CN215585378U - Multi-functional shank training frame for neurosurgery - Google Patents

Abstract

The utility model belongs to the technical field of leg training, and particularly relates to a multifunctional leg training frame for neurosurgery, which aims at solving the problems that the existing training mode needs manual work of medical staff to train the legs of a patient, the mode is time-consuming and labor-consuming, the working strength of the medical staff is increased, and the training effect of the patient is reduced. The utility model does not need manual training of workers, reduces two working strengths, can change the exercise strength and the exercise interval, and can be suitable for different patients.

Description

Multi-functional shank training frame for neurosurgery

Technical Field

The utility model relates to the technical field of leg training, in particular to a multifunctional leg training frame for neurosurgery.

Background

Neurosurgery is a branch of surgery, and is a branch of surgery, which is based on surgery as a main treatment means, and is used for researching the injury, inflammation, tumor, deformity and certain genetic metabolic disorders or dysfunctional diseases of human nervous systems, such as brain, spinal cord and peripheral nervous systems, and related auxiliary mechanisms, such as skull, scalp, cerebral vessels and meninges, by using a unique neurosurgical research method.

The hospital does not have a special leg training frame, needs medical care personnel to manually train the legs of the patient, and the mode wastes time and labor, increases the working strength of the medical care personnel and reduces the training effect of the patient.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects that the existing training mode needs medical staff to manually train the legs of a patient, the mode wastes time and labor, increases the working strength of the medical staff and reduces the training effect of the patient, and provides a multifunctional leg training frame for neurosurgery.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a multifunctional leg training frame for neurosurgery comprises a training plate, wherein a backrest is slidably mounted at the top of the training plate, a push rod motor is arranged at the top of the training plate, an output shaft of the push rod motor is fixedly connected with the backrest, a cavity is formed in the training plate, a vertical rod is rotatably mounted in the cavity, a fixed wheel is sleeved on the outer side of the vertical rod, two adapting holes are symmetrically formed in the inner wall of the top of the cavity, adapting rods are slidably mounted in the two adapting holes, and foot pedals are fixedly mounted at the top ends of the two adapting rods;

fixed mounting has two square poles in the cavity, two adaptation poles respectively with two square pole sliding connection, the equal fixed mounting in the outside of two adaptation poles has the pulling force piece, is connected with same steel wire stay cord on two pulling force pieces, and the steel wire stay cord is connected with the tight pulley transmission, and symmetrical sliding mounting has two pinch rollers on the bottom inner wall of cavity, and two pinch rollers all contact with the steel wire stay cord.

Preferably, two telescopic motors are symmetrically arranged on the inner wall of the bottom of the cavity, moving blocks are fixedly mounted on output shafts of the two telescopic motors, and the two extrusion wheels are rotatably connected with the two moving blocks respectively.

Preferably, the same adjusting plate is slidably mounted on the outer sides of the two square rods, an air cylinder is fixedly mounted on the inner wall of one side of the cavity, an output shaft of the air cylinder is fixedly connected with the adjusting plate, two springs are fixedly mounted between the adjusting plate and the two adaptive rods, and the two springs are respectively sleeved on the outer sides of the two square rods.

Preferably, an elastic belt is arranged on the backrest, and a snap ring is arranged on the elastic belt.

Compared with the prior art, the utility model has the advantages that:

(1) according to the scheme, the push rod motor pushes the backrest to move, so that the distance between the backrest and the two foot pedal plates can be adjusted, and the backrest can be suitable for patients with different heights to use;

(2) the pedals are alternatively pedaled by two feet, the arranged springs can exercise the two legs of the patient, and the arranged steel wire pull ropes can play a role in transmission;

(3) when the pedaling distance of the two legs needs to be changed, the two telescopic motors are started, the two movable blocks can be pushed to move by the telescopic motors, the movable blocks drive the extrusion wheels to extrude the steel wire pull rope, the deformation of the steel wire pull rope can be changed, and the pedaling distance of the two legs can be changed;

(4) when the deformation of spring needs to be changed, the cylinder is started, the cylinder drives the adjusting plate to move, the distance between the adjusting plate and the two adapting rods can be adjusted, the deformation of the spring can be changed, and the exercise force can be changed.

The utility model does not need manual training of workers, reduces two working strengths, can change the exercise strength and the exercise interval, and can be suitable for different patients.

