CN113633530A - Intelligent walking aid - Google Patents
Intelligent walking aid Download PDFInfo
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- CN113633530A CN113633530A CN202111134705.9A CN202111134705A CN113633530A CN 113633530 A CN113633530 A CN 113633530A CN 202111134705 A CN202111134705 A CN 202111134705A CN 113633530 A CN113633530 A CN 113633530A
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H3/00—Appliances for aiding patients or disabled persons to walk about
- A61H3/04—Wheeled walking aids for patients or disabled persons
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H3/00—Appliances for aiding patients or disabled persons to walk about
- A61H3/04—Wheeled walking aids for patients or disabled persons
- A61H2003/043—Wheeled walking aids for patients or disabled persons with a drive mechanism
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61H—PHYSICAL THERAPY APPARATUS, e.g. DEVICES FOR LOCATING OR STIMULATING REFLEX POINTS IN THE BODY; ARTIFICIAL RESPIRATION; MASSAGE; BATHING DEVICES FOR SPECIAL THERAPEUTIC OR HYGIENIC PURPOSES OR SPECIFIC PARTS OF THE BODY
- A61H3/00—Appliances for aiding patients or disabled persons to walk about
- A61H3/04—Wheeled walking aids for patients or disabled persons
- A61H2003/046—Wheeled walking aids for patients or disabled persons with braking means
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Abstract
The invention discloses an intelligent walking aid, which comprises a control system, wherein: control system includes main control unit, drive arrangement, security sensor module, power management module, wireless control module and supplementary module, its characterized in that: the main controller is respectively connected with the driving device, the safety sensor module, the power management module and the auxiliary module; the main controller is wirelessly connected with the wireless control module; the power management module determines whether to power on the driving device according to the human body state; the position sensor includes 1 infrared detection sensor and 3 ultrasonic sensors.
Description
The application is a divisional application of an invention patent application with the application number of '201810986449.8', the application date of 2018, 8 and 28 and the name of 'intelligent walking aid control system'.
Technical Field
The invention relates to an intelligent walking aid control system, in particular to a walking aid control system and a walking aid for helping old people and patients with walking dysfunction to walk, and belongs to the technical field of rehabilitation auxiliary appliances and mobile walking aids.
Background
For the disabled and the old with weak lower limb standing and walking ability, in daily life, when the disabled and the old need to solve the needs of going out and rehabilitation, the traditional walking aid cannot sense whether the human body stands at a safe and correct position, cannot detect the walking posture of the human body, cannot judge the road condition of the environment where the walking aid is located, and brings potential safety hazards to the people using the walking aid. The invention aims at the problems and provides an intelligent walking aid control system which is used for starting a walking aid by a user of the walking aid in a correct sitting posture state, safely and normally driving, detecting the walking posture of a human body in use and training the user to walk in a passive mode and an active mode. When a user operates the walking aid and meets the conditions of going up and down slopes, the system can control the walking aid to accelerate or decelerate according to the slope of the slope. The walking posture and the daily life condition of the user of the walking aid can be effectively improved, a brand-new and safe life style is brought to the user, and the rehabilitation level of the user and the comfort level of the user who uses the walking aid to go out are improved.
Disclosure of Invention
In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose:
the utility model provides an intelligence helps capable ware control system, includes main control unit, drive arrangement, safety sensor module, power management module, wireless control module and supplementary module, wherein: the main controller is respectively connected with the driving device, the safety sensor module, the power management module and the auxiliary module; the main controller is wirelessly connected with the wireless control module; the power management module determines whether to power on the driving device according to the human body state.
The control system described, wherein: the driving device comprises a first driver, a second driver, a left motor, a right motor and a Hall sensor; the safety sensor module comprises a position sensor, an inclination sensor and a pressure sensor; the power management module comprises a battery, a voltage conversion circuit and a power self-starting device, the self-starting device serves as a power switch and is in a normally open state to cut off power supply, after the position sensor detects that a human body is in a correct position and posture, whether a pressure sensor of the safety sensor module is stressed or not is judged, if the pressure is exerted, the switch of the self-starting device is closed at the moment, the power is switched on, and the driving device is in a power-on state.
