CN110547944A

CN110547944A - Walking gait correction trainer for hemiplegic patient

Info

Publication number: CN110547944A
Application number: CN201910806165.0A
Authority: CN
Inventors: 张玲玲; 马松华
Original assignee: Second Peoples Hospital of Nantong
Current assignee: Second Peoples Hospital of Nantong
Priority date: 2019-08-28
Filing date: 2019-08-28
Publication date: 2019-12-10
Anticipated expiration: 2039-08-28
Also published as: CN110547944B

Abstract

The invention discloses a walking gait correction trainer for hemiplegic patients, which relates to the technical field of gait correction and comprises a bottom plate, wherein the upper surface of the bottom plate is fixedly connected with a telescopic mechanism and an armrest frame, the telescopic part of the telescopic mechanism is fixedly connected with a seat, the upper surface of the bottom plate is also fixedly connected with a leg lifting mechanism, and the leg lifting mechanism is fixedly provided with a foot lifting mechanism. The walking gait correction trainer can simultaneously simulate the movement tracks of hip joints, knee joints and ankle joints when a person walks by matching the structures, thereby improving the gait recovery effect, and solving the problem that most of the walking gait correction trainers for the traditional hemiplegic patients realize the gait correction training by driving the hip joints and the knee joints, but cannot simulate the movement tracks of the ankle joints of the lower limbs of the human body in the normal walking process, so that the gait correction rehabilitation training is inconsistent with the walking posture tracks of the lower limbs of the normal human body, and the training effect is poor.

Description

Walking gait correction trainer for hemiplegic patient

Technical Field

The invention relates to the technical field of gait correction, in particular to a walking gait correction trainer for hemiplegic patients.

Background

Most of the traditional walking gait correction trainers for hemiplegic patients realize gait correction training by driving hip joints and knee joints, but cannot simulate the movement track of ankle joints of lower limbs of human bodies in the normal walking process, so that the gait correction rehabilitation training is inconsistent with the walking posture track of the lower limbs of the normal human bodies, and the training effect is poor.

Disclosure of Invention

The walking gait correction trainer for hemiplegic patients has the advantages that the walking gait correction trainer can simultaneously simulate the movement tracks of hip joints, knee joints and ankle joints when people walk, further improves the gait recovery effect, and solves the problem that most of the walking gait correction trainers for hemiplegic patients realize gait correction training by driving the hip joints and the knee joints, cannot simulate the movement tracks of the ankle joints of lower limbs of human bodies in the normal walking process, so that the walking posture tracks of the walking rehabilitation training and the lower limbs of the normal human bodies are inconsistent, and the training effect is poor.

in order to achieve the purpose, the invention provides the following technical scheme: the walking gait correction trainer for hemiplegic patients comprises a bottom plate, wherein the upper surface of the bottom plate is fixedly connected with a telescopic mechanism and an armrest frame, the telescopic part of the telescopic mechanism is fixedly connected with a seat, the upper surface of the bottom plate is also fixedly connected with a leg lifting mechanism, and the leg lifting mechanism is fixedly provided with a leg lifting mechanism.

The leg lifting mechanism comprises a supporting plate, a motor, a first transmission arm and a pedal plate, the supporting plate is fixedly installed on the upper surface of the bottom plate, the motor is fixedly installed on one side, away from the telescopic mechanism, of the supporting plate, one end, away from the motor, of the first transmission arm is hinged to the supporting plate, a second transmission arm is fixedly connected to a shaft arm of an output shaft of the motor, one end, close to the motor, of the first transmission arm is rotatably connected with a first connecting shaft through bearing matching, one end, away from the motor, of the second transmission arm is rotatably connected with a second connecting shaft through bearing matching, one ends, away from the supporting plate, of the first connecting shaft and the second connecting shaft are rotatably connected with a linkage block through bearing matching, and the pedal plate is fixedly installed on.

Preferably, the foot lifting mechanism comprises a fixed plate, a gear, a first bevel gear, a second bevel gear, a reciprocating screw and a support arm, the fixed plate is fixedly connected to the upper surface of the base plate, two ends of the reciprocating screw are rotatably connected to the linkage block through bearings in a matched manner, the gear and the first bevel gear are fixedly connected to a shaft arm of the second connecting shaft, the second bevel gear is fixedly connected to a shaft arm at one end of the reciprocating screw close to the first bevel gear, the second bevel gear is in meshed connection with the first bevel gear, the support arm is fixedly connected to the upper surface of the linkage block, an inner gear ring is fixedly connected to the upper surface of the fixed plate, the gear is in meshed connection with the inner gear ring, a lifting plate is hinged to the upper end of the support arm, a pedal plate is fixedly connected to the upper surface of the lifting plate, and a reciprocating screw sleeve is sleeved on the outer side surface of the reciprocating, the upper end of the reciprocating threaded sleeve is hinged with a linkage arm, and the upper end of the linkage arm is hinged with the right end of the lifting plate.

preferably, the number of the leg lifting mechanisms is two, and the two leg lifting mechanisms are symmetrically distributed in a front-back axial mode by taking the telescopic mechanisms as symmetrical axes.

