CN211214227U

CN211214227U - Walking following rehabilitation training equipment

Info

Publication number: CN211214227U
Application number: CN201920264054.7U
Authority: CN
Inventors: 王天
Original assignee: Hangzhou Chengtian Technology Development Co Ltd
Current assignee: Hangzhou Chengtian Technology Development Co Ltd
Priority date: 2019-03-02
Filing date: 2019-03-02
Publication date: 2020-08-11
Anticipated expiration: 2029-03-02

Abstract

The utility model relates to a follow rehabilitation training device walks mainly comprises lifting support, walking base and cantilever rings, installs sensor and wheelset portion on the walking base. The automatic following control method is characterized in that the positions of detected parts of crus at two sides are detected through sensors, so that the motion trend of a human body is judged, and the motion of the walking following rehabilitation training device automatically following the motion trend of a user is realized by controlling the hub type Mecanum wheels. The structure and the method have clear control logic, simple equipment structure and the functions of hanging the human body, preventing falling down, reducing weight, automatically following, judging walking trend, damping, buffering and the like. The device has good help function for rehabilitation training, does not limit the movement range of the user, can walk freely, and has positive significance for the rehabilitation of the user.

Description

Walking following rehabilitation training equipment

Technical Field

The utility model relates to a supplementary rehabilitation training's equipment specifically says so and is exactly a walking following rehabilitation training equipment.

Background

In order to prevent muscular atrophy caused by long-term bed rest, patients with damaged lower limbs due to accidents, injuries and the like often need to continuously perform standing and walking training to achieve the purpose of rehabilitation. In addition, the weakness of the leg muscles of the elderly often causes the mobility of the elderly to be inconvenient and even the mobility of the elderly to be lost, and the life quality of the elderly is seriously affected.

In the prior art, patent application numbers 2012100608925 and 2015205878671 disclose an electric wheelchair and an electric medical bed chair capable of moving in all directions, but both have no automatic following function and can only move in all directions under the control of people. And has no function of lower limb training and rehabilitation.

The single-drive bionic gait rehabilitation training robot system with application number 2016210419406 has a control system controlling two exoskeleton walking mechanisms to realize the alternate gait motion of a sound person and achieve the coordination of a medical running platform and the bionic gait robot according to preset parameters. But training can be carried out only in fixed places and positions, and the functions of automatic following and omnidirectional movement are not provided. The weight reduction device of the lower limb rehabilitation equipment with the application number of 201720725354.1 and the weight reduction device for rehabilitation training with the application number of 201810128019.2 can realize the weight reduction function of lower limb exercise. But does not have the automatic following and walking function.

The patent application No. 2017100595330 discloses a robot protection frame which can protect a robot from being beaten during operation but does not have an automatic guiding function.

Application number 201711254276.2 is walking trainer for orthopedics rehabilitation, can subtract heavy to the human body, alleviates the pressure of backbone and low limbs, and adjusts according to the difference of human height, but can only go on straightly, does not have the function of automatic following and omnidirectional movement. The automatic following infusion support with the application number of 2015109836992 can automatically follow, but the principle is that the following is executed by judging the relative distance and the direction between a human body and the whole infusion support, the trend cannot be actively judged, and the follow-up is only passive.

A movable parallel flexible cable driven lower limb rehabilitation robot with application number 201810407801.8 and an implementation method thereof, a leg wearing device is pulled by a flexible cable to drive a diseased limb to realize rehabilitation training; the front part of the bottom of the robot is provided with a universal driven wheel, and the rear part of the bottom of the robot is provided with a rear driving wheel. The robot can realize the gait training and the walking training in a passive mode, an assisted mode and an active mode. The human body is passive traction rehabilitation training. And does not have the function of automatic actuation following.

In summary, in the prior art, none of apparatuses for lower limb rehabilitation exercise includes: hang, prevent falling, subtract heavy, automatic following, walking trend judgement, shock attenuation and function rehabilitation equipment in an organic whole such as buffering.

