CN204636917U - The special lower limb exoskeleton of hemiplegic patient - Google Patents

Abstract

The utility model discloses a special lower limb exoskeleton for patients with hemiplegia, which comprises a unilateral exoskeleton leg, a support rod, a telescopic rod, a controller and a battery, and the unilateral exoskeleton leg includes a thigh rod, a calf rod, a sole boot, and a hip joint , knee joint and ankle joint, the thigh rod is connected to the support rod through the hip joint, and the support rod is provided with a hip joint drive motor, a knee joint drive motor and a telescopic rod drive motor in sequence from top to bottom, and the hip joint drive motor passes through the hip joint worm gear. The worm is connected to the hip joint, the driving motor of the knee joint is connected to the middle part of the calf rod through the worm gear of the knee joint and the swinging rod of the knee joint, and the ankle joint shock absorber is arranged between the ankle joint and the knee joint, and the driving motor of the telescopic rod is connected with the transmission structure of the screw. The telescopic rod is connected, and the controller and the battery are arranged on the support rod. The utility model aims at patients with unilateral lower limb hemiplegia, fully exerts the function of the healthy side limb of the patient, helps the patient to walk on level ground and go up and down stairs, improves reliability and reduces cost.

Description

Lower limb exoskeleton for hemiplegic patients

technical field

The utility model relates to a device for assisting the disabled, in particular to a special lower limb exoskeleton for hemiplegic patients.

Background technique

Existing technology and existing deficiencies:

1. Existing related products and their shortcomings

(1) At the opening ceremony of the 2014 World Cup in Brazil, the exoskeleton that allowed the paralyzed Brazilian teenager Pinto to stand up and kick off was called BRA-Santos Dumont, which represented the advanced level of exoskeleton technology in the world today.

This brain-controlled exoskeleton is a research result of the international "Walk Again Project". The exoskeleton uses electrodes implanted in the scalp or in the patient's brain to detect brain activity signals. These signals are transmitted wirelessly to a computer on the wearer, which is responsible for translating the signals into specific leg movements. The BRA-Santos Dumont exoskeleton device has a high technical content, which gathers the wisdom of hundreds of scientists and applies the most advanced technology today. The device is controlled by brain waves and requires electrodes to be implanted directly into the brains of paralyzed patients. When placing the electrodes, not only must the electrodes be implanted in the brain tissue under the skull, but also be able to detect more neurons in the cerebral cortex at the same time. Some neuroscientists believe that recording brain activity through non-invasive means such as EEG can reflect the correspondence between consciousness and muscles, but this idea has not yet been realized. This device structure is too numerous and diverse, also has a certain distance from practicality. Its cost is also unacceptable for ordinary patients.

(2) Walking Assist Device developed by Honda. It can reduce the user's various muscle loads and easily complete some basic movements. This equipment includes three parts: seat, fream and shoes, with a total weight of 6.5kg. Honda is currently testing the effect of the equipment on a small scale at their car plant.

This device is relatively dexterous, but it is mainly suitable for the elderly and infirm with healthy limbs but weak physical strength, and is not suitable for hemiplegic patients. Because this system is difficult to guarantee the user's balance. But the development of the utility model has some references.

(3) The bionic exoskeleton developed by Israel's Argo Medical Technologies, named "ReWalk". In 2014, this product passed the certification of the US Food and Drug Administration (FDA). It is the first exoskeleton approved by FDA. According to the FDA, ReWalk can help people who have lost mobility in their legs feel like walking again.

"ReWalk" helps paraplegics (that is, people who are paralyzed from the waist down) stand, walk and climb stairs. "ReWalk" requires a pair of crutches to help maintain body balance, and consists of electric leg supports, body sensors and a backpack with a computer control box and rechargeable batteries. The user can use the remote control belt to select a certain mode, such as standing, sitting, walking, climbing and so on. It then leans forward, activating body sensors and putting the mechanical legs in motion.

While the ReWalk is FDA-cleared, that doesn't mean everyone with limited mobility can use it. It is reported that the price of this equipment is as heavy as its weight, which is as high as 69,500 US dollars. Users also need to go through 15 training courses before they can really get started. Product owner Goffre himself was paralyzed in an accident in 1997, but unfortunately, he cannot use his utility model because his arms are not yet fully functional. Because the device requires both hands to use crutches to maintain balance, it is somewhat difficult for hemiplegic patients to use.

(4) The paraplegic walking machine developed by Professor Zhang Jichuan of the Rehabilitation Engineering Research Center of Tsinghua University and Beijing Ruihaibo Technology Co., Ltd. The product has two main uses: 1. It is used as a walking tool for paraplegic patients to wear on their bodies, and walk independently driven by the walking mechanism; 2. It cooperates with a medical treadmill and is used as the main rehabilitation equipment for training for people with lower limb dysfunction.

The control system of the walking machine is composed of an optical code disc, a microprocessor, a power amplifier, and a position feedback system. Patients can manually adjust the walking speed according to their needs. The walking machine is made of lightweight and high-strength titanium alloy, with a total weight of only 9.6 kg. At present, the patient needs the cooperation of the trolley to use the walking system, which is not suitable for going up and down stairs and downhill.

