CN111166599A

CN111166599A - Radiation-proof operation treatment cabin device

Info

Publication number: CN111166599A
Application number: CN202010088662.4A
Authority: CN
Inventors: 彭雪; 罗旭; 刘蕾; 陈图南; 周娅颖
Original assignee: First Affiliated Hospital of PLA Military Medical University
Current assignee: Nanfang Hospital; First Affiliated Hospital of PLA Military Medical University
Priority date: 2020-02-12
Filing date: 2020-02-12
Publication date: 2020-05-19

Abstract

The invention discloses a radiation-proof operation handling cabin device, wherein a medical worker stretches a hand into an operation box to perform an operation, treads a first pedal to enable the first pedal to compress a compression cylinder, the compression cylinder is connected with air pressure in series into an output cylinder through a pipeline and drives a lifting rod to extend towards a direction far away from a base to drive a telescopic arm to ascend, when the medical worker does not apply force to the first pedal, the bottom of the telescopic arm and a sliding rail are limited, so that the height of the operation box can be adjusted without manually operating in the process of interventional operation of the medical worker in the operation box, the operation of the medical worker on an operation bed is more convenient, and the operation effect is better.

Description

Radiation-proof operation treatment cabin device

Technical Field

The invention relates to the field of medical instruments for operations, in particular to a radiation-proof operation treatment cabin device.

Background

At present, under the radiation and radioactive substance contamination emergency rescue state, the operation cabin protection isolation operation needs to be carried out on the critical illness which cannot be washed away or the illness which urgently needs to damage the control operation or treatment, under the condition of self radiation-proof clothes or lead clothes protection, when the nuclear radiation contamination patient is subjected to the operation or treatment, the operation range and the operation accuracy can be influenced due to the wearing of protective equipment, the problem is solved by the application patent, and the influence degree of the equipment on the medical personnel rescue is reduced.

Disclosure of Invention

The invention aims to provide a radiation-proof operation treatment cabin device, and aims to solve the technical problem that in the prior art, under the condition of protection of a radiation-proof garment or a lead garment, when a medical worker performs operation or treatment on a patient infected with nuclear radiation and not decontaminated, the operation range and the operation accuracy are influenced due to wearing of protective equipment.

In order to achieve the above purpose, the radiation-proof surgical treatment cabin device adopted by the invention comprises a base, a surgical box, a first pedal and an adjusting assembly, wherein the surgical box is connected with the base in a sliding manner and is positioned above the base, the first pedal is connected with the base in a rotating manner, is positioned at the bottom of the base, which is far away from the surgical box, is positioned on the outer side wall of the base, and partially extends into the base, the adjusting assembly is abutted against the first pedal, is connected with the base in a sliding manner and is connected with the surgical box in a rotating manner, and the adjusting assembly is positioned between the base and the surgical box; the adjusting assembly comprises a telescopic arm and a driving component, the telescopic arm is connected with the base in a sliding mode, is connected with the operating box in a rotating mode and is located between the base and the operating box, the driving component is abutted against the first pedal, is fixedly connected with the base and is connected with the telescopic arm in a rotating mode, and the driving component drives the telescopic arm to stretch towards the base; the drive component includes compression cylinder, delivery cylinder and jacking rod, compression cylinder with first footboard butt, and with base fixed connection, and be located the base is close to one side of first footboard, delivery cylinder with compression cylinder passes through pipe connection, and with base fixed connection, and be located the base is close to one side of flexible arm, the jacking rod with delivery cylinder sliding connection, and with flexible arm rotates to be connected, and is located delivery cylinder with between the flexible arm.

The compression cylinder comprises a cylinder body and a piston rod, the cylinder body is fixedly connected with the base and is positioned on one side, close to the first pedal, of the base; the piston rod is connected with the cylinder body in a sliding mode, is connected with the first pedal in a rotating mode and is located between the cylinder body and the first pedal.

The driving component further comprises a sliding rail and a connecting roller, the sliding rail is fixedly connected with the base and is positioned on one side, close to the telescopic arm, of the base; the connecting roller is connected with the sliding rail in a sliding mode, is connected with the telescopic arm in a rotating mode, and is located on one side, close to the base, of the telescopic arm.

The sliding rail is provided with a plurality of bulges, and the bulges are uniformly arranged along the extending direction of the sliding rail; the driving component further comprises a limiting clamp, and the limiting clamp is fixedly connected with the telescopic arm, extends and retracts towards the direction of the sliding rail and is abutted to the protrusion.