Drawings

FIG. 1 is a schematic structural view of a multifunctional leg training frame for neurosurgery according to the present invention;

FIG. 2 is a schematic top view of a leg training stand for neurosurgery in accordance with the present invention;

fig. 3 is a schematic structural diagram of a side view a of a multifunctional leg training frame for neurosurgery according to the present invention.

In the figure: 1. a training board; 2. a backrest; 3. a push rod motor; 4. an elastic band; 5. a cavity; 6. a telescopic motor; 7. a moving block; 8. an extrusion wheel; 9. an adapter hole; 10. an adapter rod; 11. a tension block; 12. a pedal plate; 13. a spring; 14. a square bar; 15. a cylinder; 16. an adjusting plate; 17. a steel wire rope; 18. a fixed wheel; 19. a vertical rod.

Detailed Description

The technical solutions in the embodiments will be described clearly and completely with reference to the drawings in the embodiments, and it is obvious that the described embodiments are only a part of the embodiments, but not all embodiments.

Example one

Referring to fig. 1-3, a multifunctional leg training frame for neurosurgery comprises a training plate 1, a backrest 2 is slidably mounted on the top of the training plate 1, a push rod motor 3 is arranged on the top of the training plate 1, an output shaft of the push rod motor 3 is fixedly connected with the backrest 2 through screws, a cavity 5 is formed in the training plate 1, a vertical rod 19 is rotatably mounted in the cavity 5, a fixed wheel 18 is sleeved on the outer side of the vertical rod 19, two adapting holes 9 are symmetrically formed in the inner wall of the top of the cavity 5, adapting rods 10 are slidably mounted in the two adapting holes 9, a pedal plate 12 is fixedly mounted at the top ends of the two adapting rods 10 through welding, two square rods 14 are fixedly mounted in the cavity 5 through welding, the two adapting rods 10 are respectively slidably connected with the two square rods 14, tension blocks 11 are fixedly mounted on the outer sides of the two adapting rods 10 through welding, and the same steel wire pull rope 17 is connected on the two tension blocks 11, the steel wire stay cord 17 is connected with the fixed pulley 18 in a transmission way, two extrusion wheels 8 are symmetrically and slidably mounted on the inner wall of the bottom of the cavity 5, and the two extrusion wheels 8 are all in contact with the steel wire stay cord 17.

In this embodiment, two telescopic motors 6 are symmetrically arranged on the inner wall of the bottom of the cavity 5, moving blocks 7 are fixedly mounted on output shafts of the two telescopic motors 6 through welding, and two squeezing wheels 8 are rotatably connected with the two moving blocks 7 respectively.

In this embodiment, the outside slidable mounting of two square poles 14 has same regulating plate 16, installs cylinder 15 through welded fastening on one side inner wall of cavity 5, and the output shaft of cylinder 15 passes through screw fixed connection with regulating plate 16, installs two springs 13 through welded fastening between regulating plate 16 and two adaptation poles 10, and two springs 13 overlap respectively and establish the outside at two square poles 14.

In this embodiment, the backrest 2 is provided with an elastic band 4, and the elastic band 4 is provided with a snap ring.

Example two

Referring to fig. 1-3, a multi-functional leg training frame for neurosurgery comprises a training plate 1, a backrest 2 is slidably mounted on the top of the training plate 1, a push rod motor 3 is arranged on the top of the training plate 1, an output shaft of the push rod motor 3 is fixedly connected with the backrest 2, a cavity 5 is formed in the training plate 1, a vertical rod 19 is rotatably mounted in the cavity 5, a fixed wheel 18 is sleeved on the outer side of the vertical rod 19, two adapting holes 9 are symmetrically formed in the inner wall of the top of the cavity 5, adapting rods 10 are slidably mounted in the two adapting holes 9, a pedal plate 12 is fixedly mounted at the top ends of the two adapting rods 10, two square rods 14 are fixedly mounted in the cavity 5, the two adapting rods 10 are respectively slidably connected with the two square rods 14, tension blocks 11 are fixedly mounted on the outer sides of the two adapting rods 10, the same steel wire pull rope 17 is connected with the fixed wheel 18, two extrusion wheels 8 are symmetrically and slidably mounted on the inner wall of the bottom of the cavity 5, and the two extrusion wheels 8 are both in contact with a steel wire pull rope 17.