(5) In July 2014, "Shenzhen Special Zone News", "China Science Daily" and other domestic media reported that the lower extremity exoskeleton robot project of the Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences had made a major breakthrough, and successfully achieved paraplegia patients through wearing robots. Standing and walking ^[9] . The robot adopts a miniaturized power system and an underactuated mechanical structure, and uses flexible control to achieve a stable gait of the exoskeleton robot. Compared with the same type of robots at home and abroad, the advanced exo-skeleton robot has the characteristics of compact structure, intelligent gait planning, rehabilitation training and walking assistance for the disabled.

After comparison, this achievement is similar to the bionic exoskeleton developed by Israel's Argo Medical Technologies, named "ReWalk" exoskeleton. But the use of this device needs to use two crutches, needs two healthy hands to assist movement, also is not suitable for unilateral hemiplegia patient.

2. Existing related patents and shortcomings

A patent for a wearable lower limb exoskeleton walker robot, CN103054692A discloses a wearable lower limb exoskeleton walker robot, which consists of an ankle joint movement module, a knee joint movement module, a hip joint movement module, a drive module, a waist and a support frame module and so on. A patented wearable lower limb power-assisted exoskeleton, CN103315834, provides a single-degree-of-freedom wearable lower limb power-assisted exoskeleton through complex structures such as connecting rods and gears. A patent for a split-type human lower extremity exoskeleton walking aid, CN201939538 discloses a split human lower extremity exoskeleton walking aid, which uses telescopic support rods that do not need to be tied to the big and small legs to support the human body. A patent for a wearable lower limb walking exoskeleton, ZL200420081794.4 discloses a wearable lower limb walking exoskeleton, which consists of hip four-bar mechanism, knee four-bar mechanism, ankle four-bar mechanism, etc. A computer records normal gait and then reproduces it to help the patient walk. A patent for an anthropomorphic lower limb exoskeleton robot, CN103610568A discloses an anthropomorphic lower limb exoskeleton robot, which consists of a hip drive system, a knee drive system, and an ankle wearable system. 3 degrees of freedom are set at the hip, 1 degree of freedom at the knee and 2 degrees of freedom at the ankle to increase the comfort of the wearer. Patented exoskeleton wearable lower limb rehabilitation robot, CN201110292009.0 separates a wearable exoskeleton lower limb rehabilitation robot, including foot exoskeleton, ankle exoskeleton, calf exoskeleton, knee exoskeleton, thigh exoskeleton, hip joint Exoskeleton and waist exoskeleton. The driving motor adopts a harmonic reducer and a disc motor.

In the above-mentioned patents, both lower limbs are balanced, and the needs of hemiplegic patients with healthy unilateral limbs are not considered. The structure is too complicated, and it is troublesome to wear, so it is difficult to promote.

Utility model content

In order to solve the defects and deficiencies in the above-mentioned prior art, the utility model provides a method for patients with unilateral lower limb hemiplegia to help them walk on flat ground and go up and down stairs, give full play to the role of the healthy side of the patient, improve system reliability, and reduce costs. The special lower extremity exoskeleton for hemiplegic patients and its use method and stability verification method.

The technical scheme of the utility model: a special lower extremity exoskeleton for hemiplegia patients, including a unilateral exoskeleton leg, a support rod mechanism, a controller and a battery, and the unilateral exoskeleton leg includes a thigh rod, a calf rod, a sole boot, The hip joint connected to the top of the thigh bar, the knee joint connected to the thigh bar and the calf bar, and the ankle joint connected to the calf bar and the sole boot, the support bar mechanism includes a support bar and a telescopic bar arranged at the bottom of the support bar, the The thigh rod is connected with the support rod through the hip joint, and the hip joint drive motor, the knee joint drive motor and the telescopic rod drive motor are sequentially arranged on the support rod from top to bottom, and the hip joint drive motor is connected to the hip joint through the worm gear of the hip joint. Joint connection, the knee joint drive motor is connected to the middle part of the calf rod through the knee joint worm gear and the knee joint swing rod, an ankle joint shock absorber is arranged between the ankle joint and the knee joint, and the telescopic rod drive motor is connected through a screw The transmission structure is connected with the telescopic rod, and the controller and the battery are arranged on the support rod.

Preferably, a slide rail is provided on the calf rod, the bottom of the knee joint swing rod is connected to the slide rail through a slider, an underarm support bar is provided on the top of the support rod, and an armpit support bar is provided on the underarm support bar. There are shoulder straps.

Preferably, thigh straps are provided on the thigh bar, calf straps are provided on the calf bar, a chest guard is provided on the upper part of the support bar, and the chest guard is divided into left and right side guards, the left side Both the guard plate and the right guard plate are connected to the support rod through the guard plate hinge.