The limiting clamp comprises a sliding block and a limiting buckle, the sliding block is fixedly connected with the telescopic arm and is in sliding connection with the sliding rail, and the sliding block is positioned at one end, close to the sliding rail, of the telescopic arm; the limiting buckle is connected with the sliding block in a sliding mode, is electrically connected with the output cylinder, and extends out of the sliding block and abuts against the protrusion.

The radiation-proof operation treatment cabin device further comprises a second pedal and a rotary driving device, wherein the second pedal is rotatably connected with the base and is positioned on one side, close to the first pedal, of the base; the rotary driving device is electrically connected with the second pedal, fixedly connected with the telescopic arm and rotatably connected with the operation box, and is positioned between the telescopic arm and the operation box.

The rotary driving device comprises a rotary stepping motor and a contact switch, the rotary stepping motor is in rotary connection with the telescopic arm, is in rotary connection with the operating box and is positioned on one side of the telescopic arm close to the operating box; the contact switch is abutted against the second pedal, is electrically connected with the rotary stepping motor, and is positioned between the base and the second pedal.

The rotary driving device further comprises a rotary platform, the rotary platform is connected with the rotary stepping motor in a rotating mode, the rotary platform is fixedly connected with the operation box and located on one side, close to the operation box, of the rotary stepping motor.

The operation box is provided with an operation opening, and the operation opening is positioned on the outer side of the operation box and extends into the operation box; the radiation-proof operation treatment cabin device further comprises a protection arm, wherein the protection arm is fixedly connected with the operation box and is positioned in the operation port and extends into the operation box.

The radiation-proof operation treatment cabin device further comprises a rotary bearing, the rotary bearing is fixedly connected with the operation box, is rotatably connected with the protection arm and is located inside the operation opening, and the rotary bearing is located between the protection arm and the operation box.

According to the radiation-proof operation handling cabin device, a medical worker stretches a hand into the operation box to perform an operation, treads the first pedal to enable the first pedal to compress the compression cylinder, the compression cylinder is connected with air pressure in series into the output cylinder through a pipeline and drives the jacking rod to stretch out in a direction far away from the base to drive the telescopic arm to lift upwards, when the medical worker does not apply force to the first pedal, the bottom of the telescopic arm and the sliding rail are limited, so that the height of the operation box can be adjusted without manual operation and control during the operation of the medical worker in the operation box, the operation of the medical worker on an operation bed is more convenient, and the operation effect is better.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic view of the external structure of the elevating platform of the present invention.

FIG. 2 is a schematic view of the structure of the surgical cassette of the present invention

Fig. 3 is a schematic view of the structure of the inside of the base of the present invention.

Fig. 4 is a schematic view of the sliding structure of the telescopic arm and the base of the present invention.

Fig. 5 is a schematic view of the connection of the protective arm of the present invention to a surgical cassette.

In the figure: 1-base, 2-operation box, 3-first pedal, 4-adjusting component, 5-second pedal, 6-rotary driving device, 7-protective arm, 8-rotary bearing, 21-operation opening, 41-telescopic arm, 42-driving component, 61-rotary stepping motor, 62-contact switch, 63-rotary platform, 100-radiation-proof operation treatment cabin device, 421-compression cylinder, 422-output cylinder, 423-jacking rod, 424-sliding rail, 425-connecting roller, 426-limit card, 521-cylinder, 522-piston rod, 523-protrusion, 524-sliding block and 525-limit buckle.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In a first example of the present embodiment:

referring to fig. 1 to 4, the present invention provides a radiation-proof surgical treatment cabin device 100, including a base 1, a surgical box 2, a first pedal 3 and an adjusting assembly 4, wherein the surgical box 2 is slidably connected to the base 1 and is located above the base 1, the first pedal 3 is rotatably connected to the base 1 and is located at the bottom of the base 1 away from the surgical box 2 and is located at the outer side wall of the base 1, and a part of the first pedal extends into the base 1, the adjusting assembly 4 is abutted to the first pedal 3 and is slidably connected to the base 1 and is rotatably connected to the surgical box 2, and the adjusting assembly 4 is located between the base 1 and the surgical box 2; the adjusting assembly 4 comprises a telescopic arm 41 and a driving member 42, the telescopic arm 41 is slidably connected with the base 1, rotatably connected with the operating box 2 and located between the base 1 and the operating box 2, the driving member 42 is abutted against the first pedal 3, fixedly connected with the base 1 and rotatably connected with the telescopic arm 41, and the driving member 42 drives the telescopic arm 41 to extend and retract towards the base 1; the driving member 42 includes a compression cylinder 421, an output cylinder 422 and a lifting rod 423, the compression cylinder 421 abuts against the first pedal 3, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the first pedal 3, the output cylinder 422 is connected to the compression cylinder 421 through a conduit, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the telescopic arm 41, and the lifting rod 423 is slidably connected to the output cylinder 422, is rotatably connected to the telescopic arm 41, and is located between the output cylinder 422 and the telescopic arm 41.