SUMMERY OF THE UTILITY MODEL

In order to deal with the existing among the prior art not enough with optimize prior art, the utility model provides a walk and follow rehabilitation training device, and use the automatic following control method of this equipment.

The main technical scheme of the walking following rehabilitation training equipment is as follows:

mainly by lifting support (1), walking base (2) and cantilever rings (13) are constituteed, install on its characterized in that walking base (2): the device comprises a sensor (5), a wheel set part (3) and a motion trend control module; the motion trend control module is arranged in the electric control cabinet (8) and is electrically connected with the sensor (5).

The sensor (5) is a non-contact distance detection sensor; the sensor mounting frame (4) is vertically arranged between the chassis cross beams (6), and the sensor (5) is arranged on the sensor mounting frame (4); the sensor (5) emits a light signal or a sound wave signal toward the examined parts (181) of the lower legs on both sides.

The wheel set section (3) is formed by hub type Mecanum wheels (31) mounted on the chassis cross member (6). The hub-type mecanum wheel (31) has the capability of omnidirectional movement. And the Mecanum wheel with the motor at the wheel hub part is selected, so that the Mecanum wheel has self-driving capability and simplifies the structure.

The position information of the detected parts (181) of the shanks at the two sides is detected by the sensor (5), and the motion trend control module judges the motion trend direction of the human body (18) according to the position information, so that the wheel set part (3) is controlled to move towards the trend direction.

The whole body is C-shaped, and the human body (19) can be suspended by the cantilever hoisting ring (13).

The automatic following control method uses the walking following rehabilitation training device to carry out walking trend judgment and control strategies in the following modes:

a) the human body (18) wears an exoskeleton machine (19); the exoskeleton machine (19) is connected with a hanging strip (17) on the cantilever (14) through a hanging hook (172). The user is in a ready state.

b) The lower leg examined part (181) is positioned in front of the sensor (5).

c) The sensor (5) emits laser or ultrasonic waves to detect the distance between the two shank examined parts (181) and the sensor (5) and the distance between the two shank examined parts (181); the motion trend direction of the human body (18) is judged through a preset judgment mode of the motion trend control module. The distance between each of the two shank examined parts (181) and the sensor (5) is judged through the reflected wave, the distance between the two shank examined parts (181) is judged at the same time, and the included angle between the connecting line between the two shank examined parts (181) and the sensor mounting frame (4) is judged. The movement trend of the user is judged according to the data.

d) By controlling the wheel hub type Mecanum wheel (31), the walking following rehabilitation training equipment automatically follows the movement trend of the user.

The structure and the method have clear control logic, simple equipment structure and the functions of hanging the human body, preventing falling down, reducing weight, automatically following, judging walking trend, damping, buffering and the like. The device has good help function for rehabilitation training, does not limit the movement range of the user, can walk freely, and has positive significance for the rehabilitation of the user.

Drawings

The present invention will be further described with reference to the accompanying drawings.

Fig. 1 is a perspective view of the whole usage state of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a view of the base portion of the present invention.

Fig. 4 is a diagram of a hub-type mecanum wheel and a buffer device according to the present invention.

Figure 5 is the utility model discloses shock attenuation and suspender diagram.

Figure 6 is a three-dimensional view of the shock absorbing and hanging strip of the present invention.

Fig. 7 is a diagram of the direct-acting push rod of the present invention.

Wherein:

1-lifting support, 2-walking base, 3-wheel group part, 31-hub Mecanum wheel, 32-hub, 33-bearing seat plate, 34-damping sliding sleeve, 35-damping spring, 36-hinge part, 37-hinge plate, 38-beam fixed plate, 4-sensor mounting frame, 5-sensor, 6-chassis beam, 7-connecting longitudinal beam, 8-electric control cabinet, 9-fixed support, 10-telescopic support, 11-translational push rod, 111-lower push rod hinge part, 112-upper push rod hinge part, 113-S-shaped weighing sensor, 12-handrail, 13-cantilever lifting ring, 14-cantilever, 15-damping lifting ring part, 151-damper pressing plate, 152-guide shaft, 153-shaft sleeve, 154-damper mounting block, 155-cantilever connecting end, 156-lifting ring pulling plate, 16-damper, 17-lifting belt, 171-rotary lifting ring, 172-lifting hook, 18-human body, 181-shank examined part, and 19-exoskeleton machine.