In this embodiment, the symmetry is provided with two flexible motors 6 on the bottom inner wall of cavity 5, and the equal fixed mounting of output shaft of two flexible motors 6 has movable block 7, and two pinch rollers 8 rotate with two movable blocks 7 respectively and are connected, and flexible motor 6 can promote two movable blocks 7 and remove, and movable block 7 drives pinch roller 8 and extrudees steel wire stay cord 17, can change the deformation of steel wire stay cord 17, can change the interval that two legs pedaled.

In this embodiment, the outside slidable mounting of two square poles 14 has same regulating plate 16, and fixed mounting has cylinder 15 on one side inner wall of cavity 5, and the output shaft and the regulating plate 16 fixed connection of cylinder 15, fixed mounting have two springs 13 between regulating plate 16 and two adaptation poles 10, and two springs 13 overlap respectively and establish in the outside of two square poles 14, and the spring 13 of setting can be tempered patient's both legs.

In this embodiment, the backrest 2 is provided with the elastic band 4, the elastic band 4 is provided with the snap ring, and the elastic band 4 is arranged to fix the patient.

In the embodiment, when the electric appliance is used, the electric appliance is switched on, the power supply and the controller are switched on, a patient sits on the backrest 2, the backrest 2 is pushed to move by the push rod motor 3, the distance between the backrest 2 and the two pedal plates 12 can be adjusted, the electric appliance can be suitable for patients with different heights to use, the pedal plates 12 are alternately pedaled by two feet, the arranged springs 13 can exercise the two legs of the patient, the arranged steel wire pull ropes 17 can play a transmission role, when the pedaled distance of the two legs needs to be changed, the two telescopic motors 6 are started, the telescopic motors 6 can push the two moving blocks 7 to move, the moving blocks 7 drive the extrusion wheels 8 to extrude the steel wire pull ropes 17, the deformation of the steel wire pull ropes 17 can be changed, the pedaled distance of the two legs can be changed, when the deformation of the springs 13 needs to be changed, the air cylinders 15 are started, the adjusting plates 16 are driven by the air cylinders 15 to move, the distance between the adjusting plates 16 and the two adapting rods 10 can be adjusted, can change spring 13's deformation, all structures in this application can carry out the selection of material and length according to the in service behavior, and the attached drawing is the schematic structure picture, and specific actual dimensions can make appropriate adjustment.

The above descriptions are only preferred embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to, replaced or changed.

Claims (4)

1. A multifunctional leg training frame for neurosurgery comprises a training plate (1), wherein a backrest (2) is slidably mounted at the top of the training plate (1), and is characterized in that a push rod motor (3) is arranged at the top of the training plate (1), an output shaft of the push rod motor (3) is fixedly connected with the backrest (2), a cavity (5) is formed in the training plate (1), a vertical rod (19) is rotatably mounted in the cavity (5), a fixed wheel (18) is sleeved on the outer side of the vertical rod (19), two adapting holes (9) are symmetrically formed in the inner wall of the top of the cavity (5), adapting rods (10) are slidably mounted in the two adapting holes (9), and a pedal plate (12) is fixedly mounted at the top ends of the two adapting rods (10);

fixed mounting has two square poles (14) in cavity (5), two adaptation poles (10) respectively with two square poles (14) sliding connection, the equal fixed mounting in outside of two adaptation poles (10) has pulling force piece (11), be connected with same steel wire stay cord (17) on two pulling force pieces (11), steel wire stay cord (17) are connected with tight pulley (18) transmission, symmetrical sliding mounting has two extrusion wheel (8) on the bottom inner wall of cavity (5), two extrusion wheel (8) all contact with steel wire stay cord (17).

2. The multifunctional leg training frame for neurosurgery according to claim 1, wherein two telescopic motors (6) are symmetrically arranged on the inner wall of the bottom of the cavity (5), moving blocks (7) are fixedly mounted on output shafts of the two telescopic motors (6), and two squeezing wheels (8) are respectively and rotatably connected with the two moving blocks (7).

3. The multifunctional leg training frame for the neurosurgery according to claim 1, wherein the same adjusting plate (16) is slidably mounted on the outer sides of the two square rods (14), the air cylinder (15) is fixedly mounted on the inner wall of one side of the cavity (5), the output shaft of the air cylinder (15) is fixedly connected with the adjusting plate (16), two springs (13) are fixedly mounted between the adjusting plate (16) and the two adapting rods (10), and the two springs (13) are respectively sleeved on the outer sides of the two square rods (14).

4. The multifunctional leg training frame for neurosurgery according to claim 1, characterized in that an elastic band (4) is arranged on said backrest (2), and a snap ring is arranged on said elastic band (4).

Images