Further, the compression cylinder 421 includes a cylinder 521 and a piston rod 522, the cylinder 521 is fixedly connected to the base 1 and is located on one side of the base 1 close to the first pedal 3; the piston rod 522 is slidably connected to the cylinder 521, rotatably connected to the first pedal 3, and located between the cylinder 521 and the first pedal 3.

Further, the driving member 42 further includes a slide rail 424 and a connecting roller 425, the slide rail 424 is fixedly connected to the base 1 and is located on a side of the base 1 close to the telescopic arm 41; the connecting roller 425 is slidably connected to the slide rail 424, rotatably connected to the telescopic arm 41, and located on one side of the telescopic arm 41 close to the base 1.

Further, the slide rail 424 is provided with a plurality of protrusions 523, and the protrusions 523 are uniformly arranged along the extending direction of the slide rail 424; the driving member 42 further includes a limiting clip 426, and the limiting clip 426 is fixedly connected to the telescopic arm 41, extends and retracts in the direction of the slide rail 424, and abuts against the protrusion 523.

Further, the limit card 426 includes a slider 524 and a limit buckle 525, the slider 524 is fixedly connected to the telescopic arm 41, is slidably connected to the slide rail 424, and is located at one end of the telescopic arm 41 close to the slide rail 424; the limiting buckle 525 is connected with the sliding block 524 in a sliding manner, is electrically connected with the output cylinder 422, and extends out of the sliding block 524 to be abutted against the protrusion 523.

