Knee rehabilitation machine with multi-position synchronous force application

Abstract

A knee rehabilitation machine with multi-position synchronous force application includes a bottom box, a vertical box, and a suspension box. The vertical box is vertically arranged at an end of the bottom box, and an upper end of the vertical box is horizontally fixed with the suspension box. A pressing unit swing lever mechanism is arranged in the bottom box, and a vibration unit, a pulling unit, and a transmission mechanism of a pressing unit are arranged in the vertical box.

Claims

1. A knee rehabilitation machine with multi-position synchronous force application, comprising a bottom box, a vertical box, and a suspension box; wherein the vertical box is vertically arranged at an end of the bottom box, and an upper end of the vertical box is horizontally fixed with the suspension box; a swing lever mechanism of a pressing unit is arranged in the bottom box, and a vibration unit, a pulling unit, and a transmission mechanism of the pressing unit are arranged in the vertical box; a movable strap is arranged on the suspension box; a first shaft roller is firmly and coaxially arranged at an outer end of the suspension box, and the first shaft roller is arranged with a fixing strap configured to fix and bind a thigh of the patient; the vibration unit in the vertical box drives a fork to swing through a reduction motor; a roller coaxially arranged in the suspension box is fixed on an upper end of the fork; the roller is capable of swinging synchronously with a swing of the fork; the movable strap is fixed on the roller and is capable of swinging with the roller; the transmission mechanism of the pressing unit in the vertical box drives the swing lever mechanism of the pressing unit in the bottom box by a swing of the roller; two pressing vertical rods adapted to be symmetrically arranged on both sides of the calf of the patient are capable of swinging, and the two pressing vertical rods snap together to connect to a knee-joint-shaped buckle with a shape similar to a knee joint, thereby clasping the knee joint of the patient; the pulling unit in the vertical box is driven by another reduction motor to pull two traction belt rods, while two horizontal tightening buckles adapted to be on both sides of the thigh of the patient are connected with an axial positioning strap adapted to bind and axially position the thigh of the patient.

2. The knee rehabilitation machine according to claim 1, wherein the reduction motor is arranged on a bracket fixed in the vertical box; a drive shaft of the reduction motor is coaxially fixed with a turntable; a pin shaft is fixedly arranged parallel to an outer side of a disk of the turntable, and a runner is coaxially arranged on an outer end of the pin shaft; a second shaft roller is horizontally arranged in the suspension box, and an inner end of the second shaft roller is arranged by means of a bearing through a bearing seat fixed in a suspension beam; an outer end of the second shaft roller is arranged on the suspension box; the fork is fixed on the inner end of the second shaft roller, and a lower part of the fork defines a long through hole for guiding the runner running the pin shaft in the long through hole; when the turntable rotates, the fork swings to both sides with a circular movement of the pin shaft, thereby driving a swinging movement of the second shaft roller.

3. The knee rehabilitation machine according to claim 2, wherein a cam disc is fixed coaxially on the second shaft roller outside the fork of the vibration unit; the cam disc is in an inverted center structure; a vertical moving rod is arranged at a lower end of the cam disc, and a lower end of the vertical moving rod is hinged on a hinge beam; each side of the hinge beam is hinged with a lower swing lever, an inner end of each lower swing lever is hinged with a hinge frame through a hinge shaft, and an outer end of each lower swing lever is hinged with a corresponding pressing vertical rod through another hinge shaft.

4. The knee rehabilitation machine according to claim 1, wherein the another reduction motor is fixed in the vertical box, an output shaft of the another reduction motor is coaxially arranged with a drive gear, and the drive gear meshes with a driven gear; an outer disk surface of each of the drive gear and the driven gear is fixed with a sheave wheel, and a pulling belt is wound around the sheave wheel; a cross beam is cantilevered and fixed to an end of a horizontal bracket below the sheave wheels, and each of two ends of the cross beam is provided with a guide wheel; the pulling belt of each sheave wheel is snap connected with a traction belt rod through the corresponding guide wheel.

5. The knee rehabilitation machine according to claim 1, wherein a swinging angle of the fork is in a range of 0° to ±60°.

6. The knee rehabilitation machine according to claim 3, wherein a vertical guide sleeve is arranged on the vertical moving rod, and a recovery spring is arranged on the vertical moving rod at an upper end of the vertical guide sleeve.

