F373RBT6 as a main control chip; the Cortex-M4 pin of the STM32F373RBT6 realizes the driving of a motor, the serial port function and the pushing of data packets.

Preferably, the human-computer interaction module is a USART HMI intelligent serial port screen; GUI is arranged inside the USART HMI intelligent serial port screen and used for modifying parameters on the control through serial port communication.

Preferably, the ESP-M1 wireless module adopts an ESP8285 chip; an ESP8285 chip is internally integrated with a core processor and is provided with an SRAM; the ESP8285 chip has a cache memory built in.

Preferably, the stepping motor driving module adopts an MC33931 chip; the 33931H bridge in the ESP8285 chip is used to control inductive loads.

Preferably, the motor current detection module adopts an AD8211YRJZ chip for performing a current test on the motor.

Preferably, the motor speed measuring module adopts an SN74LVC2G17 chip; the SN74LVC2G17 chip operates a VCC pin to provide hysteresis for input, and then speed measurement is performed through a timer in the MCU.

Preferably, the muscle current collecting module collects signals through an electrode patch; the muscle current acquisition module acquires through the internal ADC of STM32 through rectifier circuit, smoothing circuit and signal amplification again.

Preferably, the system workflow steps of the knee joint rehabilitation robot are as follows:

step S1: acquiring RCC clock frequency;

step S2: setting a tick timer;

step S3: configuring electrode control PWM parameters;

step S4: initializing all peripheral equipment;

step S5: starting up and initializing ESP state variables;

step S6: judging whether the timer reaches 1 ms;

if the time exceeds 1ms, executing step S7;

if the time is less than 1ms, executing step S9;

step S7: setting the led to be in a 1ms display mode;

step S8: calling an ESP related mode processing function;

step S9: executing the received command of the ESP;

step S10: judging whether the timer reaches 1ms again;

if the time exceeds 1ms, executing step S11;

if the time is less than 1ms, executing step S13;

step S11: setting a PWM value of the motor;

step S12: the ESP performs a 1s processing function;

step S13: judging whether the timer reaches 1min or not;

if the time exceeds 1min, executing step S14;

if the time is less than 1min, executing step S15;

step S14: ESP executes 1min processing function;

step S15: judging whether the serial port 1 receives data or not;

if yes, go to step S16;

if not, go to step S17;

step S16: executing the processing function;

step S17: acquiring a speed value;

step S18: obtaining an ADC value;

step S19: returning to step S6, the sequence loops.

The invention has the following beneficial effects:

(1) the rehabilitation strategy of the rehabilitation robot is selected in a visual human-computer interaction mode, and the patient directly selects three modes of passive training, active training and active impedance training through the touch display screen, so that the patient can finish the rehabilitation training without going out, the trouble of the patient going to a hospital for rehabilitation is avoided, the pain of the patient is relieved, and the medical cost is reduced.

(2) The rehabilitation robot monitors the physiological and functional indexes of a patient in real time, manages health data and provides objective data for a rehabilitation doctor to revise a training plan; utilize man-machine interface technique, adjust training intensity and training mode according to patient's health state, be favorable to improving the blood supply state of patient's brain, have the promotion effect to improving muscle reflex arc, be favorable to mobilizing patient's recovered enthusiasm, make patient's muscle obtain abundant exercise.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a knee joint rehabilitation robot system according to the present invention;

FIG. 2 is a circuit diagram of an MCU in the knee joint rehabilitation robot;

FIG. 3 is a circuit diagram of a power supply module;

FIG. 4 is a circuit diagram of the ESP-M1 wireless module;

FIG. 5 is a circuit diagram of a stepper motor driver module;

FIG. 6 is a circuit diagram of a motor current detection module;

FIG. 7 is a circuit diagram of a motor speed measurement module;

FIG. 8 is a circuit diagram of a myoelectric current collection module;

fig. 9 is a system operation flowchart of the knee joint rehabilitation robot.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the invention relates to a knee joint rehabilitation robot, which comprises an MCU circuit, a power supply module, a human-computer interaction module, a stepping motor driving module, an ESP-M1 wireless module, a motor current detection module, a motor speed measurement module, a myoelectric current acquisition module and an HMI serial port touch screen;

the ESP-M1 wireless module is used for realizing wireless communication and transmitting data; the ESP-M1 wireless module is used for connecting the HMI serial port touch screen with the MCU in a communication way through an RS-485 bus; the human-computer interaction module is used for the visual interaction between a human and a machine and the selection of a training mode; the stepping motor driving module is used for driving a stepping motor to realize the control of the motor motion mode;

the MUC is respectively connected with the power supply module, the man-machine interaction module, the stepping motor driving module, the ESP-M1 wireless module, the motor current detection module, the motor speed measurement module and the myoelectric current acquisition module through serial ports; the knee joint rehabilitation robot system needs to perform rehabilitation training in a manual selection state, a user needs to firstly perform manual selection of a motion mode through a human-computer interaction module, data needs to be acquired, processed and transmitted, and a stepping motor is controlled.