Detailed Description

Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.

As shown in fig. 1-7:

as shown in fig. 2, a main technical solution of a walking following rehabilitation training device is as follows: mainly by lifting support (1), walking base (2) and cantilever rings (13) are constituteed, install on walking base (2): a sensor (5) and a wheel set part (3). The sensor (5) is a non-contact distance detection sensor.

The sensor mounting frame (4) is further included; the sensor mounting frame (4) is vertically arranged between the chassis cross beams (6), and the sensor (5) is arranged on the sensor mounting frame (4). The sensor (5) emits a light signal or a sound wave signal toward the examined parts (181) of the lower legs on both sides.

The electric control cabinet (8) is internally provided with a battery, a motion trend control module and other control devices which are connected with each controlled part through wires.

The positions of the detected parts (181) of the shanks at the two sides are detected by the sensors (5), so that the movement trend direction of the human body (18) is judged, and the wheel set part (3) is controlled to move towards the trend direction.

Fig. 3, as a first preferred embodiment, the sensors (5) are installed in a plurality of equal parts along the straight line of the sensor mounting frame (4); the sensor (5) is a laser sensor or an ultrasonic sensor. Any sensor may be used as long as it can detect a linear distance, and the sensor is not limited to the above two types, and may be a non-contact sensor such as an infrared distance measuring sensor or a 24GHZ radar sensor.

Fig. 3, as a second preferred embodiment, if a single sensor is selected, in order to obtain a plurality of distance values of the examined part (181) of the lower leg, a plurality of sensors (5) need to be configured, and the number of the sensors (5) is 4-20. And the distance between the adjacent sensors (5) is controlled within 5 cm.

As a third preferred embodiment, the sensor (5) can also be a laser radar; the laser radar is arranged in the middle of the sensor mounting frame (4). The laser radar that the present case chose for use is 360 laser scanning range radar, only install one can, further reduced the complexity of equipment. If the laser scanning range radar with the model number of LIDAR RPLIDAR-A3 is selected, the scanning frequency is 16000 times per second, the position data of the detected parts (181) of the shanks at two sides can be sufficiently established, and the laser scanning range radar can be used indoors and outdoors.

Fig. 7 is a fourth preferred embodiment, which is characterized in that the lifting support (1) further comprises a linear motion push rod (11), the lower part of the linear motion push rod (11) is connected with a lower hinge part (111) of the push rod, the upper part of the linear motion push rod is connected with an upper hinge part (112) of the push rod, the telescopic support (10) is pushed and pulled to extend through the linear motion push rod (11), and the height of the cantilever hanging ring (13) is adjusted according to users with different heights and recovery conditions.

Fig. 5 and 6, as a preferred embodiment five, the said boom hoist link (13) includes the boom (14) and the sling (17), characterized in that a shock absorbing sling part (15) is installed between the boom (14) and the sling (17); the shock absorption lifting ring part (15) consists of a damper pressure plate (151), a guide shaft (152), a shaft sleeve (153), a damper mounting block (154), a lifting ring pulling plate (156) and a damper (16); the damper mounting block (154) is fixed at the end of the cantilever (14) through the cantilever connecting end (155); the guide shaft (152) penetrates through a shaft sleeve (153) on the damper mounting block (154) and drives the damper pressure plate (151) to slide up and down along the shaft sleeve (153); the damper (16) is fixed on the damper mounting block (154), and the transversely arranged damper pressure plate (151) can press the extending shaft of the longitudinally arranged damper (16) when moving downwards; the rotary lifting ring (171) is connected to a lifting ring pulling plate (156), and the lifting ring pulling plate (156) is fixed on the guide shaft (152); and the damper pressing plate (151) and the lifting ring pulling plate (156) are respectively positioned on the upper side and the lower side of the damper mounting block (154).