Preferably, the telescopic mechanism is an electric push rod or a hydraulic rod.

Compared with the prior art, the invention has the following beneficial effects:

The invention simulates the movement track of the hip joint and the knee joint of the lower limb when walking through the operation of the output shaft of the motor by arranging the supporting plate, the motor, the first transmission arm, the second transmission arm, the first connecting shaft, the second connecting shaft, the linkage block and the pedal.

The walking ankle joint device simulates the movement track of the walking ankle joint of a person and improves the gait recovery effect through the fixing plate, the gear, the first bevel gear, the second bevel gear, the reciprocating screw rod, the supporting arm, the inner gear ring, the lifting plate, the reciprocating screw sleeve and the linkage arm.

The two leg lifting mechanisms are arranged in a front-rear axis symmetrical distribution mode by taking the telescopic mechanisms as symmetrical axes, so that a patient can conveniently carry out synchronous training on the two lower limbs of the patient, and the output shafts of the two motors are sequentially driven in the training process, so that the process that the two lower limbs operate sequentially when the patient walks is simulated.

In conclusion, the walking gait correction trainer can simulate the movement tracks of the hip joint, the knee joint and the ankle joint of a person during walking, further improves the gait recovery effect, and solves the problem that most of walking gait correction trainers for the hemiplegic patients realize gait correction training by driving the hip joint and the knee joint and cannot simulate the movement track of the ankle joint of the lower limbs of the person during normal walking, so that the walking posture track of the gait correction rehabilitation training is inconsistent with the walking posture track of the lower limbs of the person, and the training effect is poor.

Drawings

FIG. 1 is a front view of the structure of the present invention;

FIG. 2 is a top view of a partial structure of the present invention;

FIG. 3 is a front view of a partial structure of the present invention;

FIG. 4 is a structural diagram of the reciprocating screw sleeve after moving to the middle of the reciprocating screw rod according to the present invention;

FIG. 5 is a view showing the state of the reciprocating screw insert of the present invention after moving to the leftmost end of the reciprocating screw.

In the figure: 1-bottom plate, 2-telescopic mechanism, 3-handrail frame, 4-seat, 5-leg lifting mechanism, 6-foot lifting mechanism, 7-supporting plate, 8-motor, 9-first transmission arm, 10-second transmission arm, 11-first connecting shaft, 12-second connecting shaft, 13-linkage block, 14-pedal, 15-fixing plate, 16-gear, 17-first bevel gear, 18-second bevel gear, 19-reciprocating screw, 20-supporting arm, 21-internal gear ring, 22-lifting plate, 23-reciprocating screw sleeve and 24-linkage arm.

Detailed Description

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

Referring to fig. 1 to 5, the present invention provides a technical solution: a walking gait correction trainer for hemiplegic patients comprises a bottom plate 1, wherein the upper surface of the bottom plate 1 is fixedly connected with a telescopic mechanism 2 and an armrest frame 3, the telescopic part of the telescopic mechanism 2 is fixedly connected with a seat 4, the upper surface of the bottom plate 1 is also fixedly connected with a leg lifting mechanism 5, and the leg lifting mechanism 5 is fixedly provided with a foot lifting mechanism 6.