The control system described, wherein: after the control system is powered on, the safety sensor sends the position information of the intelligent walking aid user to the main controller in real time, the main controller judges whether the user is at a safe position according to the received position information, if the user is at the safe position, the main controller continues to judge the pressure of the left handrail and the pressure of the right handrail, and if the pressure of the left handrail and the pressure of the right handrail are both greater than zero, the main controller controls the self-starting device of the power management module to supply power to the driving device of the walking aid; if the user is not in the safe position, the main controller controls the self-starting device of the power management module not to supply power to the driving device of the walking aid, and simultaneously controls the display module and the alarm device in the auxiliary module to send out an alarm signal which is not in the safe position.
The control system described, wherein: the position sensor comprises 1 infrared detection sensor and 3 ultrasonic sensors, wherein the first ultrasonic sensor and the second ultrasonic sensor are respectively arranged below the left handrail and the right handrail of the walking aid; the third ultrasonic sensor and the infrared detection sensor are arranged in the center of the front end of the seat cushion of the walking aid.
The control system described, wherein: the main control unit is to the judgement of safe position, it is through synthesizing the information that detects 1 infrared detection sensor and 3 ultrasonic sensor and judging and go on, namely, when infrared detection sensor detects that there is human activity before helping the capable ware handrail, and first ultrasonic sensor and second ultrasonic sensor detect the scope apart from human hip respectively within first predetermined range, and when third ultrasonic sensor detected human trunk apart from helping the capable ware within second predetermined range, main control unit judges that the human body is in the safe position of helping the capable ware, and main control unit starts intelligent helping the capable ware this moment.
The control system described, wherein: the safety sensor module further comprises pressure sensors, the pressure sensors are respectively arranged on a left hand handrail and a right hand handrail of the walking aid and used for detecting the pressure of a user holding the walking aid and transmitting the detected pressure value to the main controller in real time, and the main controller determines whether to start the walking aid, increase or decrease the walking speed of the walking aid and give an alarm according to the received pressure value.
The control system described, wherein: when the position sensor judges the safe position of the human body at the walking aid and the pressure sensors detect the pressure of the left handrail and the right handrail of the walking aid held by the hands of a user, the main controller sends a control signal to the self-starting device, the switch of the self-starting device is closed, the power management module starts to supply power to the first driver and the second driver of the driving device of the walking aid, and the left motor and the right motor start.
The control system described, wherein: in an initial state under a passive mode, a user holds a handrail of the walking aid to generate pressure, the walking aid walks forwards at the moment, a Hall sensor of a driving device feeds back the running condition of a left motor and a right motor to a main controller, a pressure sensor on the handrail records the pressure of a hand, the main controller judges which hand has large pressure in the initial state and detects the pressure value of the hand with large initial pressure in real time, and if the pressure value is gradually reduced, the main controller controls the speed of the walking aid to be gradually reduced until the walking aid stops; when the pressure value is gradually increased, the main controller controls the speed of the walking aid to be gradually increased, the safety sensor module of the walking aid judges the distance and the posture of the human body, and if the human body is in a safe position, the controller controls the speed of the walking aid to be continuously increased until the speed reaches the maximum speed of safe operation; if the human body is in the unsafe position, the main controller controls the speed of the walking aid to be gradually reduced until the human body is in the safe position.
The control system described, wherein: the safety sensor module also comprises an inclination sensor, the inclination sensor judges whether the walking aid is in an up-slope or down-slope state, the main controller controls the walking aid to accelerate when the walking aid is in the up-slope state, and the main controller controls the walking aid to decelerate when the walking aid is in the down-slope state.
The control system described, wherein: when the walking aid starts or stops, the main controller controls the speed change of the walking aid in a buffering mode.
The control system described, wherein: in the active mode, the main controller controls the walking aid to turn according to the pressure detection values of the left hand and the right hand of the user on the left handrail and the right handrail.
The control system described, wherein: the main controller judges the turning angle of the walking aid in the following way: setting the distance between two handrails of the walking aid as H, and converting the pressure value of the human body acting on the left and right handrails into an equivalent distance numerical value; setting a turning judgment model as a symmetrical quadrangle, setting two bottom edges as pressure equivalent distances and setting the height as the distance H between two handrails, setting the lengths of an upper bottom and a lower bottom as a and b respectively, wherein the upper bottom represents left-hand pressure and the lower bottom represents right-hand pressure, if a is not equal to b, the model is an isosceles trapezoid, calculating an included angle phi between the waist and the upper bottom of the trapezoid, and when the phi is more than 0, controlling the walking aid to turn left by a main controller; when phi is less than 0, the main controller controls the walking aid to turn right.