Mainly plays a role in shock absorption.

Fig. 6 shows, as a sixth preferred embodiment, that the damper (16) is an adjustable hydraulic shock absorber.

Fig. 7 further includes an S-shaped load cell (113) as a preferred embodiment seven, and the S-shaped load cell (113) is installed between the linear motion push rod (11) and the upper hinge portion (112) of the push rod. The S-shaped weighing sensor is mainly used for measuring the tension and pressure between solids and is also called as a tension and pressure sensor. The sensor is made of alloy steel, is sealed and protected by glue, is easy to install and convenient to use, and is suitable for electronic force-measuring and weighing systems such as hanging scales, batching scales, mechanical-modification scales and the like. The function of this part is to weigh the user as a reference value for subsequent weight reduction measures.

Fig. 4 shows, as an eighth preferred embodiment, that the wheel-hub mecanum wheels (31) are connected to the chassis cross member (6) by means of a damping device; the buffer device includes: a bearing seat plate (33), a damping spring (35) and a hinge plate (37); a hub (32) of the hub type Mecanum wheel (31) is fixedly connected with a bearing seat plate (33); the bearing seat plate (33) is provided with two cylindrical sleeve-shaped damping sliding sleeves (34); the damping spring (35) is accommodated in the damping sliding sleeve (34), and the lower part of the damping sliding sleeve (34) is closed, so that the damping spring (35) does up-and-down reciprocating motion along the axis of the damping sliding sleeve (34); the upper part of the shaft in the damping spring (35) is fixedly connected with the hinge plate (37); the hinge plate (37) is hinged with the beam fixing plate (38) through a hinge part (36); the buffer device is fixed on the chassis beam (6) through a beam fixing plate (38); the method is characterized in that: the hub type Mecanum wheels (31) are elastically connected with the beam fixing plate (38) or the chassis beam (6).

The above embodiments are for the detailed description that the device structure of the present invention has carried out, and the present invention is applied to the embodiments of the automatic control method for device production as follows.

Fig. 1 shows an automatic following control method, which uses the walking following rehabilitation training device to perform walking trend judgment and control strategies in the following ways:

b) The lower leg examined part (181) is positioned in front of the sensor (5).

Fig. 1 and 7, as a first preferred embodiment of the automatic following control method, achieve the purpose of reducing weight of a human body (18) by the following means:

a) the external skeleton machine (19) hung on the human body (18) by the hook (172);

b) a push rod in the linear motion push rod (11) is pushed out upwards until the hanging strip (17) is tightened;

c) the S-shaped weighing sensor (113) measures the total weight of the human body (18) and the exoskeleton machine (19);

during the above process, the human body (18) is kept in a static state; the direct-acting push rod (11) is controlled to retract a certain distance downwards, so that the value measured by the S-shaped weighing sensor (113) is reduced to a set value compared with the total weight, and the purpose of reducing weight is achieved.

The structure and the method have clear control logic, simple equipment structure and the functions of hanging the human body, preventing falling down, reducing weight, automatically following, judging walking trend, damping, buffering and the like. Has good help function for rehabilitation training, does not limit the movement range of the user, can walk at will, and has positive significance for the rehabilitation of the user

The embodiments of the present invention are examples of the present invention, and may be combined with other known techniques, or may be modified to omit some modifications without departing from the scope of the present invention.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the same; although the present invention has been described in detail with reference to preferred embodiments, it should be understood by those skilled in the art that: the invention can be modified or equivalent substituted for some technical features; without departing from the spirit of the present invention, it should be understood that the scope of the claims is intended to cover all such modifications and variations.