Preferably, the ankle joint shock absorber is a shock absorbing rod, the top of the shock absorbing rod is hinged on the knee joint, the bottom of the shock absorbing rod is hinged on the ankle joint, and the control box is equipped with the hip joint, knee A controller for coordinated control among the three drive motors of joints and support rods. The controller has a 3-axis teaching function, which can memorize and reproduce the acceleration and deceleration curves of the three motors, so that patients can adjust the hip, knee, etc. according to their own habits. Action planning of the three parts of the telescopic rod. The foot boots and the telescopic rod are equipped with pressure sensors to determine whether the patient’s sole and the telescopic rod are on the ground. Each drive motor is equipped with a rotary encoder to detect the movement of each joint. Position and speed, as well as the telescopic length of the support rod. An inclination angle sensor is installed on the support rod to detect the angle change of the support rod and realize the coordinated control of the support rod and the exoskeleton leg joints.

The utility model adopts a unilateral exoskeleton leg+support rod structure, and the support rod adopts a telescopic structure, and drives corresponding joints through transmission mechanisms such as worm gears and worms. The ankle joint does not have a driving motor, and the ground cushion is realized by the ankle joint shock absorber. The battery and the control box are fixed on the support pole. The exoskeleton legs are connected to the support rods through hip joints. When wearing it, the patient's affected leg is bound to the exoskeleton leg, and the affected foot is put into the boot. The support bar is pressed against the patient's armpits, and the shoulder straps are fixed on the patient's shoulders. The front and rear guards are tightly attached to the front chest and the back respectively, and are fastened with straps. In order to meet the requirements of patients of different heights, length adjustment devices are provided on the thigh bar, calf bar, telescopic bar, etc. To improve wearing comfort and convenience, in order to reduce the complexity of the device, improve reliability and reduce cost, the exoskeleton of this project is only designed with three degrees of freedom of the hip, knee and ankle. In order to increase the wearing comfort of the patient and reduce the weight of the device, the exoskeleton's large and calf rods are made of highly flexible and high-strength materials, such as polyurethane. In order to facilitate the self-wearing of the patient, the exoskeleton should be in an upright ready state before wearing.

A method for using a special lower limb exoskeleton for hemiplegic patients on flat ground, comprising the following steps:

1) Wearing preparation: the patient sits on a long bench, the exoskeleton legs are in a sitting posture, the thighs are flat, the calves are vertical, the support rods are placed under the armpits, and they are in an upright contraction state;

2) The patient wears it by himself: the exoskeleton leg is bound to the affected leg, the shoulder strap is fixed, and the chest and back are locked by the left and right side shields;

3) Standing up: the healthy leg moves back parallel to the support rod, the telescopic rod is extended, and the patient's body is lifted from the armpit, the healthy leg and the support rod are synchronously assisting the human body to stand, and the exoskeleton leg moves back to be flush with the healthy leg and the support rod;

4) Before the walking aid, the support rod and the exoskeleton legs are close together and upright;

5) When the controller issues an instruction to move forward on flat ground, the exoskeleton legs are driven by the hip joint and knee joint motors, simulating the habit of the human body to lift the affected leg forward; the healthy side leg assists the body to lean forward, and the body leans forward during the process In the middle, the extension of the support rod assists the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing;

6) Finally, the support rod shrinks and lifts off the ground. Under the action of the hip joint motor and the weight of the support rod itself, the support rod moves forward and closes to the exoskeleton legs and is in a vertical state again. After the support rod is upright, drive the motor to make it stretch again On the ground, complete one step of walking assistance and prepare for the next walking assistance.

Preferably, when worn in step 2), the patient's affected leg is bound to the exoskeleton leg, thigh bar and calf bar through thigh straps and calf straps respectively, and the affected foot is put into the sole boot, and the support bar It is pressed on the patient's armpit, and the shoulder strap is fixed on the patient's shoulder; the left and right side shields are respectively close to the front chest and back, and are fastened with belts.

Preferably, during walking, the weight of the device is borne by the support rod and the exoskeleton leg in turn, before walking is borne by the support rod, and during the assisting walking process, the weight is gradually transferred from the support rod to the exoskeleton leg.

The affected leg does not need to bear the weight of the device and the patient itself.

A method for using a special lower extremity exoskeleton for hemiplegic patients to go up and down stairs, comprising the following steps:

1) Wearing preparation: the patient sits on a long bench, the exoskeleton legs are in a sitting posture, the thighs are flat, the calves are vertical, the support rods are placed under the armpits, and they are in an upright contraction state;

2) The patient wears it by himself: the exoskeleton leg is bound to the affected leg, the shoulder strap is fixed, and the chest and back are locked by the left and right side shields;

3) Standing up: the healthy leg moves back parallel to the support rod, the telescopic rod is extended, and the patient's body is lifted from the armpit, the healthy leg and the support rod are synchronously assisting the human body to stand, and the exoskeleton leg moves back to be flush with the healthy leg and the support rod;

4) Before the walking aid, the support rod and the exoskeleton legs are close together and upright;

5) When going up the stairs, when the controller issues an instruction to move forward on flat ground, the telescopic rod first stretches to raise the patient's leg, and the exoskeleton leg is driven by the hip joint and knee joint motor to simulate the habit of the human body to lift the affected leg forward The healthy side leg helps to make the body lean forward. During the process of leaning forward, the support rod extends to assist the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing on the ground;