The control system described, wherein: the auxiliary module includes response hand brake, human information sensor and display module, and the user passes through the response hand brake in the auxiliary module of control, and the speed of motor about the adjustment helps the capable ware, and the auxiliary module detects the user rhythm of the heart and sends for main control unit through the human information sensor on the handrail, and display module shows user rhythm of the heart, road conditions information and speed information.
The control system described, wherein: the safety sensor module comprises an inclination sensor, the inclination sensor is installed in a main frame of the intelligent walking aid, the inclination sensor is parallel to a perpendicular line where the center of gravity of the walking aid is located, the walking aid moves in 4 directions including forward tilting, backward tilting, left side tilting and right side tilting, and the measured variation of the perpendicular line of the center of gravity of the walking aid is transmitted to the main controller in real time.
The control system described, wherein: when the walking aid is on flat ground, the value of the vertical line of the gravity center of the walking aid measured by the inclination sensor is (0, 0), when the walking aid ascends, descends, inclines on the left side and inclines on the right side, the two-dimensional value of the vertical line of the gravity center of the walking aid measured by the inclination sensor is (X, Y), the measured two-dimensional value is divided into a coordinate system with 4 quadrants, X is larger than 0 and represents an ascending slope, X is smaller than 0 and represents a descending slope, Y is larger than 0 and represents a left inclining, Y is smaller than 0 and represents a right inclining, the maximum limit threshold value of the system is preset, the maximum limit threshold value of the ascending slope and the descending slope is X and-X, and the maximum limit threshold value of the left-right inclining is Y and-Y.
The control system described, wherein: the main control unit compares the up-down slope numerical value of the walking aid gravity center perpendicular line detected by the inclination sensor with the preset up-down slope maximum limit threshold value in real time, when the inclination sensor measures that the absolute value of the walking aid gravity center perpendicular line is greater than the absolute value of the preset up-down slope maximum limit threshold value, the main control unit controls the display module and the alarm module of the auxiliary module to send alarm signals to prompt slope danger, and the main control unit sends stop signals to the driving device, and the motor stops.
The control system described, wherein: the main control unit compares the left and right inclination values of the vertical lines of the gravity center of the walking aid detected by the inclination sensor with the preset left and right inclination maximum threshold values in real time, when the inclination sensor measures that the absolute value of the vertical lines of the gravity center of the walking aid is greater than the absolute value of the preset left and right inclination maximum threshold values, the main control unit controls the display module and the alarm module of the auxiliary module to send alarm signals to prompt that the walking aid is inclined, the main control unit sends stop signals to the driving device, and the motor stops running.
The control system described, wherein: when a user operates the wireless control module, after the key is pressed down, a corresponding key information instruction is sent to the main controller in a wireless communication mode, and the main controller controls the driving device according to corresponding information to control the left motor and the right motor to be started or closed or control the motors to rotate forward and backward so as to realize forward and backward running of the walking aid.
The control system described, wherein: when the walking aid is in motion, the main controller controls the speed of the walking aid to be gradually reduced until the speed of the walking aid is 0 when the main controller judges that the human body is not at the safe position and in the incorrect posture, the main controller judges the position of the human body when the walking aid is stopped, if at least one of the first ultrasonic sensor and the second ultrasonic sensor detects that the range from the hip of the human body is less than 25cm and/or the third ultrasonic sensor detects that the trunk of the human body is less than 55cm away from the walking aid, the main controller sends a signal to the driving device to control the driver 1 and the driver 2 to enable the left motor and the right motor to continue to move forwards until the first ultrasonic sensor and the second ultrasonic sensor detect that the range from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the distance between the trunk of the human body and the walking aid is 55cm, and the human body stops following; if at least one of the first ultrasonic sensor and the second ultrasonic sensor detects that the distance from the hip of the human body is more than 45cm, and/or the third ultrasonic sensor detects that the distance from the trunk of the human body to the walking aid is more than 75cm, the main controller sends a signal to the driving device to control the driver 1 and the driver 2 to enable the left motor and the right motor to move in opposite directions relative to the walking aid before stopping until the first ultrasonic sensor and the second ultrasonic sensor detect that the distance from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the distance from the trunk of the human body to the walking aid is less than 75cm and stops following.