In this embodiment, the base 1 is a rectangular platform and is placed on the sliding platform, the sliding plate of the sliding platform is fixed with the base 1 by screw threads, the sliding plate is connected with the sliding platform by a screw rod, the screw rod is driven to rotate after the motor is powered on, and then the sliding plate is driven to drive the base 1 to move linearly, the number of the screw rods is two, the screw rods are respectively arranged on different horizontal planes, the projection is vertically intersected, the screw rods horizontally slide along with the sliding plate, and the screw rods are limited by the sliding platform in other directions, so that the base 1 drives the operation box to adjust the operation box on the horizontal plane in the front-back and left-right directions, a power supply, an operation tool and the like for operation are arranged in the base 1, instrument operation tables are arranged on two sides of the base 1, a controller for adjusting the position of the operation box 2 to slide left and right is arranged on one side, the other side is provided with surgical equipment; the inner layer and the outer layer of the operation box 2 are made of transparent lead-containing glass, so that the operation and observation of the condition in the operation box 2 are facilitated, the operation box 2 is provided with the operation ports 21, the left side and the right side of the operation box 2 are respectively provided with 4 operation ports 21, the front side and the rear side of the operation ports are respectively provided with 2 operation ports, medical staff can stretch hands to enter the operation box 2, and the top of the outer side of the operation box 2 is provided with an environment monitor which can monitor the radiation quantity outside the operation box 2 in real time and display the radiation quantity; the first pedal 3 is rotatably connected with the base 1 through a rotating shaft, and partially extends out of the outer surface of the base 1 for an operator to step on, when the operator steps on the first pedal 3, the first pedal 3 rotates around the rotating shaft to be close to the base 1, the compression cylinder 421 is installed between the first pedal 3 and the base 1, the compression cylinder 421 comprises the cylinder 521 and the piston rod 522, the piston head of the piston rod 522 is driven by the rod part to slide in the cylinder 521 to extrude the gas in the cylinder 521, the piston rod 522 is rotatably connected with the bottom of the first pedal 3, the piston rod 522 is driven by the first pedal 3 to slide up and down, the output cylinder 422 is threadedly installed on the upper surface of the base 1 and is connected with the compression cylinder 421 through a pipeline in series, receiving the pressure information transmitted by the compression cylinder 421, fixing ends of the jacking rods 423 being fixed on the surface of the output cylinder 422, and being driven by the output cylinder 422 to extend and retract the sliding rods of the jacking rods 423, the telescopic arms 41 being cross-connected and being connected at cross positions by screws, and cross points being capable of sliding up and down on the screws, the bottoms of the telescopic arms 41 being horizontally slid on the sliding rails 424 by the connection rollers 425, both ends of the tops of the telescopic arms 41 being rotatably connected with the surgical box 2 by rotating shafts, the tops of the telescopic arms 41 being axially rotated along the rotating shafts and being slid along cross directions, so as to change the vertical heights of the telescopic arms 41, ends of the jacking rods 423 far from the output cylinder 422 being rotatably connected with cross positions of the telescopic arms 41 by rotating shafts, and the jacking rods 423 driving the telescopic arms 41 to slide in directions perpendicular to the base 1, the surgical box 2 is further driven to be close to or far away from the base 1, the protrusions 523 are uniformly arranged inside the track of the sliding rail 424, the protrusions 523 are rhombic protrusions 523, the sliding block 524 is fixed at one end, close to the sliding rail 424, of the telescopic arm 41 in a threaded manner, the limiting buckle 525 is connected with the sliding block 524 in a sliding manner and is electrically connected with the output cylinder 422 through an electric wire, the output cylinder 422 outputs pressure and generates an electric signal, the electric signal is transmitted to a processor of the limiting buckle 525, and the limiting buckle 525 contracts towards the inside of the sliding block 524, so that the telescopic arm 41 can slide along with the sliding rail 424; the output cylinder 422 stops outputting pressure, the telescopic clamp extends towards the direction of the slide rail 424 and is clamped with the bulge 523 to limit the telescopic arm 41; (ii) a Therefore, when a medical staff inserts a hand into the operating box 2 to perform an operation, and treads the first pedal 3, so that the first pedal 3 drives the piston rod 522 to extrude the cylinder 521, the compression cylinder 421 connects the air pressure in series into the output cylinder 422 through a pipeline, and drives the lifting rod 423 to extend in a direction away from the base 1, so as to drive the telescopic arm 41 to rise, and meanwhile, the slide rail 424 at the bottom of the telescopic arm 41 slides on the slide rail 424, so as to release the first pedal 3, the limiting buckle 525 extends out of the slide block 524 to be clamped with the protrusion 523 of the slide rail 424, so as to limit the telescopic arm 41, so that the height of the operating box 2 can be adjusted without manual operation during the operation of a newborn baby, and the operation of the operating bed by the medical staff is more convenient, thereby the operation effect is better.

In a second example of the present embodiment:

referring to fig. 1 and 2, the present invention provides a radiation-proof surgical treatment cabin device 100, including a base 1, a surgical box 2, a first pedal 3 and an adjusting assembly 4, wherein the surgical box 2 is slidably connected to the base 1 and is located above the base 1, the first pedal 3 is rotatably connected to the base 1 and is located at the bottom of the base 1 away from the surgical box 2 and is located on the outer side wall of the base 1, and a part of the first pedal extends into the base 1, the adjusting assembly 4 is abutted to the first pedal 3 and is slidably connected to the base 1 and is rotatably connected to the surgical box 2, and the adjusting assembly 4 is located between the base 1 and the surgical box 2; the adjusting assembly 4 comprises a telescopic arm 41 and a driving member 42, the telescopic arm 41 is slidably connected with the base 1, rotatably connected with the operating box 2 and located between the base 1 and the operating box 2, the driving member 42 is abutted against the first pedal 3, fixedly connected with the base 1 and rotatably connected with the telescopic arm 41, and the driving member 42 drives the telescopic arm 41 to extend and retract towards the base 1; the driving member 42 includes a compression cylinder 421, an output cylinder 422 and a lifting rod 423, the compression cylinder 421 abuts against the first pedal 3, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the first pedal 3, the output cylinder 422 is connected to the compression cylinder 421 through a conduit, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the telescopic arm 41, and the lifting rod 423 is slidably connected to the output cylinder 422, is rotatably connected to the telescopic arm 41, and is located between the output cylinder 422 and the telescopic arm 41.

Further, the radiation-proof surgical treatment cabin device 100 further comprises a second pedal 5 and a rotary driving device 6, wherein the second pedal 5 is rotatably connected with the base 1 and is positioned on one side of the base 1 close to the first pedal 3; the rotation driving device 6 is electrically connected with the second pedal 5, fixedly connected with the telescopic arm 41 and rotatably connected with the operation box 2, and the rotation driving device 6 is positioned between the telescopic arm 41 and the operation box 2.

