阅读说明：本技术 一种多功能的影像科x射线扫描设备 (Multi-functional image branch of academic or vocational study X ray scanning equipment ) 是由 亓立勇 于 2021-10-19 设计创作，主要内容包括：本发明提供一种多功能的影像科X射线扫描设备,包括组装底座,竖盒,第一减速器,第一电机,升降座,转动板架结构,调节支撑臂结构,X射线接收板,U型放置座,射线发射器,夹紧板,操作螺栓,控制器,控制开关,站立移动台结构和竖螺杆,所述的组装底座上表面的左侧螺栓安装有竖盒,并在竖盒的上端螺栓安装第一减速器；所述的第一减速器上端螺栓安装有第一电机,且第一减速器的下端键连接有竖螺杆,并且竖螺杆的下端通过轴承安装在竖盒内部的下侧。本发明的有益效果为：通过转动板架结构的设置,带动连接臂进行支撑并辅助转动使用。(The invention provides multifunctional X-ray scanning equipment for an imaging department, which comprises an assembling base, a vertical box, a first speed reducer, a first motor, a lifting seat, a rotating plate frame structure, an adjusting support arm structure, an X-ray receiving plate, a U-shaped placing seat, a ray emitter, a clamping plate, an operating bolt, a controller, a control switch, a standing mobile platform structure and a vertical screw rod, wherein the vertical box is installed on a left bolt on the upper surface of the assembling base, and the first speed reducer is installed on an upper bolt of the vertical box; first reduction gear upper end bolt install first motor, and the lower extreme key-type of first reduction gear has perpendicular screw rod to the lower extreme of perpendicular screw rod passes through the bearing and installs the downside in erecting the box inside. The invention has the beneficial effects that: through the setting of rotating grillage structure, drive the linking arm and support and supplementary rotation and use.)

1. The multifunctional X-ray scanning equipment for the department of imaging is characterized by comprising an assembling base (1), a vertical box (2), a first speed reducer (3), a first motor (4), a lifting seat (5), a rotating plate frame structure (6), an adjusting support arm structure (7), an X-ray receiving plate (8), a U-shaped placing seat (9), a ray emitter (10), a clamping plate (11), an operating bolt (12), a controller (13), a control switch (14), a standing mobile platform structure (15) and a vertical screw rod (16), wherein the vertical box (2) is installed on a left bolt on the upper surface of the assembling base (1), and the first speed reducer (3) is installed on an upper bolt of the vertical box (2); a first motor (4) is installed on the upper end of the first speed reducer (3) through a bolt, the lower end of the first speed reducer (3) is connected with a vertical screw (16) in a key mode, and the lower end of the vertical screw (16) is installed on the lower side of the interior of the vertical box (2) through a bearing; the lifting seat (5) is inserted into the vertical box (2), and a vertical screw (16) is connected with the lifting seat (5) through internal threads; the rotating plate frame structure (6) is arranged on the front surface of the lifting seat (5); the adjusting support arm structure (7) is arranged at the front end of the rotating plate frame structure (6); the X-ray receiving plate (8) and the U-shaped placing seat (9) are fixed on the left side and the right side of the front surface of the adjusting support arm structure (7); the ray emitter (10) is arranged on the inner side of the U-shaped placing seat (9); an operating bolt (12) is movably embedded at the upper end of the clamping plate (11), and the operating bolt (12) is in threaded connection with the upper side inside the U-shaped placing seat (9); the controller (13) is installed on the lower portion of the left surface of the vertical box (2) through a bolt, and a control switch (14) is embedded in the left end of the controller (13); the standing mobile station structure (15) is arranged on the right side of the upper surface of the assembly base (1); the adjusting support arm structure (7) comprises a connecting arm (71), a wrapping barrel (72), a mounting cavity (73), a manual disc (74), a through hole (75), a translation screw (76) and a sealing plug (77), wherein the connecting arm (71) is inserted into the left side and the right side of the interior of the wrapping barrel (72) and fixed through a bolt; the mounting cavity (73) is formed in the left side of the inner part of the connecting arm (71), and a sealing plug (77) is mounted in the mounting cavity (73) in a bolt manner; a translation screw (76) is mounted at the right end of the manual disc (74) through a bolt; the through holes (75) are formed in the front end and the rear end of the inner part of the connecting arm (71); the translation screw rod (76) is movably embedded in the middle part of the interior of the sealing plug (77).