7. The knee rehabilitation machine according to claim 4, wherein a vertical guiding sleeve is arranged between each guide wheel and a corresponding sheave wheel, and a horizontal guiding sleeve is arranged between each guide wheel and a corresponding traction belt rod.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a structural front view of a knee rehabilitation machine with multi-position synchronous force application of the present disclosure.

(2) FIG. 2 is a structural left view of the knee rehabilitation machine with multi-position synchronous force application shown in FIG. 1.

(3) FIG. 3 is a cross-sectional section in the A-A direction of FIG. 1.

(4) FIG. 4 is a cross-sectional section in the B-B direction of FIG. 2.

(5) FIG. 5 is an enlarged structural schematic view of a vibration unit of the present disclosure.

(6) FIG. 6 is a cross-sectional section in the C-C direction of FIG. 5.

(7) FIG. 7 is a partial sectional schematic view of FIG. 1.

(8) FIG. 8 is a cross-sectional section in the D-D direction of FIG. 7.

(9) FIG. 9 is an enlarged structural schematic view of a pulling unit of the present disclosure.

(10) FIG. 10 is a cross-sectional section in the E-E direction of FIG. 9.

(11) FIG. 11 is an enlarged structural schematic view of a part F in FIG. 9.

DETAILED DESCRIPTION

(12) The following further describes the present disclosure with reference to the following examples: the following examples are illustrative and not restrictive, and the following examples cannot be used to limit the scope of the present disclosure.

(13) A knee rehabilitation machine with multi-position synchronous force application includes a bottom box 11, a vertical box 1 and a suspension box 2; the vertical box 1 is vertically arranged at an end of the bottom box 11, and an upper end of the vertical box 1 is horizontally fixed with the suspension box 2. Lower bottom corners of the bottom box 11 are arranged with Vientiane rollers 10 to realize the movement of the whole mechanism; a connecting table 9 is arranged on an outside of the bottom box 11 for a patient 8 to lie down; a pressing unit swing lever mechanism is arranged in the bottom box 11, and a vibration unit, a pulling unit, and a transmission mechanism of a pressing unit are arranged in the vertical box 1; a movable strap 3 is arranged on the suspension box 2, which is configured to bind a calf of the patient; a fixed shaft roller 4 is coaxially arranged at an outer end of the suspension box 2, and the fixed shaft roller 4 is arranged with a fixing strap 5 for fixing and binding a thigh of the patient, as shown in FIG. 4. In addition, the bottom box 11 is further arranged with two pressing vertical rods 6 symmetrically disposed on both sides of a knee of the patient and two horizontal tightening buckles 7 disposed on both sides of the thigh.

(14) The overall internal structure of the present disclosure is shown in FIG. 4. The vibration unit in the vertical box 1 drives a fork 13 to swing through a reduction motor 12. A roller 15 coaxially arranged in the suspension box 2 is fixed on an upper end of the fork 13. The roller 15 swings synchronously with the swing of the fork 13. The movable strap 3 is fixed on the roller 15 and swings with the roller 15. The swinging angle is in a range of 0° to ±60°, and the optimal swinging angle is in a range of ±25° to ±40°. Since the fixing strap 5 fixes the patient's thigh, and the movable strap 3 produces a swing with a certain angle, this arrangement may realize the suspension of the patient's thigh, promote blood circulation, and allows the patient's knee to be regularly twisted and shaken, which promotes the patient's knee joint exercise and restore. In addition, the pulling unit in the vertical box 1 is driven by another reduction motor 20 to pull two traction belt rods 16 at the same time to pull the patient's calf axially, while the two horizontal tightening buckles 7 on both sides of the patient's thigh are connected with an axial positioning strap 18, which bind the patient's thigh and position it axially, so as to realize the straightening recovery of the knee joint. The transmission structure of the pressing unit in the vertical box 1 is a swing lever mechanism that uses swing of the roller 15 to drive the pressing unit in the bottom box 11. By swinging the two pressing vertical rods 6 symmetrically arranged on both sides of the patient's calf, the two pressing vertical rods 6 snap together to connect to a magic buckle 17 with a shape similar to the knee joint, thereby clasping the patient's knee joint, which realizes the compression of the patient's knee joint, corrects the instability of the knee joint, eliminates various discomfort caused by it, and prevents the occurrence of the knee arthrosis. Therefore, in the present disclosure, suspension, vibration, pulling and pressing are applied to the patient's knee joint simultaneously, overcoming the possible damage to the patient's knee joint caused by the single application of force to the knee joint in the related art, and realizing effective rehabilitation training of the knee joint with perfect comprehensive rehabilitation effect.