6) When going down the stairs, when the controller issues an instruction to move forward on flat ground, the telescopic rod shortens first to lower the center of gravity, and the exoskeleton legs are driven by the hip joint and knee joint motors, simulating the habit of the human body to lift the affected leg forward; the healthy side The legs help to make the body lean forward. During the forward leaning process, the support rods extend to assist the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing on the ground;

7) Finally, the support rod shrinks and lifts off the ground. Under the action of the hip joint motor and the weight of the support rod itself, the support rod moves forward and closes to the exoskeleton leg and becomes vertical again. After the support rod stands upright, the motor is driven to extend the support rod again On the ground, complete one step of walking assistance and prepare for the next walking assistance.

A method for verifying the stability of the lower extremity exoskeleton for hemiplegic patients, comprising the following steps:

1) Using the three-dimensional acquisition and positioning system, the image of the healthy side leg of the hemiplegic patient completing sitting up, walking on flat ground, and going up and down stairs with the assistance of others is collected;

2) Through the ariel biological operation analysis software, the hip and knee joint motion angle and angular velocity function; the trajectory of key points and the velocity function curve are obtained;

3) Add the motion parameters of the hip and knee joints to the corresponding parts of the model, and simulate through the ADAMS software to find the rotation angle, speed and torque parameters of the driving motors of the hip and knee joints;

4) The patient tries on the prototype exoskeleton of the utility model, simulating several modes of movement of the human body, and the telescopic motor of the support rod is manually controlled by others according to the needs of walking;

5) Obtain the functional relationship between the rotation angle and rotation speed of the drive motor of the support rod and the rotation angle and rotation speed of the hip and knee joint motors;

6) Establish the exoskeleton and human body model through Solidworks and import them into ADAMS, set up relevant constraints and motion pairs; add the obtained motion parameters to the output shafts of each drive motor for simulation;

7) Simulation and calculation of the zero-moment point ZMP trajectory of the exoskeleton and human walking assistance process, and analysis of the stability margin.

Preferably, the joint position, speed, and torque parameters obtained in step 6) are converted into control data of each drive motor and stored in the controller. During operation, the controller uses the control strategy based on these data and sensor feedback data, Control each drive motor to achieve the desired exoskeleton movement.

The transmission structure of the hip joint and knee joint of the utility model refers to the mature design scheme of the existing double lower extremity walking aid exoskeleton. calf exercise. The expansion and contraction of the support rod is realized by the drive motor through the screw nut, and then through the guiding mechanism to realize the non-rotational expansion and contraction.

The utility model is designed with multiple safety protection measures. One is the design of the limit position of mechanical operation to ensure that the range of movement of the mechanism is within the allowable range of the human body; the other is to realize safety protection through the self-locking of related parts. For example, when the human body is upright, the knee joint needs to be protected. Erect self-locking. This project selects the motor with self-locking function, and selects the transmission parts with self-locking function, such as worm gear (when the lead angle of the worm is less than the equivalent friction angle between meshing teeth, it has self-locking property), thread (thread The self-locking condition is that the thread lead angle is less than the equivalent friction angle), etc. The third is to set the travel switch to realize safety guarantee through electrical interlocking. The fourth is to fully consider various possible situations in the software to achieve safety and fault tolerance protection.

The gait stability verification of the utility model and the motor drive parameter design are carried out in combination

(1) Gait verification. According to the above-mentioned exoskeleton structure and walking aid method, the gait stability analysis is carried out according to the zero moment point ZMP (Zero Moment Point) method to ensure the balance and stability of the patient when walking.

(2) Transform the required gait requirements into the control parameters required by each drive motor.

(1) Gait stability verification, zero moment point ZMP (Zero Moment Point) trajectory analysis is a common method for judging gait stability. ZMP is the intersection of the extension line of the resultant force vector of gravity, inertial force and ground reaction force on the lower extremity exoskeleton and the ground. In order to make the lower extremity exoskeleton walk stably, the zero moment point (ZMP) should always be kept within the reasonable support area (stable area) of the convex polygon formed by the supporting feet (rods). The stable area is the projection of the convex area formed by the soles of the feet or the support rods on the horizontal plane.

This project uses the three-dimensional acquisition and positioning system of human motion images (Figure 10) to collect images of the healthy side legs of hemiplegic patients who complete sitting ups, walking on flat ground, and going up and down stairs with the assistance of others; each operating mode is obtained through the ariel biological operation analysis software Corresponding to the leg motion parameters. Then import these motion parameters into the human body and exoskeleton model established by ADAMS for simulation, calculate the zero moment point ZMP trajectory, judge the stability during walking, and analyze the stability margin of gait.