The leg lifting mechanism 5 comprises a support plate 7, a motor 8, a first transmission arm 9 and a pedal plate 14, an elastic strap for fixing the position of the feet is arranged on the pedal plate 14, so that the feet of a user can move along with the pedal plate 14, the support plate 7 is fixedly arranged on the upper surface of the bottom plate 1, the motor 8 is fixedly arranged on one side of the support plate 7 far away from the telescopic mechanism 2, one end of the first transmission arm 9 far away from the motor 8 is hinged with the support plate 7, a shaft arm of an output shaft of the motor 8 is fixedly connected with a second transmission arm 10, one end of the first transmission arm 9 close to the motor 8 is rotatably connected with a first connecting shaft 11 in a matching way through a bearing, one end of the second transmission arm 10 far away from the motor 8 is rotatably connected with a second connecting shaft 12 in a matching way through a bearing, one end of the first connecting shaft 11 and the second connecting shaft 12 far away from the support plate 7 is, in use, the patient is moved to the chair 4, and then steps on the two pedals 14 with both feet, meanwhile, the patient can cover the armrest frame 3 by both hands to avoid the self-dumping phenomenon, and then the operation of the output shaft of the motor 8 is carried out, the second transmission arm 10 rotates counterclockwise, and the process of rotating counterclockwise by the second transmission arm 10 is transmitted by the first transmission arm 9, the first connection shaft 11 and the second connection shaft 12, the linkage block 13 is enabled to translate (the translation track is a circle formed by the rotation of the second connecting shaft 12 by taking the output shaft of the motor 8 as the circle center), the pedal plates 14 are enabled to translate synchronously in the translation process of the linkage block 13, so that the effects of lifting and lowering the legs of the patient during the simulation walking of the lower limbs are realized, and through the processes of lifting legs and putting down, the movement tracks of the hip joints and the knee joints of the lower limbs when walking are simulated.

Preferably, the foot lifting mechanism 6 comprises a fixed plate 15, a gear 16, a first bevel gear 17, a second bevel gear 18, a reciprocating screw 19 and a support arm 20, the fixed plate 15 is fixedly connected to the upper surface of the base plate 1, both ends of the reciprocating screw 19 are rotatably connected to the linkage block 13 through bearings in a matching manner, the gear 16 and the first bevel gear 17 are fixedly connected to a shaft arm of the second connecting shaft 12, the second bevel gear 18 is fixedly connected to a shaft arm of the reciprocating screw 19 near one end of the first bevel gear 17, the second bevel gear 18 is in meshing connection with the first bevel gear 17, the support arm 20 is fixedly connected to the upper surface of the linkage block 13, an inner toothed ring 21 is fixedly connected to the upper surface of the fixed plate 15, the gear 16 is in meshing connection with the inner toothed ring 21, the upper end of the support arm 20 is hinged to a lifting plate 22, the pedal plate 14 is fixedly connected to the upper surface of the lifting plate 22, a reciprocating screw 23 is, the upper end of the reciprocating screw sleeve 23 is hinged with a linkage arm 24, the upper end of the linkage arm 24 is hinged with the right end of the lifting plate 22, the first conical gear 17 rotates through the process that the second connecting shaft 12 rotates along the anticlockwise direction of the output shaft of the motor 8 and through the process that the gear 16 is in meshing transmission with the inner toothed ring 21, the second conical gear 18 synchronously rotates through the process that the gear 16 rotates and through the linkage of the second connecting shaft 12, the reciprocating screw rod 19 synchronously rotates through the process that the first conical gear 17 rotates and through the process that the first conical gear 17 is in meshing transmission with the second conical gear 18, the reciprocating screw sleeve 23 reciprocates left and right through the process that the reciprocating screw rod 19 rotates and through the sleeved relation between the reciprocating screw rod 19 and the reciprocating screw sleeve 23, the reciprocating screw sleeve 23 reciprocates left and right, and through the process that the reciprocating screw sleeve 23 reciprocates left and right and through the linkage of the linkage arm 24, the lifting plate 22 swings around the hinge point between the lifting plate 22 and the support arm 20, and the pedal 14 swings synchronously by the swinging process of the lifting plate 22, and the swinging track of the pedal 14 is as follows: assuming that the state shown in fig. 1 starts, the second connecting shaft 12 starts to rotate counterclockwise by forty-five degrees, in the process, the linkage block 13 moves leftward while moving upward, and the reciprocating screw 23 moves leftward along the reciprocating screw 19, so that the pedal 14 moves forward while lifting, and the pedal 14 rotates clockwise around the hinge point between the lifting plate 22 and the supporting arm 20 to the state shown in fig. 4; with the continuous counterclockwise rotation of the second connecting shaft 12 by forty-five degrees, in the process, the linkage block 13 moves leftwards while moving downwards, and meanwhile the reciprocating screw sleeve 23 moves leftwards continuously along the reciprocating screw rod 19, so that the pedal plate 14 moves forwards while lifting, and the pedal plate 14 continues to rotate clockwise to the state shown in fig. 5 by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center, so that the purpose that when a person walks, the lower limbs move forwards while lifting the tiptoes (the purpose that the lower limbs move forwards while lifting the tiptoes is to facilitate the simulation of the effect that the heels land first when a foot is subsequently dropped) is simulated; then, as the second connecting shaft 12 continues to rotate counterclockwise by forty-five degrees, in the process, the linkage block 13 moves downwards and moves rightwards, and meanwhile, the reciprocating screw sleeve 23 moves rightwards along the reciprocating screw rod 19, so that when the pedal plate 14 is put down, the pedal plate 14 continues to rotate counterclockwise to the state shown in fig. 4 by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center, and the effect that the heel firstly lands when a person walks and lands is simulated; then, the linkage block 13 continuously rotates counterclockwise for forty-five degrees along with the continuous counterclockwise rotation of the second connecting shaft 12, and in the process, the linkage block 13 moves rightward while moving upward, and meanwhile, the reciprocating screw sleeve 23 continuously moves rightward along the reciprocating screw rod 19, so that when the pedal plate 14 is lifted, the pedal plate 14 continuously rotates counterclockwise by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center and returns to the state shown in fig. 1, the effect of lifting the heel of a person when lifting the foot is simulated, the movement tracks of the hip joint, the knee joint and the ankle joint when the person walks are simulated by the operation of the output shaft of the motor 8 in such a reciprocating manner, and the gait recovery effect is improved.