The control system described, wherein: the timer of the main controller records the speed of the walking aid in real time according to time periods, and when the speed of the walking aid exceeds a preset speed value during turning, the main controller decelerates the walking aid and turns.
The control system described, wherein: the main controller scans and detects the value change of the pressure sensor at regular time, if the pressure change amplitude is too large, the abnormal condition is judged, and the main controller does not turn the walking aid.
The control system described, wherein: the main controller judges the variation of the turning angle phi within the preset time range, and if the variation exceeds a preset value, the main controller does not respond to the turning instruction any more and does not turn the walking aid.
An intelligent walker comprising a control system as described in one of the above.
Drawings
FIG. 1 is a schematic diagram of a control system for an intelligent walker;
FIG. 2 is an equivalent diagram of a model for calculating the turning angle of the intelligent walker;
FIG. 3 is a schematic view of an intelligent walker ascending and descending, and left and right dumping to set a safe zone;
fig. 4 is a schematic view of a position sensor arrangement.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings, 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. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.
As shown in FIG. 1, the intelligent walker control system of the present invention comprises: the device comprises a main controller, a driving device, a safety sensor module, a power management module, a wireless control module and an auxiliary module. The main controller is respectively connected with the driving device, the safety sensor module, the power management module, the auxiliary module and the wireless control module, and the power management module provides power for the control system.
The driving device comprises a driver 1, a driver 2, a left motor, a right motor and a Hall sensor; the safety sensor module comprises a position sensor, an inclination sensor and a pressure sensor; the power management module comprises a battery, a voltage conversion circuit and a power supply self-starting device, the power supply of the main controller and each sensor module is provided by the voltage conversion circuit, the self-starting device is used as a power switch and is in a normally open state, the power supply of the driving device is cut off, when the position sensor detects that a human body is in a correct position and a posture, the main controller judges whether the pressure sensor of the safety sensor module is under pressure or not, if the pressure is applied, the main controller controls the self-starting device to be closed, the power supply is switched on, and the driving device of the intelligent walking aid is in a power-on state.
The specific control process is as follows; after the control system is powered on, the position sensor sends the position information of the intelligent walking aid user to the main controller in real time, the main controller judges whether the user is in a safe position according to the received position information, and if the user is in the safe position, the main controller continues to judge the handrail pressure of the walking aid; if the user is not in the safe position, the main controller controls the self-starting device of the power management module not to supply power to the driving device of the walking aid, and simultaneously controls the display module and the alarm device in the auxiliary module to send out an alarm signal which is not in the safe position.
As shown in fig. 4, the position sensor comprises 1 infrared detection sensor and 3 ultrasonic sensors, wherein the first ultrasonic sensor and the second ultrasonic sensor are respectively arranged below the left handrail and the right handrail of the walking aid, the detection of the hip of the human body by the ultrasonic sensors cannot be influenced after the handrails are held by the hands of a user, and the safety distance is within the range of 25cm-45cm away from the hip of the human body. The basic reason of the above arrangement is that the legs swing back and forth during walking, which is not beneficial to detecting the distance, the distance between the hip of the human body and the walking aid is stable, the hip posture is an important reference for the walking posture, and many patients needing walking assistance have the phenomenon of hip swing walking according to clinical experience, in order to correct the walking posture, the ultrasonic sensor is adopted to detect the hip of the human body, and the range from the hip of the human body is set to be 25cm-45 cm.
The third ultrasonic sensor and the infrared detection sensor are arranged in the center of the front end of the seat cushion of the walking aid and are used for detecting a human body, and the third ultrasonic sensor detects that the distance between the trunk of the human body and the front end of the walking aid is between 55cm and 75cm and is a safe distance. The infrared detection sensor detects that the human body moves in front of the handrail of the walking aid and sends an electric signal to the main controller. The arrangement is mainly used for considering that the posture of the trunk part of a human body influences walking efficiency and gravity center during walking, if the posture of the trunk part of the human body is incorrect and contains a humpback, not only the gait of the human body is changed, but also the pressure of a person holding the walking aid is increased, and the detection of the armrest pressure of the walking aid is influenced; more importantly, the gravity center of the walking posture of the human body is on the walking aid for a long time, so that the human body completely depends on the walking aid, and the independent walking and the complete rehabilitation of the human body are not facilitated. Therefore, the distance between the trunk of the human body detected by the third ultrasonic sensor and the front end of the walking aid is set to be reasonable between 55cm and 75 cm.