As shown in fig. 2, the MCU selects STM32F373RBT6 as the main control chip; a Cortex-M4 pin of the STM32F373RBT6 realizes the driving of a motor, the serial port function and the pushing of a data packet; 32-512KB Flash and 6-64KB SRAM memories are integrated on an STM chip, and the debugging modes are divided into serial debugging (SWD) and JTAG interfaces, and at most 112 fast I/O ports, 11 timers and 13 communication interfaces. The STM32 adopts a 32-bit microcontroller of an ARM Cortex-M kernel, has the advantages of high performance, strong real-time performance, low power consumption, convenience for low-voltage operation and the like, and is easy to develop; therefore, the MCU circuit of this application file chooses STM32F373RBT6 as the main control chip, because all data processing and sending are concentrated in the terminal module, integrate whole lower floor's hardware simultaneously, for the realization and the high efficiency of function, the system has chooseed STM32F373 to construct whole lower floor's circuit, STM32F373 is the development board that uses 32 bit microcontroller and 72MHz consumption to use Cortex-M4 as the kernel, possess the high integration of each module function.

As shown in fig. 3, considering that a voltage of 12V is used for driving the stepping motor, a power supply circuit design with a maximum voltage of 48V is adopted for scalability.

The design of the human-computer interaction module adopts an industrial serial port screen, an industrial touch screen and the like which are specially used as screens of industrial intelligent display instruments, a GUI (graphical user interface) is generally designed in a dragging control mode by software, and the human-computer interaction module is a USART HMI (Universal Serial bus interface) intelligent serial port screen; GUI is arranged in the USART HMI intelligent serial port screen and used for modifying parameters on the control through serial port communication; GUI is a Graphical User Interface (GUI), which refers to a computer operation User Interface displayed in a Graphical manner, and is an Interface display format for people to communicate with a computer, allowing a User to use an input device such as a mouse to manipulate icons or menu options on a screen to select commands, call files, start programs, or perform other daily tasks. Graphical user interfaces have many advantages over character interfaces that enter text or character commands through a keyboard to accomplish routine tasks. The graphical user interface consists of windows, pull-down menus, dialog boxes and corresponding control mechanisms, and is standardized in various new applications, i.e. the same operations are always performed in the same way, and graphical objects are seen and operated by users in the graphical user interface, and the technology of computer graphics is applied.

As shown in fig. 4, the ESP-M1 wireless module core processor employs a cost effective ESP8285 chip; the ESP8285 chip integrates an enhanced version of Tensiica's L106 diamond series 32-bit core processor in a smaller-size package and is provided with an SRAM; the ESP8285 has a complete Wi-Fi network function, can be independently applied, and can also be carried on other host MCUs as a slave machine to operate. When the ESP8285 hosts an application, the application can be started directly from an external Flash. The built-in cache memory is advantageous for improving system performance and optimizing the storage system. In addition, the ESP8285 can be used as a Wi-Fi adapter only through an SPI/SDIO interface or an I2C/UART interface and applied to a controller based on STM 32.

As shown in fig. 5, the stepping motor driving module adopts an MC33931 chip; the 33931H bridge in the ESP8285 chip is used for controlling an inductive load, and the current is up to 5.0 peak value. The RMS current capability is the degree to which the heat sink provides to the device package. The internal peak current limited load current activates the above-mentioned 6.5 ± 1.5a output load may be pulse width modulated at a frequency of up to 11 khz. The load current feedback function provides a proportion which is 0.24% of the load current and is suitable for the A/D input of a single chip microcomputer outputting the monitoring current. Under-voltage status flag output reporting, over-current and over-temperature faults can be achieved.

As shown in fig. 6, the motor current detection module adopts an AD8211YRJZ chip for performing current test on the motor, so as to facilitate realization of a current closed loop for motor control.

As shown in fig. 7, the motor speed measuring module adopts an SN74LVC2G17 chip; the SN74LVC2G17 chip operates a VCC pin of 1.65V-5.5V to provide hysteresis for input, and then speed measurement is carried out through a timer in the MCU.

As shown in fig. 8, the myoelectric current collecting module collects signals through an electrode patch; the muscle current acquisition module acquires through the internal ADC of STM32 through rectifier circuit, smoothing circuit and signal amplification again.

As shown in fig. 9, the system workflow of the knee joint rehabilitation robot includes the following steps:

step S1: acquiring RCC clock frequency;

step S2: setting a tick timer;

step S3: configuring electrode control PWM parameters;

step S4: initializing all peripheral equipment;

step S5: starting up and initializing ESP state variables;

step S6: judging whether the timer reaches 1 ms;

if the time exceeds 1ms, executing step S7;

if the time is less than 1ms, executing step S9;

step S7: setting the led to be in a 1ms display mode;

step S8: calling an ESP related mode processing function;

step S9: executing the received command of the ESP;

step S10: judging whether the timer reaches 1ms again;

if the time exceeds 1ms, executing step S11;

if the time is less than 1ms, executing step S13;

step S11: setting a PWM value of the motor;

step S12: the ESP performs a 1s processing function;

step S13: judging whether the timer reaches 1min or not;

if the time exceeds 1min, executing step S14;

if the time is less than 1min, executing step S15;

step S14: ESP executes 1min processing function;

step S15: judging whether the serial port 1 receives data or not;

if yes, go to step S16;

if not, go to step S17;

step S16: executing the processing function;

step S17: acquiring a speed value;

step S18: obtaining an ADC value;

step S19: returning to step S6, the sequence loops.