Preferably, the number of the leg lifting mechanisms 5 is two, the two leg lifting mechanisms 5 are symmetrically distributed in a front-rear direction by taking the telescopic mechanism 2 as a symmetric axis, the two leg lifting mechanisms 5 are arranged, so that a patient can conveniently and synchronously train the two lower limbs of the patient, and the output shafts of the two motors 8 are sequentially driven in the training process, so that the process that the two lower limbs operate sequentially when the person walks is simulated.

preferably, telescopic machanism 2 is electric putter or hydraulic stem, and through the electric putter or the hydraulic stem that set up, is convenient for adjust the height of seat 4 to different height users' demand has been adapted to.

The working principle is as follows: when the walking gait correction trainer for hemiplegic patients is used, the patients are moved to the seat 4, then two feet are respectively stepped on the two foot pedals 14, meanwhile, the patients can cover the handrail frame 3 by two hands to avoid the phenomenon of self dumping, then the second transmission arm 10 is rotated anticlockwise through the operation of the output shaft of the motor 8, the second transmission arm 10 rotates anticlockwise and is transmitted by the first transmission arm 9, the first connecting shaft 11 and the second connecting shaft 12, so that the linkage block 13 translates (the translation track is a circle formed by the rotation of the second connecting shaft 12 by taking the output shaft of the motor 8 as a circle center), the foot pedals 14 synchronously translate through the translation process of the linkage block 13, the effects of leg lifting and leg lowering during the simulation walking of the lower limbs of the patients are realized, and the motion tracks during the walking of hip joints and knee joints are simulated through the processes of leg lifting and leg lowering, meanwhile, the gear 16 rotates in the process that the second connecting shaft 12 rotates in the counterclockwise direction of the output shaft of the motor 8 and the gear 16 and the inner toothed ring 21 are in meshing transmission, the first conical gear 17 rotates in the process that the gear 16 rotates and the second connecting shaft 12 are in linkage, the first conical gear 17 rotates in the process that the first conical gear 17 rotates and the first conical gear 17 and the second conical gear 18 are in meshing transmission, the second conical gear 18 rotates synchronously, the reciprocating screw rod 19 rotates synchronously in the process that the second conical gear 18 rotates, the reciprocating screw rod 19 rotates and the reciprocating screw sleeve 23 reciprocates leftwards and rightwards, the linkage arm 24 lifts in linkage, and the movable plate 22 swings with the hinge point between the lifting plate 22 and the supporting arm 20 as the circle center, the pedal 14 is synchronously swung by the swinging process of the lifting plate 22, and the swinging track of the pedal 14 is as follows: assuming that the state shown in fig. 1 starts, the second connecting shaft 12 starts to rotate counterclockwise by forty-five degrees, in the process, the linkage block 13 moves leftward while moving upward, and the reciprocating screw 23 moves leftward along the reciprocating screw 19, so that the pedal 14 moves forward while lifting, and the pedal 14 rotates clockwise around the hinge point between the lifting plate 22 and the supporting arm 20 to the state shown in fig. 4; with the continuous counterclockwise rotation of the second connecting shaft 12 by forty-five degrees, in the process, the linkage block 13 moves leftwards while moving downwards, and meanwhile the reciprocating screw sleeve 23 moves leftwards continuously along the reciprocating screw rod 19, so that the pedal plate 14 moves forwards while lifting, and the pedal plate 14 continues to rotate clockwise to the state shown in fig. 5 by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center, so that the purpose that when a person walks, the lower limbs move forwards while lifting the tiptoes (the purpose that the lower limbs move forwards while lifting the tiptoes is to facilitate the simulation of the effect that the heels land first when a foot is subsequently dropped) is simulated; then, as the second connecting shaft 12 continues to rotate counterclockwise by forty-five degrees, in the process, the linkage block 13 moves downwards and moves rightwards, and meanwhile, the reciprocating screw sleeve 23 moves rightwards along the reciprocating screw rod 19, so that when the pedal plate 14 is put down, the pedal plate 14 continues to rotate counterclockwise to the state shown in fig. 4 by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center, and the effect that the heel firstly lands when a person walks and lands is simulated; then, the linkage block 13 continuously rotates counterclockwise for forty-five degrees along with the continuous counterclockwise rotation of the second connecting shaft 12, and in the process, the linkage block 13 moves rightward while moving upward, and meanwhile, the reciprocating screw sleeve 23 continuously moves rightward along the reciprocating screw rod 19, so that when the pedal plate 14 is lifted, the pedal plate 14 continuously rotates counterclockwise by taking a hinge point between the lifting plate 22 and the supporting arm 20 as a circle center and returns to the state shown in fig. 1, the effect of lifting the heel of a person when lifting the foot is simulated, the movement tracks of the hip joint, the knee joint and the ankle joint when the person walks are simulated by the operation of the output shaft of the motor 8 in such a reciprocating manner, and the gait recovery effect is improved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. Training ware is corrected to hemiplegia patient gait of walking, including bottom plate (1), its characterized in that: the upper surface of the bottom plate (1) is fixedly connected with a telescopic mechanism (2) and an armrest frame (3), a telescopic part of the telescopic mechanism (2) is fixedly connected with a seat (4), the upper surface of the bottom plate (1) is also fixedly connected with a leg lifting mechanism (5), and the leg lifting mechanism (5) is fixedly provided with a foot lifting mechanism (6);