The main controller judges the safe position and the correct posture by comprehensively judging the information detected by 1 infrared detection sensor and 3 ultrasonic sensors, namely, when the infrared detection sensors detect that the human body moves in front of the handrail of the walking aid, the first ultrasonic sensor and the second ultrasonic sensor respectively detect that the range from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the distance from the trunk of the human body to the walking aid is between 55cm and 75cm, the human body is judged to be in the safe position of the walking aid, and at the moment, the power supply self-starting device of the intelligent walking aid can be started.
The main controller judges the pressure of the handrail of the walking aid in the following ways: the safety sensor module further comprises pressure sensors which are respectively arranged in two areas of the walking aid: the left hand handrail and the right hand handrail are used for detecting the pressure of the user for holding the walking aid and transmitting the detected pressure value to the main controller in real time, and the main controller determines whether to start the walking aid, increase or decrease the walking speed of the walking aid and give an alarm according to the received pressure value
When the position sensor judges the safe position of the human body at the walking aid and the pressure sensor detects the pressure of the walking aid supported by both hands of the user, the main controller sends a control signal to the self-starting device, the switch of the self-starting device is closed, the power management module starts to supply power to the drivers 1 and 2 of the walking aid driving device, and the left motor and the right motor start. Generally speaking, when the left handrail pressure value and the right handrail pressure value received by the main controller are both larger than zero, the main controller starts the walking aid, namely the main controller controls the switch of the self-starting device to be closed, the power supply is switched on, the driving device of the intelligent walking aid is in a power-on state, and the walking aid starts to move. Otherwise, the main controller considers the walking to be misoperation and does not start the walking aid.
The invention adjusts the assistance mode according to the pressure applied by the user to the armrest, and sets the assistance mode to be a passive assistance mode and an active assistance mode respectively. In the passive mode, the main controller limits the walking aid not to turn, and the speed of the walking aid is automatically adjusted according to the pressure applied by the user on the handrail and the road conditions (flat ground, ascending slope or descending slope), so as to drive the user to walk. In the active mode, the master controller allows the walker to turn.
In the passive mode, in the initial condition, a user holds the handrail of the walking aid with a hand to generate pressure, the walking aid walks forwards, the Hall sensor of the driving device feeds back the movement speed and other conditions of the left motor and the right motor to the main controller, the pressure sensor on the handrail records the pressure of the hand of the user, the pressure of the left handrail is set to be A10 at the moment, the pressure of the right handrail is set to be A20, the maximum one of the two values of A10 and A20 is set to be A0, namely the pressure of the walking aid pushed by the user in the passive mode is set to be A0 in the initial condition, the pressure value A0 of the hand with the large initial pressure is detected, and if the pressure A0 is gradually reduced, the main controller controls the speed of the walking aid to be gradually reduced until the walking aid stops; when the pressure A0 is gradually increased, the main controller controls the speed of the walking aid to be gradually increased, the distance and the posture of the human body are judged by the safety sensor module of the walking aid according to the judgment standard, the judgment standard is the judgment of the safety position (namely the comprehensive judgment of information detected by 1 infrared detection sensor and 3 ultrasonic sensors, when the infrared detection sensor detects that the human body moves in front of the handrail of the walking aid, the first ultrasonic sensor and the second ultrasonic sensor respectively detect that the distance from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the distance from the trunk of the human body is between 55cm and 75cm, the human body is judged to be at the safety position of the walking aid), if the human body is at the safety position, the walking aid judges that the human body can well follow, the speed of the walking aid is continuously increased until the speed reaches the maximum speed of safe operation, for example 5 km/h; if the human body is in an unsafe position, and/or the infrared detection sensor detects that no human body moves in front of the handrail of the walking aid, and/or at least one of the first ultrasonic sensor and the second ultrasonic sensor detects that the distance from the hip of the human body is out of the range of 25cm-45cm, and/or the third ultrasonic sensor detects that the distance from the trunk of the human body to the walking aid is out of the range of 55cm-75cm, the main controller of the walking aid judges that the human body cannot follow, and the main controller controls the speed of the walking aid to gradually reduce until the human body is in a safe position and in a correct posture.