One specific application of this embodiment is:

after the system is powered on, the MCU firstly initializes the whole circuit, including initializing data and initializing each GPIO port, wherein the initialization needs to be delayed for a period of time, and the influence of the previous data on the subsequent data is prevented. The system designs an interrupt-triggered mode to detect if there is a change in the high and low levels, and the external interrupt is a computer system interrupt that occurs due to an external disturbance, whether from a user, a peripheral device, other hardware device, or through a network. The method is characterized in that the method is different from the internal interruption automatically generated when a machine reads a program instruction, the whole system only implements main functions or a sleep mode under a normal condition, and simultaneously detects whether an external device pin has an interruption triggering signal or not, once the external interruption triggers, the whole hardware enters the implementation of the interruption function, and then the device automatically restores to the previous state after the interruption is finished.

After initialization is completed, a human-computer interaction interface is started, user operation is waited, rehabilitation robot data are read through RS-485 communication and displayed on an HMI serial port screen, a user performs corresponding operation through a serial port, an MCU acquires and processes related user operation data in real time, and a stepping motor is controlled to push so as to achieve rehabilitation movement, wherein the system flow is shown in figure 10.

It should be noted that, in the above system embodiment, each included unit is only divided according to functional logic, but is not limited to the above division as long as the corresponding function can be implemented; in addition, specific names of the functional units are only for convenience of distinguishing from each other, and are not used for limiting the protection scope of the present invention.

In addition, it is understood by those skilled in the art that all or part of the steps in the method for implementing the embodiments described above may be implemented by a program instructing associated hardware, and the corresponding program may be stored in a computer-readable storage medium.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. A knee joint rehabilitation robot comprises an MCU circuit, a power supply module, a man-machine interaction module, a stepping motor driving module, an ESP-M1 wireless module, a motor current detection module, a motor speed measurement module, a myoelectric current acquisition module and an HMI serial port touch screen; the method is characterized in that:

2. The knee joint rehabilitation robot according to claim 1, wherein the MCU selects STM32F373RBT6 as a main control chip; the Cortex-M4 pin of the STM32F373RBT6 realizes the driving of a motor, the serial port function and the pushing of data packets.

3. The knee joint rehabilitation robot according to claim 1, wherein the human-computer interaction module is a USART HMI intelligent serial port screen; GUI is arranged inside the USART HMI intelligent serial port screen and used for modifying parameters on the control through serial port communication.

4. The knee joint rehabilitation robot according to claim 1, wherein the ESP-M1 wireless module employs an ESP8285 chip; an ESP8285 chip is internally integrated with a core processor and is provided with an SRAM; the ESP8285 chip has a cache memory built in.

5. The knee joint rehabilitation robot according to claim 1, wherein the stepping motor driving module employs an MC33931 chip; the 33931H bridge in the ESP8285 chip is used to control inductive loads.

6. The knee joint rehabilitation robot according to claim 1, wherein the motor current detection module employs an AD8211YRJZ chip for performing current testing on the motor.

7. The knee joint rehabilitation robot according to claim 1, wherein the motor speed measuring module adopts an SN74LVC2G17 chip; the SN74LVC2G17 chip operates a VCC pin to provide hysteresis for input, and then speed measurement is performed through a timer in the MCU.

8. The knee joint rehabilitation robot according to claim 1, wherein the muscle current collecting module collects signals through an electrode patch; the muscle current acquisition module acquires through the internal ADC of STM32 through rectifier circuit, smoothing circuit and signal amplification again.

9. The knee joint rehabilitation robot according to claims 1-8, wherein the system workflow steps of the knee joint rehabilitation robot are as follows:

step S1: acquiring RCC clock frequency;

step S2: setting a tick timer;

step S3: configuring electrode control PWM parameters;

step S4: initializing all peripheral equipment;

step S5: starting up and initializing ESP state variables;

step S6: judging whether the timer reaches 1 ms;

if the time exceeds 1ms, executing step S7;

if the time is less than 1ms, executing step S9;

step S7: setting the led to be in a 1ms display mode;

step S8: calling an ESP related mode processing function;

step S9: executing the received command of the ESP;

step S10: judging whether the timer reaches 1ms again;

if the time exceeds 1ms, executing step S11;

if the time is less than 1ms, executing step S13;

step S11: setting a PWM value of the motor;

step S12: the ESP performs a 1s processing function;

step S13: judging whether the timer reaches 1min or not;

if the time exceeds 1min, executing step S14;

if the time is less than 1min, executing step S15;

step S14: ESP executes 1min processing function;

step S15: judging whether the serial port 1 receives data or not;

if yes, go to step S16;

if not, go to step S17;

step S16: executing the processing function;

step S17: acquiring a speed value;

step S18: obtaining an ADC value;

step S19: returning to step S6, the sequence loops.