the leg lifting mechanism (5) comprises a supporting plate (7), a motor (8), a first transmission arm (9) and a pedal plate (14), the supporting plate (7) is fixedly installed on the upper surface of the bottom plate (1), the motor (8) is fixedly installed on one side, far away from the telescopic mechanism (2), of the supporting plate (7), one end, far away from the motor (8), of the first transmission arm (9) is hinged to the supporting plate (7), a shaft arm of an output shaft of the motor (8) is fixedly connected with a second transmission arm (10), one end, close to the motor (8), of the first transmission arm (9) is rotatably connected with a first connecting shaft (11) through a bearing in a matched mode, one end, far away from the motor (8), of the second transmission arm (10) is rotatably connected with a second connecting shaft (12) through a bearing in a matched mode, one ends, far away from the supporting plate (7), of the first connecting shaft (11) and the second connecting shaft (12) are rotatably, the pedal (14) is fixedly arranged on the linkage block (13) through the foot lifting mechanism (6).

2. The walking gait correction trainer for hemiplegic patients according to claim 1, characterized in that: the foot lifting mechanism (6) comprises a fixing plate (15), a gear (16), a first bevel gear (17), a second bevel gear (18), a reciprocating screw (19) and a supporting arm (20), the fixing plate (15) is fixedly connected to the upper surface of the bottom plate (1), two ends of the reciprocating screw (19) are rotatably connected to the linkage block (13) through bearing matching, the gear (16) and the first bevel gear (17) are fixedly connected to a shaft arm of the second connecting shaft (12), the second bevel gear (18) is fixedly connected to a shaft arm of one end, close to the first bevel gear (17), of the reciprocating screw (19), the second bevel gear (18) is in meshing connection with the first bevel gear (17), the supporting arm (20) is fixedly connected to the upper surface of the linkage block (13), an inner gear ring (21) is fixedly connected to the upper surface of the fixing plate (15), the gear (16) is connected with the inner toothed ring (21) in a meshed mode, the upper end of the supporting arm (20) is hinged to a lifting plate (22), the pedal (14) is fixedly connected to the upper surface of the lifting plate (22), the outer side face of the reciprocating screw rod (19) is sleeved with a reciprocating threaded sleeve (23), the upper end of the reciprocating threaded sleeve (23) is hinged to a linkage arm (24), and the upper end of the linkage arm (24) is hinged to the right end of the lifting plate (22).

3. The walking gait correction trainer for hemiplegic patients according to claim 2, characterized in that: the number of the leg lifting mechanisms (5) is two, and the two leg lifting mechanisms (5) are symmetrically distributed in a front-back axial mode by taking the telescopic mechanism (2) as a symmetric axis.

4. The walking gait correction trainer for hemiplegic patients according to claim 1, 2 or 3, characterized in that: the telescopic mechanism (2) is an electric push rod or a hydraulic rod.