The walking aid is provided with following states in an active mode and a passive mode, namely: when the walking aid is in motion, the main controller controls the speed of the walking aid to be gradually reduced until the speed of the walking aid is 0 when the main controller judges that the human body is not at the safe position and in the incorrect posture, the main controller judges the position of the human body when the walking aid is stopped, if at least one of the first ultrasonic sensor and the second ultrasonic sensor detects that the range from the hip of the human body is less than 25cm and/or the third ultrasonic sensor detects that the trunk of the human body is less than 55cm away from the walking aid, the main controller sends a signal to the driving device to control the driver 1 and the driver 2 to enable the left motor and the right motor to continue to move forwards until the first ultrasonic sensor and the second ultrasonic sensor detect that the range from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the human trunk stops following when the distance between the human trunk and the walking aid is 55cm, namely the main controller does not actively adjust the speed of the walking aid any more. Similarly, if at least one of the first and second ultrasonic sensors detects that the range from the hip of the human body is more than 45cm, and/or the third ultrasonic sensor detects that the trunk of the human body is more than 75cm from the walker, the main controller sends a signal to the driving device to control the driver 1 and the driver 2 to move the left and right motors in opposite directions relative to the walker before stopping until the first and second ultrasonic sensors detect that the range from the hip of the human body is between 25cm and 45cm, and the third ultrasonic sensor detects that the trunk of the human body is less than 75cm from the walker to stop following.
Under the condition of ascending and descending slopes, whether the walking aid is ascending and descending is judged by the inclination sensor, the ascending is assisted acceleration, and the descending is assisted deceleration. The safety position of the human body still needs to be judged by adjusting the speed, the judgment of the safety position is the same as that of the human body, and when the human body is not in the safety position, the main controller controls the walking aid to decelerate. The slope of the up-slope and the down-slope of the standard barrier-free passage is 1:8 indoors and 1:10 outdoors, the slope is fixed and unchanged, and the influence on the position of the detected human body relative to the walking aid is small, so that the method for judging the safe position of the human body by using the flat ground is used for judging the safe position of the human body in the up-slope and down-slope states.
The invention provides buffering for start and stop of the walking aid (the speed is not immediately 0 and is gradually increased or decreased, and the buffering speed of acceleration and deceleration is 5 seconds when the speed is reduced from 5 km/h to 0). The passive power-assisted mode focuses more on torque output and enhances the dynamic property of the walking aid. When the walking aid is used, the safety sensor module monitors the balance state (namely, the states of ascending, descending and left-right dumping) in real time through the inclination sensor and sends the state information to the main controller, and the walking aid is decelerated before the walking aid has the states of ascending, descending and left-right dumping, so that the situation that the walking aid is too fast, a user cannot walk to keep up with the walking aid, the situation that the walking aid is too slow and the user trips are avoided.
In the active mode, the walking condition of the user can adapt to the walking aid, and the user actively exerts force to control the speed of the walking aid, namely the walking assisting speed of the walking aid is adjusted according to the pressure generated by the human body acting on the handrail of the walking aid when the user pushes the walking aid; the walking aid has the advantages that the walking aid is provided with power assisting function when ascending a slope, the damping is increased when descending the slope, and in an active mode, the main controller can allow the walking aid to turn according to the pressure detection values of the left hand and the right hand of a person on the left handrail and the right handrail, so that the walking aid can provide the training of turning and walking for a patient.
