CN216652771U - Robot working platform for placing body position, traction, reduction and operation - Google Patents

Abstract

A robot working platform for placing body position, traction, reduction and operation belongs to medical equipment. The utility model has the beneficial effects that: the robot arm slides on the tracks around the plane plate, and completes position arrangement, fracture traction, displacement reduction and operation together with the plane plate, the fixing piles, the limb bracket and the traction support. The fixing piles and the limb bracket can be adjusted randomly according to the operation requirement and the body position and body shape of the patient, and the body position placing, traction, reduction and operation are completed simultaneously. The plane plate is directly arranged on the operating bed, the installation and the operation are simple, the equipment cost is reduced, the operation workload is reduced, and the robot operation work foundation is provided.

Description

Robot working platform for placing body position, traction, reduction and operation

Technical Field

The utility model belongs to a medical instrument for orthopedics department, and particularly relates to a robot working platform for placing body positions, traction, restoration and operation of patients with limb fracture, which is designed according to the traditional Chinese medicine bone setting technology.

Background

The posture, traction and reduction are the three most basic factors in the traditional Chinese medicine bonesetting technology, in traditional Chinese medicine bare-handed manual bonesetting, the posture is the basis for obtaining good traction and reduction, traction is the basic method for fracture reduction, fracture reduction is the further adjustment of traction reduction, and the importance of the three factors is not obvious.

The quality of the fracture traction reduction is determined by the position of the patient. At present, the position of the orthopedic operation is placed without a matched complete special tool, and the position of a patient is placed only by scattered pillows and the like, so that the position requirements of robot traction, reduction and operation treatment of fracture cannot be met.

Traction is an important means for fracture reduction, and better traction effect can be achieved when the body position is reasonably placed. At present, no traction tool is arranged on an orthopedic operating table, only a special traction bed frame is arranged outside the operating table, the traction tool is only used for traction of proximal femur fracture of lower limbs, and no traction tool is arranged for fracture of other parts. The traction bed frame is arranged outside the operating table for traction, the operation is complex, the operation pollution is easily caused, the probability of infection of patients is high, serious consequences are generated, and the treatment effect of fracture is finally influenced.

Fracture reduction is the final aim of traditional Chinese medicine bonesetting, and is to further adjust fracture and reduce the fracture under the conditions of traction and reduction. The final fracture reduction purpose is realized through better position placing and reasonable traction and reduction methods. Furthermore, the orthopaedics is divided into three major parts, namely bone joints, spines and wounds, the application of the existing orthopedic robot to the bone joints, spines and wounds is limited to the positioning level, and particularly, in the trauma orthopaedics, the orthopedic robot is limited to the screw driving of pelvis fracture, and the reduction and the operation of limb fracture are still blank.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects and provide a robot working platform for posture placement, traction, reduction and operation, and the posture placement, traction, reduction and operation of the four-limb fracture can be completed on one working platform at one time.

The purpose of the utility model is realized by the following technical scheme: the utility model provides a put position, pull, restoration and for operation robot work platform which characterized in that: the robot comprises a plane plate, fixing piles, limb brackets, a traction support and a track frame, wherein a plurality of fixing holes are formed in the plane plate, the fixing piles and the limb brackets are respectively inserted into the fixing holes, the plane plate is installed in the track frame, tracks are arranged on the periphery of the track frame, a robot arm capable of sliding along the tracks is installed in the tracks, and the robot arm is connected with the traction support.

The fixing holes are square, hexagonal, quincunx or round.

The aperture of the fixing holes is 3-6cm, and the distance between the fixing holes is 8-15 cm.

The height of the fixing pile is 10-50 cm.

The fixing pile is connected into a column shape by a plurality of supporting units.

The limb bracket is formed by connecting a plurality of supporting units into a door-shaped limb bracket, and the supporting surface of the limb bracket is a cambered surface matched with the anatomical form of the limb.

The contact surface of the fixing pile and the body of the patient is a cambered surface which is inosculated with the anatomical form of the limbs.

The traction support is U-shaped, the two ends of the opening end of the U-shaped traction support are connected with the traction needle, and the closed end of the U-shaped traction support is connected with the robot arm.

The beneficial effects of the utility model are:

1. the plane plate is arranged in the track frame, the robot arms are arranged in the tracks arranged on the periphery of the track frame, and the robot arms slide on the tracks and complete position arrangement, fracture traction, displacement reduction and operation together with the plane plate, the fixing piles for fixing the position of a patient, the limb brackets for supporting and/or fixing limbs and the traction support.

2. Because the fixing piles and the limb bracket adopt the insertion structure, the fixing piles and the limb bracket can be adjusted at will according to the operation requirements and the body position and body shape of the patient, and the body position placing, traction, reduction and operation are completed simultaneously.

3. The plane plate is directly arranged on the operating bed, the installation and the operation are simple, the equipment cost is reduced, the operation workload is reduced, and the working foundation of the operation robot is provided.

4. The platform can be used for artificial joint replacement and body position placement during robot surgery.

5. The platform can be used for placing the body position, traction and closed reduction internal fixation during the current clinical artificial operations of various fractures of limbs.

6. The floor type robot, the plane plate, the fixing pile for fixing the body position of the patient, the limb bracket for supporting and/or fixing the limb and the traction support jointly complete body position placement, fracture traction, displacement reduction and operation.

Drawings

FIG. 1 is a schematic diagram of the present invention.