2. The multifunctional X-ray scanning equipment for the department of imaging as claimed in claim 1, wherein two connecting arms (71) are provided and are matched with the left end and the right end of the wrapping cylinder (72), the joint of the wrapping cylinder (72) and the connecting arms (71) is fixed through bolts, the mounting cavity (73) is communicated with the through hole (75), the U-shaped placing seat (9) is inserted into the mounting cavity (73) and the through hole (75), the rear end of the U-shaped placing seat (9) is provided with a T-shaped steel block, the sealing plug (77) is T-shaped, the inside of the sealing plug (77) movably supports a translation screw rod (76), and the translation screw rod (76) is in threaded connection with the U-shaped placing seat (9).

3. The multifunctional X-ray scanner for department of imaging as claimed in claim 1, wherein said rotating rack structure (6) comprises an assembly plate (61), a rotating shaft (62), a first gear (63), a second reducer (64), a second motor (65) and a positioning limiting seat structure (66), the rear end of said assembly plate (61) is bolted to the front surface of the lifting seat (5); the rotating shaft (62) is mounted in the middle of the inside of the assembling plate (61) through a bearing, and a connecting arm (71) is mounted at the front end of the rotating shaft (62) through a bolt; the first gear (63) is embedded on the outer wall of the rotating shaft (62); the second speed reducer (64) is mounted on the lower portion of the rear surface of the assembling plate (61) through bolts, and a second motor (65) is mounted on the lower portion of the right end of the second speed reducer (64) through bolts; the positioning limiting seat structure (66) is arranged on the right side of the front surface of the assembling plate (61).

4. The multifunctional X-ray scanner of claim 3, wherein the positioning-limiting base structure (66) comprises a fastening cylinder (661), a long plate (662), a connecting post (663), a tightening plate (664), a second gear (665) and a slot (666), the fastening cylinder (661) is bolted to the upper right portion of the rear surface of the assembly plate (61), and an output shaft of the fastening cylinder (661) passes through the assembly plate (61) and is bolted to the long plate (662); the connecting column (663) is arranged at the lower part of the rear end of the long plate (662) by bolts, and a jacking disc (664) is glued at the rear end of the connecting column (663); the second gear (665) is connected to the front end of the second speed reducer (64) in a shaft mode, and the second gear (665) is arranged on the front surface of the assembling plate (61); the draw-in groove (666) set up in the inside outside in front of second gear (665).

5. The multifunctional X-ray scanner apparatus for department of imaging as claimed in claim 3, wherein said rotating cylinders (62) inside said assembling plate (61) each support a first gear (63) and a connecting plate (71), said first gear (63) being engaged with a second gear (665).

6. The multifunctional X-ray scanner of claim 3, wherein the lower portion of the right end of the second decelerator (64) is connected to the output shaft of the second motor (65), and the second gear (665) is supported by the front end of the second decelerator (65).

7. The multifunctional X-ray scanner as set forth in claim 4, wherein the slot (666) in the second gear (665) is in close contact with the tightening plate (664) of the connecting column (663), the long plate (662) is supported by the output shaft of the fastening cylinder (661), and the long plate (662) is assembled with the connecting column (663) in an L-shape.

8. The multifunctional X-ray scanner as claimed in claim 1, wherein the standing mobile platform structure (15) comprises a platform (151), a pulley (152), a protective slide rail (153), a connecting side plate (154), a measuring plate (155), a moving plate (156) and a pointer (157), the connecting side plate (154) is mounted on the left and right sides of the lower surface of the platform (151) by bolts, and the pulley (152) is coupled to the connecting side plate (154); the protection slide rails (153) are arranged on the right side and the middle right side of the upper surface of the assembly base (1) through bolts, and pulleys (152) are inserted into the left side and the right side of each protection slide rail (153); the measuring plate (155) is mounted on the upper surface of the assembling base (1) through bolts, and the measuring plate (155) is arranged on the right side of the protective sliding rail (153); the moving plate (156) is mounted on the lower portion of the right end of the platform (151) through bolts, and a pointer (157) is welded to the lower portion of the right end of the moving plate (156).

9. The multifunctional X-ray scanner as claimed in claim 8, wherein the connecting side plate (154) on the lower side of the platform (151) is fitted over the outer side of the anti-slip rail (153), and the pulley (152) on the inner side of the connecting side plate (154) is supported on the upper surface of the assembly base (1).