FIG. 2 is an equivalent diagram of a model for calculating the turning angle of the intelligent walker under the active mode;
the main controller judges the turning angle of the walking aid as follows: as shown in figure 2, the distance between the two armrests of the walking aid is H, the pressure value of the human body acting on the pressure sensor 1 on the left armrest is F1, the pressure value of the human body acting on the pressure sensor 2 on the right armrest is F2, and in order to establish a model of the pressure and the distance of the human body, the left armrest and the right armrest are usedThe pressure values are converted into equivalent distance values (e.g., the pressure value applied to the handrail by the user is 20N, the relative voltage signal displayed by the sensor is 0.2V, and the distance equivalent value is 0.2 m; for convenience of calculation, the pressure equivalent values on the left and right handrails can be scaled up and down). That is, assuming that the model is a symmetrical quadrilateral, the two bottom sides are equivalent pressure distances, the height is the distance H between the two handrails, the lengths of the upper bottom and the lower bottom are set as a and b, respectively, the upper bottom represents left-hand pressure, the lower bottom represents right-hand pressure, if a ≠ b, the model is an isosceles trapezoid, as shown in fig. 2, an included angle phi (-90 < phi < 90), phi ═ arctan [ (b-a)/2H]. When phi is larger than 0, the main controller controls the walking aid to turn left; when phi is less than 0, the main controller controls the walking aid to turn to the right; because the walking speed of the walking aid pushed by a user is slow, the walking aid can sway left and right when the user walks forwards, a certain influence can be generated on the calculated angle phi, and in order to eliminate the error of the left and right sway of the walking aid and prevent the control system from misjudging the turning, a turning threshold phi is set0(e.g., phi-05 °), i.e. when phi is greater than phi0When the walking aid is used, the main controller controls the driving device, and the rotating speed of the right motor is increased relative to that of the left motor, so that the walking aid turns left; when phi is less than-phi0When the walking aid is used, the main controller controls the driving device, and the rotating speed of the left motor is increased relative to that of the right motor, so that the walking aid turns to the right.
Further, for safety reasons, the speed of the walker during the turn is dimensioned as follows: and setting a timer of the main controller to record the speed of the walking aid in real time according to the time period, adjusting the relative speeds of the left motor and the right motor according to the calculated phi angle value and the speed of the walking aid in a period of time before the walking aid, and when the speed of the walking aid exceeds a set value (for example, 4.5 kilometers per hour), decelerating the walking aid and turning. Under the mode of turning, focus on the wider rotational speed interval of subdivision more and obtain better followability and turn security, because the speed that the user pushed the capable ware is very slow, the condition of sharp turn can not appear in the capable ware of helping, for example the sudden change can not appear in the turn, if the condition that the turn angle increases unusually. For safety reasons it is not possible to turn the walker with a large turning angle, so the maximum turning angle is set to 45 ° to ensure safe turning. In addition, since the human reaction rate is generally 0.1 second or more, the timer of the main controller periodically scans and detects the change in the value of the pressure sensor at a cycle of 0.1 second, and if the pressure change width is found to be too large, it is determined that there is an abnormality. Because the person makes the instruction that needs to turn and controls the pressure sensor to carry out the action of turning to the hand, the fastest response time that needs under general conditions is 0.1-0.5 s. Therefore, the abnormal condition comprises that the variation of phi can be judged within a preset time range (can be selected within the range of 0.1s-0.5s according to requirements), if phi suddenly changes by more than +/-45 degrees within the preset time range, the error operation of the pressure of the human body on the walking aid is considered, the main controller does not respond to the turning instruction any more, and the walking aid is not turned. By this turning safety control measure, an abnormal situation can be excluded.
The auxiliary module comprises an induction hand brake, a human body information sensor and a display module, the speed of a left motor and a right motor of the walking aid is adjusted by controlling the induction hand brake in the auxiliary module, the auxiliary module detects the heart rate of a user and sends the heart rate to the main controller through the human body information sensor on the handrail, and the display module displays the heart rate of the user, road condition information (ascending, descending and the like) and speed information. By the intelligent walking aid control system, the use safety and the convenience degree of a user are improved.
FIG. 3 is a schematic diagram of an intelligent walking aid for setting safe regions for ascending and descending, and left and right toppling. The detection of the upward and downward slope and the left and right toppling is completed by a tilt sensor, the tilt sensor is arranged in a main frame of the intelligent walking aid, is parallel to a vertical line of the gravity center of the walking aid, moves in 4 directions of forward tilting, backward tilting, left tilting and right tilting of the walking aid, and transmits the measured variation of the vertical line of the gravity center of the walking aid to a main controller in real time. When the walking aid is on flat ground, the value of the vertical line of the gravity center of the walking aid measured by the inclination sensor is (0, 0), when the walking aid ascends, descends, inclines left and inclines right, the value of the vertical line of the gravity center of the walking aid measured by the inclination sensor changes, the two-dimensional value is (X, Y), the measured two-dimensional value is divided into a coordinate system with 4 quadrants, X is greater than 0 and represents ascending, X is less than 0 and represents descending, Y is greater than 0 and represents inclining left, Y is less than 0 and represents inclining right, the maximum limit threshold value of the system is preset, the maximum limit threshold value of the ascending and descending is X and-X, and the maximum limit threshold value of the left and right inclining is Y and-Y.