Wherein: 1-plane plate, 2-fixing hole, 3-fixing pile, 4-limb bracket, 5-traction bracket, 6-track frame, 7-supporting unit, 8-connecting joint, 9-robot arm and 10-track.

Detailed Description

Example (b): as shown in figure 1, a robot work platform for posture arrangement, traction, reduction and operation comprises a plane plate 1, fixing piles 3, limb brackets 4, a traction support 5 and a track frame 6, wherein a plurality of fixing holes 2 are arranged on a plane plate 1 of 50 x (30-200) cm, the distance between the fixing holes 2 is 8-15cm, the aperture of each fixing hole 2 is 3-6cm, the fixing piles 2 for fixing the body of a patient and the limb brackets 4 for supporting and/or fixing the limbs are inserted in the fixing holes 2 according to the requirements of orthopedic operation, in order to lock the fixing piles 2 and/or the limb brackets 4, the fixing holes 2 are preferably designed to be square, hexagonal, quincunx or circular, and according to the body types of the patient, the fixing piles 2 can be connected into a cylinder with the height of 10-50cm through a plurality of supporting units 7 through connecting joints 8, A square column, etc., the contact surface of the fixed pile 2 and the patient body is designed into a cambered surface which is inosculated with the anatomical form of the limbs, the limb bracket 4 is used for supporting, fixing the limbs and resisting the traction of the limbs, a plurality of supporting units 7 can be connected into a door shape through connecting joints 8, two upright posts of the door-shaped limb bracket 4 are respectively inserted into the fixing holes of the plane plate, the supporting surface of the limb bracket 4 for supporting the limbs is designed into a cambered surface which is inosculated with the anatomical form of the limbs, the size of the track frame 6 is 50 x 200cm, which is consistent with the size of an operating bed and is clamped on the operating bed, the plane plate 1 can be arranged into a whole block and is clamped in the track frame 6 or be arranged into a plurality of small blocks, according to the requirement of the treatment part, the fixed at the corresponding position in the track frame 6, the periphery of the track frame 6 is provided with a track 10, 2-4 robot arms 9 which can slide along the track are arranged in the track 10, the robot arm 9 is connected with the traction support 5, the traction support 5 is designed into a U shape, the closed end of the U-shaped traction support 5 is connected with the robot arm 9, the open end of the U-shaped traction support 5 is connected with a traction needle, and the robot arm 9 is controlled by the robot to respectively complete the placing position, traction, reduction and operation; a floor type robot can also be used, an arm 9 of the floor type robot is connected with the traction support 5, the traction support 5 is designed into a U shape, the closed end of the U-shaped traction support 5 is connected with the robot arm 9, the open end of the U-shaped traction support 5 is connected with a traction needle, and the robot arm 9 is controlled by the robot to respectively complete the placing position, traction, restoration and operation.

Case (2):

taking the intertrochanteric fracture operation as an example:

before a patient operates, a bone traction needle penetrates into a tibial tubercle part in a ward, and then the working platform is placed on an operating bed and fixed with the operating bed; then the patient lies on the flat plate with the healthy side on the side, and fixing piles are respectively inserted into the flat plate fixing holes at the joint part of the sacrococcygeal part and the pubic bone of the patient to fix the body of the patient in a side position state; then the limb bracket is arranged at the inner crotch part of the intertrochanteric fracture and is inserted into the fixing hole of the plane plate, and the limb bracket plays a role in supporting the inner part of the intertrochanteric fracture and resisting bone traction; the two ends of the U-shaped opening end of the traction support are connected with bone traction needles, the U-shaped closed end of the traction support is connected with arms of a robot, the arms of the robot are placed on a track of a track frame and can slide on the track to run, and the arms of the robot are longitudinally pulled to reset the fracture between the rotors in the inward-folded and inward-rotated state.

Claims (8)

1. The utility model provides a put position, pull, restoration and for operation robot work platform which characterized in that: the robot comprises a plane plate, fixing piles, limb brackets, a traction support and a track frame, wherein a plurality of fixing holes are formed in the plane plate, the fixing piles and the limb brackets are respectively inserted into the fixing holes, the plane plate is installed in the track frame, tracks are arranged on the periphery of the track frame, a robot arm capable of sliding along the tracks is installed in the tracks, and the robot arm is connected with the traction support.

2. The robotic posturing, traction, reduction and operation work platform of claim 1, wherein: the fixing holes are square, hexagonal, quincunx or round.

3. The robotic posturing, traction, reduction and operation work platform of claim 1, wherein: the aperture of the fixing holes is 3-6cm, and the distance between the fixing holes is 8-15 cm.

4. The robotic posturing, traction, reduction and operation work platform of claim 1, wherein: the height of the fixing pile is 10-50 cm.

5. The robotic work platform for postural positioning, traction, reduction and surgery according to claim 1, wherein: the fixing pile is connected into a column shape by a plurality of supporting units.

6. The robotic posturing, traction, reduction and operation work platform of claim 1, wherein: the limb bracket is formed by connecting a plurality of supporting units into a door-shaped limb bracket, and the supporting surface of the limb bracket is a cambered surface matched with the anatomical form of the limb.

7. A robotic work platform for posturing, traction, reduction and surgery according to claim 1, wherein: the contact surface of the fixing pile and the body of the patient is a cambered surface which is inosculated with the anatomical form of the limbs.

8. A robotic work platform for posturing, traction, reduction and surgery according to claim 1, wherein: the traction support is U-shaped, the two ends of the opening end of the U-shaped traction support are connected with the traction needle, and the closed end of the U-shaped traction support is connected with the robot arm.

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