(2) Drive motor control parameter design, import the joint motion parameters obtained by the ariel operation analysis software into the ADAMS exoskeleton model, simulate and calculate the rotation angle and speed parameters required by the two drive motors of the hip and knee joints, and the connection between the two drive motors. Axis motion control requirements. In order to find out the relationship between the control parameters of the hip and knee drive motors and the inclination angle of the support rod, the patient was asked to try on the exoskeleton prototype and complete various movements with the assistance of others. Obtain the functional relationship between the rotation angle and rotation speed of the drive motor of the support rod and the rotation angle and rotation speed of the hip and knee joint motors.

Advantages: Use the ariel operation analysis system to analyze the patient's normal leg movement to obtain control parameters, which is conducive to designing movements that meet the patient's habits. The gait analysis is carried out through the ZMP principle to improve the gait stability; the simulation is used to omit complex mathematical modeling, and the design process is simplified while ensuring the accuracy of the simulation.

Compared with the prior art, the utility model has the following beneficial effects: first, the cost is significantly reduced, because it omits a lower extremity exoskeleton and replaces it with a simple support rod; second, it has good wearability, and the existing double lower extremity exoskeleton The patient's waist and below are all wrapped by an exoskeleton, which is troublesome and uncomfortable to wear; after wearing it, the patient feels like a Transformer. The exoskeleton of the utility model only needs to bind the big and small legs of the affected side, plus a simple front and rear shield on the chest; the patient wears this product similar to a crutch, which is light and convenient; third, it has high stability, and the existing exoskeleton for both lower limbs; Both legs of the patient are restrained by the exoskeleton, which makes it difficult to realize autonomous control, and there are only two fulcrums when walking; while the utility model exoskeleton fully exerts the function of the healthy side leg of the patient, adds support rods, forms a three-point support structure, and increases walking Stability, and is conducive to the adjustment of gait parameters; fourth, the patient's weight is reduced, the existing double lower extremity structure exoskeleton, batteries and controllers are mostly placed on the back of the patient; when one leg is lifted, its weight is transmitted to the patient through the hip joint The waist is transmitted to the other side of the exoskeleton leg through the waist, which often causes discomfort in the waist; the utility model exoskeleton fixes the battery and controller on the support rod, and the weight is between the exoskeleton and the support rod when walking Transfer, the waist does not bear the weight of the device.

Description of drawings

Fig. 1 is the structural representation of the utility model;

Fig. 2 is a flow chart of the exoskeleton self-wearing and assisting standing up actions in the utility model;

Fig. 3 is a flow chart of the exoskeleton walking on flat ground in the utility model;

Fig. 4 is a design diagram of mechanism transmission in the utility model;

Fig. 5 is a design diagram of gait stability verification and drive motor control parameters in the utility model.

In the figure 1. Shoulder strap, 2. Underarm support bar, 3. Shield hinge, 4. Support rod, 5. Hip drive motor, 6. Hip worm gear, 7. Controller and battery, 8. Knee joint Drive motor, 9. Telescopic rod drive motor, 10. Knee swing rod, 11. Telescopic rod, 12. Foot boot, 13. Ankle shock absorber, 14. Calf strap, 15. Calf rod, 16. Knee Joint, 17. Thigh Bar, 18. Thigh Strap, 19. Hip, 20. Chest Guard, 21. Ankle.

Detailed ways

The utility model will be described in further detail below in conjunction with the accompanying drawings, but it is not a limitation to the protection scope of the utility model.

As shown in Figure 1, a special lower extremity exoskeleton for hemiplegic patients includes a unilateral exoskeleton leg, a support rod mechanism, a control box 7 and a power supply, and the unilateral exoskeleton leg includes a thigh bar 17, a calf bar 15, and a sole boot 12 , the hip joint 19 connected to the top of the thigh bar 17, the knee joint 16 connecting the thigh bar 17 and the calf bar 15, and the ankle joint 21 connecting the calf bar 15 and the sole boot 12, the support bar structure includes a support bar 4 and is arranged on a support The telescopic rod 11 at the bottom of the rod 4, the thigh rod 17 is connected with the support rod 4 through the hip joint 19, and the support rod 4 is successively provided with a hip joint drive motor 5, a knee joint drive motor 8 and a telescopic rod drive motor 9 from top to bottom, The hip joint drive motor 5 is connected to the hip joint 19 through the hip joint worm gear 6, the knee joint drive motor 8 is connected to the middle part of the calf bar 15 through the knee joint worm gear and the knee joint swing rod 10, and a gap is arranged between the ankle joint 21 and the knee joint 16. Ankle joint shock absorber 13, telescopic rod drive motor 9 is connected with telescopic rod 11 through leading screw transmission structure, power supply is arranged in control box 7, and control box 7 is arranged on support bar 11. Calf bar 15 is provided with slide rail, and the bottom of knee joint swing bar 10 is connected on the slide rail by a slide block, and support bar 11 top is provided with underarm support bar 2, and armpit support bar 2 is provided with shoulder strap 1. Thigh bar 17 is provided with thigh strap 18, calf bar 15 is provided with calf strap 14, and support bar 11 top is provided with chest guard plate 20, and chest guard plate 20 is divided into left and right side guard plates, left side guard plate and right side guard plate. The side guards are all connected with the support rods 11 through the guard hinges 3 . Ankle joint damper 13 is a shock absorber, and the top of the shock absorber is hinged on the knee joint 16, and the bottom of the shock absorber is hinged on the ankle joint 21, and the control box 7 is provided with three parts for realizing hip joint, knee joint and support rod. The controller for coordinated control between the driving motors. The controller has a 3-axis teaching function, which can memorize and reproduce the acceleration and deceleration curves of the three motors, which is convenient for patients to adjust the three parts of the hip, knee, and telescopic rod according to their own habits. Action planning, the foot boots 12 and the telescopic rod 11 are equipped with pressure sensors to determine whether the patient's sole and the telescopic rod are on the ground, and each drive motor is equipped with a rotary encoder to detect the movement position and speed of each joint, and to support The telescopic length of the rod, the tilt angle sensor is installed on the support rod to detect the angle change of the support rod, and realize the coordinated control of the support rod and the exoskeleton leg joints.