Further, the rotary driving device 6 comprises a rotary stepping motor 61 and a contact switch 62, wherein the rotary stepping motor 61 is rotatably connected with the telescopic arm 41, is rotatably connected with the surgical box 2, and is positioned at one side of the telescopic arm 41 close to the surgical box 2; the contact switch 62 abuts against the second step 5, is electrically connected to the rotary stepping motor 61, and is located between the base 1 and the second step 5.

Further, the rotation driving device 6 further includes a rotation platform 63, and the rotation platform 63 is rotatably connected to the rotation stepping motor 61, is fixedly connected to the surgical box 2, and is located at one side of the rotation stepping motor 61 close to the surgical box 2.

In this embodiment, the second pedal 5 is located on the side of the base 1 close to the first pedal 3, the contact switch 62 is arranged in the bottom of the second pedal 5, one surface of the contact switch 62 close to the second pedal 5 is provided with a power connection elastic sheet, the bottom of the second pedal 5 is provided with a conductive copper sheet, the second pedal 5 is connected with the contact switch 62, and then the power supply of the rotary stepping motor 61 is switched on, the rotary stepping motor 61 is fixed on one end of the telescopic arm 41 far away from the base 1 through screw threads, and rotates with the operation box 2 through the rotating platform 63, so that the medical staff drives the rotating stepping motor 61 to rotate by stepping on the second pedal 5, thereby driving the operation box 2 and the base 1 to rotate so as to adjust the positions of the medical staff and the neonate for the medical staff to perform the operation.

In a third example of the present embodiment:

referring to fig. 1, 2, 3 and 5, the present invention provides a radiation-proof surgical treatment cabin device 100, which includes a base 1, a surgical box 2, a first pedal 3 and an adjusting assembly 4, wherein the surgical box 2 is slidably connected to the base 1 and is located above the base 1, the first pedal 3 is rotatably connected to the base 1 and is located at the bottom of the base 1 away from the surgical box 2 and is located on the outer side wall of the base 1, and partially extends into the base 1, the adjusting assembly 4 is abutted to the first pedal 3 and is slidably connected to the base 1 and is rotatably connected to the surgical box 2, and the adjusting assembly 4 is located between the base 1 and the surgical box 2; the adjusting assembly 4 comprises a telescopic arm 41 and a driving member 42, the telescopic arm 41 is slidably connected with the base 1, rotatably connected with the operating box 2 and located between the base 1 and the operating box 2, the driving member 42 is abutted against the first pedal 3, fixedly connected with the base 1 and rotatably connected with the telescopic arm 41, and the driving member 42 drives the telescopic arm 41 to extend and retract towards the base 1; the driving member 42 includes a compression cylinder 421, an output cylinder 422 and a lifting rod 423, the compression cylinder 421 abuts against the first pedal 3, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the first pedal 3, the output cylinder 422 is connected to the compression cylinder 421 through a conduit, and is fixedly connected to the base 1, and is located on one side of the base 1 close to the telescopic arm 41, and the lifting rod 423 is slidably connected to the output cylinder 422, is rotatably connected to the telescopic arm 41, and is located between the output cylinder 422 and the telescopic arm 41.

Further, the surgical box 2 is provided with an operation port 21, and the operation port 21 is positioned on the outer side of the surgical box 2 and extends into the surgical box 2; the radiation-proof operation treatment cabin device 100 further comprises a protection arm 7, wherein the protection arm 7 is fixedly connected with the operation box 2, is positioned in the operation opening 21 and extends into the operation box 2.

Further, the radiation-proof operation treatment cabin device 100 further comprises a rotary bearing 8, the rotary bearing 8 is fixedly connected with the operation box 2, is rotatably connected with the protection arm 7 and is located inside the operation opening 21, and the rotary bearing 8 is located between the protection arm 7 and the operation box 2.