Claims

1. The utility model provides a rehabilitation training device is followed on walking, mainly comprises lifting support (1), walking base (2) and cantilever rings (13), its characterized in that: the walking base (2) is provided with: the device comprises a sensor (5), a wheel set part (3) and a motion trend control module; the motion trend control module is arranged in the electric control cabinet (8) and is electrically connected with the sensor (5);

the sensor (5) is a non-contact distance detection sensor; the sensor mounting rack (4) is vertically arranged between the chassis cross beams (6), and the sensor (5) is arranged on the sensor mounting rack (4);

the wheel set part (3) is composed of hub type Mecanum wheels (31) arranged on a chassis beam (6);

2. A walking-following rehabilitation training device according to claim 1, characterized in that said sensors (5) are mounted in a plurality of equal divisions along a straight line along the sensor mounting frame (4); the sensor (5) is a laser sensor or an ultrasonic sensor.

3. A walking-following rehabilitation training device according to claim 2, characterized in that said sensors (5) are 4-20 in number.

4. A walking-following rehabilitation training device according to claim 1, characterized in that said sensor (5) is a lidar; the laser radar is arranged in the middle of the sensor mounting frame (4).

5. The walking following rehabilitation training device as claimed in any one of claims 1, 2, 3 and 4, wherein the lifting bracket (1) further comprises a linear motion push rod (11), the lower part of the linear motion push rod (11) is connected with a lower hinge part (111) of the push rod, the upper part of the linear motion push rod is connected with an upper hinge part (112) of the push rod, and the telescopic bracket (10) is pushed and pulled to be telescopic through the linear motion push rod (11) so as to adjust the height of the cantilever hanging ring (13).

6. The walking following rehabilitation training device according to claim 5, wherein the cantilever lifting ring (13) comprises a cantilever (14) and a hanging strip (17), and a shock absorbing lifting ring part (15) is arranged between the cantilever (14) and the hanging strip (17);

the shock absorption lifting ring part (15) consists of a damper pressure plate (151), a guide shaft (152), a shaft sleeve (153), a damper mounting block (154), a lifting ring pulling plate (156) and a damper (16);

the damper mounting block (154) is fixed at the end of the cantilever (14) through the cantilever connecting end (155);

the guide shaft (152) penetrates through a shaft sleeve (153) on the damper mounting block (154) and drives the damper pressure plate (151) to slide up and down along the shaft sleeve (153); the damper (16) is fixed on the damper mounting block (154), and the transversely arranged damper pressure plate (151) can press the extending shaft of the longitudinally arranged damper (16) when moving downwards;

the rotary lifting ring (171) is connected to a lifting ring pulling plate (156), and the lifting ring pulling plate (156) is fixed on the guide shaft (152);

and the damper pressing plate (151) and the lifting ring pulling plate (156) are respectively positioned on the upper side and the lower side of the damper mounting block (154).

7. A walking-following rehabilitation training device according to claim 6, characterized in that said damper (16) is an adjustable hydraulic buffer.

8. The walking following rehabilitation training device according to claim 7, further comprising an S-shaped load cell (113), wherein the S-shaped load cell (113) is installed between the translational push rod (11) and the upper hinge part (112) of the push rod.

9. A walking following rehabilitation training device according to claim 8, characterized in that said hub type mecanum wheels (31) are connected to the chassis cross-member (6) by means of a damping device; the buffer device includes: a bearing seat plate (33), a damping spring (35) and a hinge plate (37);

a hub (32) of the hub type Mecanum wheel (31) is fixedly connected with a bearing seat plate (33);

the bearing seat plate (33) is provided with two cylindrical sleeve-shaped damping sliding sleeves (34); the damping spring (35) is accommodated in the damping sliding sleeve (34), and the lower part of the damping sliding sleeve (34) is closed, so that the damping spring (35) does up-and-down reciprocating motion along the axis of the damping sliding sleeve (34);

the upper part of the shaft in the damping spring (35) is fixedly connected with the hinge plate (37); the hinge plate (37) is hinged with the beam fixing plate (38) through a hinge part (36); the buffer device is fixed on the chassis beam (6) through a beam fixing plate (38); the hub type Mecanum wheels (31) are elastically connected with the beam fixing plate (38) or the chassis beam (6).