As shown in Figure 2, the product can be worn by patients themselves. When wearing it, the patient first moves to a long bench by himself, and the long bench can be placed beside the bed, and the patient can directly move from the bed to the stool. The long bench is convenient for patients to sit on it, and the front and rear stability is good. Before donning, the exoskeleton is placed upright on the side of the affected leg. Self-wearing and exoskeleton-assisted stand-up design.

As shown in Figure 3, the exoskeleton assists walking on flat ground. Before walking, the support rod and the exoskeleton legs are in an upright state. When the controller issues an instruction to move forward on flat ground, the exoskeleton legs are driven by the hip joint and knee joint motors, simulating the habit of the human body to lift the affected leg forward; the healthy side leg assists the body to lean forward; in the process of leaning forward, The extension of the support bar assists the human body to lean forward and the soles of the feet to touch the ground; and the legs of the exoskeleton gradually stand upright after touching the ground; finally, the support bar shrinks and lifts off the ground. Bring the legs together and be vertical again. After the support rod stands upright, the motor is driven to extend to support the ground again, completing one step of walking assistance and preparing for the next walking assistance. During walking, the weight of the device is borne by the support rod and the exoskeleton legs in turn. Before walking, it is borne by the support rod. During the process of assisting walking, the weight is gradually transferred from the support rod to the exoskeleton legs. When going up the stairs, the telescopic rod first stretches and raises the patient's legs, and then steps the feet. The rest of the movements are similar to walking on the ground, but the movement range is slightly different; The rest of the actions are similar to walking on flat ground. The detailed action design of going up and down the stairs will not be described in detail here. There are separate control modes for the hip joint, knee joint, and telescopic rod motors, so that patients can independently adjust the control mode and parameters in special cases.

A method for using a special lower limb exoskeleton for hemiplegic patients on flat ground, comprising the following steps:

1) Wearing preparation: the patient sits on a long bench, the exoskeleton legs are in a sitting posture, the thighs are flat, the calves are vertical, the support rods are placed under the armpits, and they are in an upright contraction state;

2) The patient wears it by himself: the exoskeleton leg is bound to the affected leg, the shoulder strap is fixed, and the chest and back are locked by the left and right side shields;

3) Standing up: the healthy leg moves back parallel to the support rod, the telescopic rod is extended, and the patient's body is lifted from the armpit, the healthy leg and the support rod are synchronously assisting the human body to stand, and the exoskeleton leg moves back to be flush with the healthy leg and the support rod;

4) Before the walking aid, the support rod and the exoskeleton legs are close together and upright;

5) When the controller issues an instruction to move forward on flat ground, the exoskeleton legs are driven by the hip joint and knee joint motors, simulating the habit of the human body to lift the affected leg forward; the healthy side leg assists the body to lean forward, and the body leans forward during the process In the middle, the extension of the support rod assists the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing;

6) Finally, the support rod shrinks and lifts off the ground. Under the action of the hip joint motor and the weight of the support rod itself, the support rod moves forward and closes to the exoskeleton legs and is in a vertical state again. After the support rod is upright, drive the motor to make it stretch again On the ground, complete one step of walking assistance and prepare for the next walking assistance.

When wearing in step 2), the patient's affected leg is bound to the exoskeleton leg, thigh bar and calf bar through the thigh strap and calf strap, respectively, and the affected foot is put into the sole boot to press the support bar against the Under the arms, the shoulder straps are fixed on the patient's shoulders; the left and right side guards are respectively close to the front chest and back, and are fastened with belts.

During walking, the weight of the device is borne by the support rods and exoskeleton legs in turn.