In this embodiment, the operation ports 21 are plural in number, and two are in a group, and are respectively located on four outer side surfaces of the operation box 2, the rotary bearing 8 is integrally fixed on the side wall of the operation opening 21, the rotary bearing 8 is made of lead-containing alloy material and has good radiation-proof performance, the shell of the rotary bearing 8 is integrally fixed with the operation box 2, the inner shell rotates through the ball, the protective arm 7 is integrally fixed on the surface of the inner shell of the rotating bearing 8, and extends into the operation box 2, the protection arm 7 is made of lead-containing nylon and has good deformability, one end of the protective arm 7 extending into the operation box 2 is integrally fixed with protective gloves, the protective gloves and the protective arm 7 are made of lead-containing nylon, hands of medical staff can move freely, and the protective gloves have good protection performance; the protection arm 7 passes through the solid fixed ring that the outside is connected in operation case 2 fixes, and fixed position is located operation case 2 operation mouth 21 department to solid fixed ring with swivel bearing 8 joint makes swivel bearing 8 rotates in solid fixed ring's inside, and solid fixed ring accessible screw thread is dismantled, and is convenient right the replacement is dismantled to protection arm 7, medical staff's accessible protection arm 7 is in freely movable arm in operation case 2, and pass through swivel bearing 8 axial rotates the angle of arm, makes medical staff's arm activity more nimble, and operation is more convenient, and then makes the operation effect better.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A radiation-proof operation treatment cabin device is characterized by comprising a base, an operation box, a first pedal and an adjusting component,

the surgical box is connected with the base in a sliding mode and located above the base, the first pedal is connected with the base in a rotating mode, located at the bottom, far away from the surgical box, of the base and located on the outer side wall of the base, and partially extends into the base, the adjusting assembly is abutted to the first pedal, connected with the base in a sliding mode and rotationally connected with the surgical box, and located between the base and the surgical box;

the adjusting assembly comprises a telescopic arm and a driving component, the telescopic arm is connected with the base in a sliding mode, is connected with the operating box in a rotating mode and is located between the base and the operating box, the driving component is abutted against the first pedal, is fixedly connected with the base and is connected with the telescopic arm in a rotating mode, and the driving component drives the telescopic arm to stretch towards the base;

the drive component includes compression cylinder, delivery cylinder and jacking rod, compression cylinder with first footboard butt, and with base fixed connection, and be located the base is close to one side of first footboard, delivery cylinder with compression cylinder passes through pipe connection, and with base fixed connection, and be located the base is close to one side of flexible arm, the jacking rod with delivery cylinder sliding connection, and with flexible arm rotates to be connected, and is located delivery cylinder with between the flexible arm.

2. The radiation protective surgical treatment cabin device of claim 1,

3. The radiation protective surgical treatment cabin device according to claim 2,

4. The radiation protective surgical treatment cabin device according to claim 3,

the sliding rail is provided with a plurality of bulges which are uniformly arranged along the extending direction of the sliding rail; the driving component further comprises a limiting clamp, and the limiting clamp is fixedly connected with the telescopic arm, extends and retracts towards the direction of the sliding rail and is abutted to the protrusion.

5. The radiation protective surgical treatment cabin device according to claim 4,

the limiting clamp comprises a sliding block and a limiting buckle, the sliding block is fixedly connected with the telescopic arm, is connected with the sliding rail in a sliding manner, and is positioned at one end, close to the sliding rail, of the telescopic arm; the limiting buckle is connected with the sliding block in a sliding mode, is electrically connected with the output cylinder, and extends out of the sliding block and abuts against the protrusion.

6. The radiation protective surgical treatment cabin device of claim 1,

the radiation-proof operation treatment cabin device also comprises a second pedal and a rotary driving device, wherein the second pedal is rotatably connected with the base and is positioned on one side of the base close to the first pedal; the rotary driving device is electrically connected with the second pedal, fixedly connected with the telescopic arm and rotatably connected with the operation box, and is positioned between the telescopic arm and the operation box.

7. The radiation protective surgical treatment cabin device according to claim 6,

the rotary driving device comprises a rotary stepping motor and a contact switch, the rotary stepping motor is in rotary connection with the telescopic arm, is in rotary connection with the operation box and is positioned on one side of the telescopic arm close to the operation box; the contact switch is abutted against the second pedal, is electrically connected with the rotary stepping motor, and is positioned between the base and the second pedal.

8. The radiation protective surgical treatment cabin device according to claim 7,

9. The radiation protective surgical treatment cabin device of claim 1,

10. The radiation protective surgical treatment cabin device of claim 9,

the radiation-proof operation treatment cabin device further comprises a rotary bearing, the rotary bearing is fixedly connected with the operation box and is connected with the protection arm in a rotating mode and located in the operation opening, and the rotary bearing is located between the protection arm and the operation box.