The main controller compares the up-down slope numerical value (namely +/-X numerical value) of the vertical line of the gravity center of the walking aid detected by the tilt sensor with the preset up-down slope maximum limit threshold value (X and-X), when the absolute value of the vertical line of the gravity center of the walking aid measured by the tilt sensor is greater than the preset up-down slope maximum limit threshold value, the main controller controls the display module and the alarm module of the auxiliary module to send out alarm signals to prompt slope danger, the walking aid must stop, the main controller sends out stop signals to the driving device, and the motor stops. The main controller judges that the walking aid is in a downhill state, and controls a driving motor of the driving device to rotate in a speed reducing mode at the time, so that the rotating speed of the walking aid is reduced, and the safety is improved; the main controller judges that the walking aid is in an ascending slope, and controls the driving motor of the driving device to rotate in an accelerating mode at the moment, so that the rotating speed of the walking aid is increased, and climbing is facilitated.
The main controller compares the left and right inclination values, namely +/-Y values, of the vertical line of the gravity center of the walking aid detected by the inclination sensor with a preset left and right toppling maximum threshold value (Y and-Y), when the inclination sensor measures that the value of the vertical line of the gravity center of the walking aid is larger than the preset left and right toppling maximum threshold value, the main controller controls the display module and the alarm module of the auxiliary module to send out alarm signals to prompt that toppling danger exists, the walking aid must stop, the main controller sends out stop signals to the driving device, and the motor stops running. The main controller obtains the shadow area in the graph as the safe driving area of the walking aid according to the superposition area of the maximum limit threshold values of ascending and descending and left and right dumping in the coordinate system, and in the area, the main controller does not control the operation of the walking aid in the way.
The wireless control module is a wireless control device worn by a user, controls the walking aid driving device through Bluetooth to control the forward or backward movement of the left and right motors, controls the walking aid to approach the user when the user is far away from (visible to) the walking aid, and can place the walking aid in a controllable range without independent walking so as to facilitate the walking of the walking aid at any time; the walking aid can also be operated to walk slowly when the walking aid is resting on the walking aid, and the walking aid can be used in place of a wheelchair. The wireless control device worn by the user is provided with 5 keys which comprise a switch key, a left motor selection key, a right motor selection key, a forward key and a backward key. The switch key is used for switching on or off the wireless control device; the left motor selection key is used for selecting the left motor to be turned on or turned off, the right motor selection key is used for selecting the left motor to be turned on or turned off, and the left motor selection key and the right motor selection key can be turned on simultaneously or independently; the forward key is used for controlling the motor to rotate forward so that the motor drives the walking aid to move forward; the backward key is used for controlling the motor to rotate reversely, so that the motor drives the walking aid to run backwards. When a user operates the wireless control module, after the key is pressed down, a corresponding key information instruction is sent to the main controller in a wireless communication mode, and the main controller controls the driving device according to corresponding information to control the left motor and the right motor to be started or closed or control the motors to rotate forward and backward so as to realize forward and backward running of the walking aid.
The device can real-time recording and save the motion state of helping capable ware, including the human posture data of at every turn using, walking mileage and speed, help capable ware motion pattern, road conditions etc. can upload the high in the clouds with helping capable ware user's these data through wiFi for follow-up analysis helps the in service behavior of capable ware, makes things convenient for development APP software, helps capable the instruction for helping capable ware user provides to help.
The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.
Claims (3)
1. An intelligence helps capable ware, includes control system, its characterized in that: control system includes main control unit, drive arrangement, security sensor module, power management module, wireless control module and supplementary module, its characterized in that: the main controller is respectively connected with the driving device, the safety sensor module, the power management module and the auxiliary module; the main controller is wirelessly connected with the wireless control module; the power management module determines whether to power on the driving device according to the human body state; the position sensor includes 1 infrared detection sensor and 3 ultrasonic sensors.
2. The control system of claim 1, wherein: the driving device comprises a first driver, a second driver, a left motor, a right motor and a Hall sensor; the safety sensor module comprises a position sensor, an inclination sensor and a pressure sensor; the power management module comprises a battery, a voltage conversion circuit and a power self-starting device.
3. The control system of claim 2, wherein: the safety sensor module also includes a pressure sensor.
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