A method for using a special lower extremity exoskeleton for hemiplegic patients to go up and down stairs, comprising the following steps:

1) Wearing preparation: the patient sits on a long bench, the exoskeleton legs are in a sitting posture, the thighs are flat, the calves are vertical, the support rods are placed under the armpits, and they are in an upright contraction state;

2) The patient wears it by himself: the exoskeleton leg is bound to the affected leg, the shoulder strap is fixed, and the chest and back are locked by the left and right side shields;

3) The healthy leg moves back parallel to the support rod, and the telescopic rod stretches to lift the patient's body from the armpit. The healthy leg and the support rod assist the human body to stand synchronously, and the exoskeleton leg retreats to be flush with the healthy leg and the support rod;

4) Before the walking aid, the support rod and the exoskeleton legs are close together and upright;

5) When going up the stairs, when the controller issues an instruction to move forward on flat ground, the telescopic rod first stretches to raise the patient's leg, and the exoskeleton leg is driven by the hip joint and knee joint motor to simulate the habit of the human body to lift the affected leg forward The healthy side leg helps to make the body lean forward. During the process of leaning forward, the support rod extends to assist the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing on the ground;

6) When going down the stairs, when the controller issues an instruction to move forward on level ground, the telescopic rod shortens first to lower the center of gravity, and the exoskeleton legs are driven by the hip joint and knee joint motors, simulating the habit of the human body to lift the affected leg forward; the healthy side The legs help to make the body lean forward. During the forward leaning process, the support rods extend to assist the human body to lean forward, the soles of the feet touch the ground, and make the exoskeleton legs gradually stand upright after landing on the ground;

7) Finally, the support rod shrinks and lifts off the ground. Under the action of the hip joint motor and the weight of the support rod itself, the support rod moves forward and closes to the exoskeleton leg and becomes vertical again. After the support rod stands upright, the motor is driven to extend the support rod again On the ground, complete one step of walking assistance and prepare for the next walking assistance.

The transmission structure of the hip joint, the knee joint, etc. of the utility model can refer to the existing mature design scheme of the walking aid exoskeleton of both lower limbs. As shown in Figure 4, the joint drive of the utility model is intended to use a stepper motor or a servo motor, through gear reduction, through the worm gear to change the transmission direction, to drive the legs to move. The expansion and contraction of the support rod is realized by the drive motor through the screw nut, and then through the guiding mechanism to realize the non-rotational expansion and contraction.

In the safety protection design of the utility model, safety is the primary goal of this product, and for this reason, multiple safety protection measures have been designed for this product. One is the design of the limit position of the mechanical operation to ensure that the movement range of the mechanism is within the allowable range of the human body; the other is to achieve safety protection through the self-locking of related components. For example, when the human body is upright, the knee joint needs to be protectively upright and self-locking. This project selects the motor with self-locking function, and selects the transmission parts with self-locking function, such as worm gear (when the lead angle of the worm is less than the equivalent friction angle between meshing teeth, it has self-locking property), thread (thread The self-locking condition is that the thread lead angle is less than the equivalent friction angle), etc. The third is to set the travel switch to realize safety guarantee through electrical interlocking. The fourth is to fully consider various possible situations in the software to achieve safety and fault tolerance protection.

As shown in Figure 5, in the verification of gait stability of the present invention, zero moment point ZMP (Zero Moment Point) trajectory analysis is a commonly used method for judging gait stability. ZMP is the intersection of the extension line of the resultant force vector of gravity, inertial force and ground reaction force on the lower extremity exoskeleton and the ground. In order to make the lower extremity exoskeleton walk stably, the zero moment point (ZMP) should always be kept within the reasonable support area (stable area) of the convex polygon formed by the supporting feet (rods). The stable area is the projection of the convex area formed by the soles of the feet or the support rods on the horizontal plane.

This project uses the three-dimensional acquisition and positioning system of human motion images to collect images of the healthy side legs of hemiplegic patients who complete sitting ups, walking on flat ground, and going up and down stairs with the assistance of others; through the ariel biological operation analysis software, the corresponding leg movements of each operation mode are obtained parameter. Then import these motion parameters into the human body and exoskeleton model established by ADAMS for simulation, calculate the zero moment point ZMP trajectory, judge the stability during walking, and analyze the stability margin of gait.

(2) Drive motor control parameter design, import the joint motion parameters obtained by the ariel operation analysis software into the ADAMS exoskeleton model, simulate and calculate the rotation angle and speed parameters required by the two drive motors of the hip and knee joints, and the connection between the two drive motors. Axis motion control requirements. In order to find out the relationship between the control parameters of the hip and knee drive motors and the inclination angle of the support rod, the patient was asked to try on the exoskeleton prototype and complete various movements with the assistance of others. Obtain the functional relationship between the rotation angle and rotation speed of the drive motor of the support rod and the rotation angle and rotation speed of the hip and knee joint motors.

Advantages: Use the ariel operation analysis system to analyze the patient's normal leg movement to obtain control parameters, which is conducive to designing movements that meet the patient's habits. The gait analysis is carried out through the ZMP principle to improve the gait stability; the simulation is used to omit complex mathematical modeling, and the design process is simplified while ensuring the accuracy of the simulation.