(15) The specific structures of the above units are described in detail below.

(16) 1. The structure of the vibration unit will be described in conjunction with FIGS. 5 and 6. The reduction motor 12 is arranged on a bracket 26 fixed in the vertical box 1. A drive shaft 27 of the reduction motor 12 is coaxially fixed with a turntable 25. A pin shaft 24 is fixedly arranged parallel to an outer side of a disk of the turntable 25, and a runner 23 is coaxially arranged on an outer end of the pin shaft 24; a shaft roller is horizontally arranged in the suspension box 2, and an inner end of the shaft roller is arranged by means of a bearing 22 through a bearing seat 21 fixed in a suspension beam. An outer end of the shaft roller is arranged on a position of the suspension box 2, and the position of the suspension box 2 is fixed to the fixed shaft roller 4 arranged coaxially with the shaft roller; the fork 13 is fixed on the inner end of the shaft roller, and a lower part of the fork 13 defines a long through hole 28, which can guide the runner 23 running the pin shaft 24 in the long through hole 28. The runner 23 may be made of bearings or similar products, so that when the turntable 25 rotates, the fork 13 swings to both sides with a circular movement of the pin shaft 24, thereby driving the swinging movement of the shaft roller.

(17) 2. The structure of the pressing unit will be described in conjunction with FIGS. 7 and 8. On the shaft roller outside the fork 13 of the vibration unit, a cam disc 29 is fixed coaxially. The cam disc 29 is in an inverted center structure; a vertical moving rod 35 is arranged at the lower end of the cam disc 29, and a lower end of the vertical moving rod 35 is hinged on a hinge beam 33; each side of the hinge beam 33 is hinged with a lower swing lever 31, an inner end of each lower swing lever 31 is hinged with a hinge frame 19 through a hinge shaft 32, and an outer end of each lower swing lever 31 is hinged with a corresponding pressing vertical rod 6 through a hinge shaft 30. In order to ensure the vertical displacement of the vertical moving rod 35, a vertical guide sleeve 34 is added to the vertical moving rod 35. In order to ensure that the vertical moving rod 35 maintains a flexible fitting displacement with the cam disc 29, a recovery spring 14 is arranged on the vertical moving rod 35 at an upper end of the vertical guide sleeve 34.

(18) When the roller 15 swings, the cam disc 29 swings at the same time, a raised part of the cam disc 29 presses the vertical moving rod 35 and makes the vertical moving rod 35 fit a cam surface by the action of the recovery spring 14. The vertical moving rod 35 moves up and down to drive the lower swing lever 31 to swing up and down with the hinge frame 19 as a shaft. The two pressing vertical rods 6 hinged at the outer end of the lower swing lever 31 are also vertically displaced up and down to achieve compression training and recovery of the patient's knee joint.

(19) 3. The structure of the pulling unit will be described in conjunction with FIGS. 9, 10, and 11 The reduction motor 20 is fixed in the vertical box 1, an output shaft of the reduction motor 20 is coaxially arranged with a drive gear 36, and the drive gear 36 meshes with a driven gear 43 in a structure same as the drive gear 36. An outer disk surface of each of the drive gear 36 and the driven gear 43 is fixed with a sheave wheel 37. A pulling belt 40 is wound around each of the two sheave wheels 37. A cross beam is cantilevered and fixed to an end of a horizontal bracket 42 below the sheave wheels 37, and a guide wheel 39 is fixed on an end of the cross beam. The pulling belt 40 of the sheave wheel 37 is snap connected with a corresponding traction belt rod 16 on a side of the calf through a corresponding guide wheel 39. In order to ensure smooth guiding of the running of the pulling belt 40, a vertical guiding sleeve 38 is further arranged between each guide wheel 39 and the corresponding sheave wheel 37, and a horizontal guiding sleeve 41 is further arranged between each guide wheel 37 and the corresponding traction belt rod 16.

(20) The above structure may realize that, when the reduction motor 20 rotates, the two gears 36 and 43 that mesh with each other are driven to rotate, and the sheave wheels 37 arranged on the gears 36 and 43 rotate. At this time, the pulling belts 40 arranged on the sheave wheels 37 are pulled upwards. Due to the action of the guide wheels 39, the pulling belts 40 stretch the patient's knee to condition and train the instability of the knee joint.