A method for verifying the stability of the lower extremity exoskeleton for hemiplegic patients, comprising the following steps:

1) Using the three-dimensional acquisition and positioning system, the image of the healthy side leg of the hemiplegic patient completing sitting up, walking on flat ground, and going up and down stairs with the assistance of others is collected;

2) Through the ariel biological operation analysis software, the hip and knee joint motion angle and angular velocity function; the trajectory of key points and the velocity function curve are obtained;

3) Add the motion parameters of the hip and knee joints to the corresponding parts of the model, and simulate through the ADAMS software to find the rotation angle, speed and torque parameters of the driving motors of the hip and knee joints;

4) The patient tries on the exoskeleton prototype of this project to simulate several human body movements, and the telescopic motor of the support rod is manually controlled by others according to the needs of walking assistance;

5) Obtain the functional relationship between the rotation angle and rotation speed of the drive motor of the support rod and the rotation angle and rotation speed of the hip and knee joint motors;

6) Establish the exoskeleton and human body model through Solidworks and import them into ADAMS, set up relevant constraints and motion pairs; add the obtained motion parameters to the output shafts of each drive motor for simulation;

7) Simulation and calculation of the zero-moment point ZMP trajectory of the exoskeleton and human walking assistance process, and analysis of the stability margin.

Convert the position, speed, and torque parameters of each joint obtained in step 6) into control data of each drive motor and store them in the controller. When working, the controller controls each drive through a control strategy based on these data and sensor feedback data. motors to achieve the desired exoskeleton motion.

The control system design of the utility model

(1) This device takes the controller independently developed by the cooperative enterprise as the core to realize the coordinated control among the three driving motors of the hip joint, knee joint and support rod.

The controller has a 3-axis teaching function, which can memorize and reproduce the acceleration and deceleration curves of the three motors. Accordingly, it is convenient for the patient to adjust the action plan of the hip, knee, and telescopic rod according to his own habits.

(2) The device is equipped with the following detection devices, and pressure sensors are installed on the soles of the exoskeleton and the telescopic rods to determine whether the patient's soles and the telescopic rods are on the ground. Each driving motor is equipped with a rotary encoder, which is used to detect the movement position and speed of each joint, as well as the telescopic length of the support rod. An inclination angle sensor is installed on the support rod to detect the angle change of the support rod to realize the coordinated control of the support rod and the leg joint of the exoskeleton.

(3) Convert the position, speed and torque parameters of each joint obtained in step 6 into control data of each drive motor and store them in the controller. When working, the controller controls each drive motor through a certain control strategy based on these data and sensor feedback data to achieve the required exoskeleton actions.

The bone mentioned in the utility model is an artificial bone structure, and the joints mentioned are all artificial joint structures.

Claims (4)

1. A special lower extremity exoskeleton for hemiplegic patients, comprising a unilateral exoskeleton leg, a support rod mechanism, a controller and a battery, characterized in that: the unilateral exoskeleton leg includes a thigh bar, a calf bar, a sole boot, a connection The hip joint at the top of the thigh bar, the knee joint connecting the thigh bar and the calf bar, and the ankle joint connecting the calf bar and the sole boot, the support bar mechanism includes a support bar and a telescopic bar arranged at the bottom of the support bar, the thigh The rod is connected with the support rod through the hip joint, and the hip joint drive motor, the knee joint drive motor and the telescopic rod drive motor are sequentially arranged on the support rod from top to bottom, and the hip joint drive motor is connected to the hip joint through the hip joint worm gear. The drive motor of the knee joint is connected to the middle part of the calf rod through the worm gear of the knee joint and the swing rod of the knee joint. An ankle joint shock absorber is arranged between the calf rod and the sole boot, and the drive motor of the telescopic rod passes through a lead screw. The transmission structure is connected with the telescopic rod, and the controller and the battery are arranged on the support rod. 2. A lower extremity exoskeleton for hemiplegic patients according to claim 1, characterized in that: said calf rod is provided with a slide rail, and the bottom of said knee joint swing rod is connected to the slide rail by a slider, so that An underarm support bar is arranged on the top of the support bar, and shoulder straps are arranged on the underarm support bar. 3. The lower extremity exoskeleton for hemiplegic patients according to claim 2, characterized in that: the thigh bar is provided with thigh straps, the calf bar is provided with calf straps, and the upper part of the support bar is provided with There is a chest guard plate, and the chest guard plate is divided into left and right guard plates, and the left guard plate and the right guard plate are both connected to the support rod through the guard plate hinges. 4. A special lower extremity exoskeleton for hemiplegic patients according to claim 3, characterized in that: the ankle joint shock absorber is a shock absorber, the top of the shock absorber is hinged on the knee joint, and the shock absorber The bottom is hinged on the ankle joint. The control box is equipped with a controller to realize the coordinated control among the three drive motors of the hip joint, knee joint and support rod. The controller has a 3-axis teaching function, which can memorize and reproduce three axes. The acceleration and deceleration curves of the two motors are convenient for patients to adjust the action planning of the hip, knee and telescopic rod according to their own habits. A pressure sensor, each drive motor is equipped with a rotary encoder, which is used to detect the movement position and speed of each joint, and the telescopic length of the support rod. The tilt angle sensor is installed on the support rod to detect the angle change of the support rod, so as to realize the connection between the support rod and the support rod. Coordinated control of exoskeleton leg joints.