10. The multifunctional X-ray scanning equipment for department of imaging as claimed in claim 8, wherein the right side of the upper surface of said measuring plate (155) is provided with graduation lines in cm, and the graduation lines correspond to the pointer (157), the left side inside said measuring plate (155) is provided with a T-shaped sliding slot, and the sliding slot is connected with the moving plate (156) through a bolt and a nut.

Technical Field

The invention belongs to the technical field of medical instruments, and particularly relates to a multifunctional X-ray scanning device for an imaging department.

Background

The X-ray is actually an electromagnetic wave with extremely high frequency, extremely short wavelength and large energy, the frequency is generally higher than 30PHz, the wavelength is shorter than 10nm, the energy is more than 124eV, and in the existing medical imaging department, the X-ray scanning equipment is used for scanning, so that the patient condition can be better checked and treated.

However, the existing X-ray scanning equipment for the department of imaging still has the problems that the scanning position is not convenient to adjust and use, the flexible rotation is not convenient to use, and the detection position is not convenient to accurately adjust and use.

Therefore, it is necessary to invent a multifunctional X-ray scanner for imaging department.

Disclosure of Invention

In order to solve the technical problems, the invention provides a multifunctional imaging department X-ray scanning device, which aims to solve the problems that the scanning position of the existing imaging department X-ray scanning device is inconvenient to adjust and use, the scanning position is inconvenient to flexibly rotate to use, and the detection position is inconvenient to accurately adjust and use. A multifunctional X-ray scanning device for an imaging department comprises an assembling base, a vertical box, a first speed reducer, a first motor, a lifting seat, a rotating plate frame structure, an adjusting support arm structure, an X-ray receiving plate, a U-shaped placing seat, a ray emitter, a clamping plate, an operating bolt, a controller, a control switch, a standing mobile platform structure and a vertical screw rod, wherein the vertical box is installed on a left bolt on the upper surface of the assembling base, and the first speed reducer is installed on an upper bolt of the vertical box; a first motor is mounted on an upper end bolt of the first speed reducer, the lower end of the first speed reducer is connected with a vertical screw rod in a key mode, and the lower end of the vertical screw rod is mounted on the lower side of the interior of the vertical box through a bearing; the lifting seat is inserted into the vertical box, and a vertical screw rod is connected with the inner thread of the lifting seat; the rotating plate frame structure is arranged on the front surface of the lifting seat; the adjusting support arm structure is arranged at the front end of the rotating plate frame structure; the X-ray receiving plate and the U-shaped placing seat are fixed on the left side and the right side of the front surface of the adjusting support arm structure; the ray emitter is arranged on the inner side of the U-shaped placing seat; an operating bolt is movably embedded at the upper end of the clamping plate and is in threaded connection with the upper side inside the U-shaped placing seat; the controller bolt is arranged on the lower part of the left surface of the vertical box, and a control switch is embedded at the left end of the controller; the standing mobile station structure is arranged on the right side of the upper surface of the assembling base; the adjustable supporting arm structure comprises connecting arms, a wrapping cylinder, an installation cavity, a manual disc, a through hole, a translation screw rod and a sealing plug, wherein the connecting arms are inserted into the left side and the right side of the interior of the wrapping cylinder and are fixed through bolts; the mounting cavity is formed in the left side of the inner part of the connecting arm, and a sealing plug is mounted on a bolt in the mounting cavity; a translation screw is arranged on a bolt at the right end of the manual disc; the through holes are formed in the front end and the rear end inside the connecting arm; the translation screw rod is movably embedded in the middle part of the interior of the sealing plug.

Preferably, the rotating plate frame structure comprises an assembling plate, a rotating shaft, a first gear, a second speed reducer, a second motor and a positioning limiting seat structure, and the rear end of the assembling plate is connected with the front surface of the lifting seat through a bolt; the rotating shaft is arranged in the middle of the inside of the assembling plate through a bearing, and a connecting arm is arranged at the front end of the rotating shaft through a bolt; the first gear is embedded on the outer wall of the rotating shaft; the second speed reducer is mounted on the lower portion of the rear surface of the assembling plate through a bolt, and a second motor is mounted on the lower portion of the right end of the second speed reducer through a bolt; the positioning limiting seat structure is arranged on the right side of the front surface of the assembling plate.

Preferably, the positioning limiting seat structure comprises a fastening electric cylinder, a long plate, a connecting column, a jacking disc, a second gear and a clamping groove, wherein a fastening electric cylinder bolt is arranged at the upper right part of the rear surface of the assembling plate, and an output shaft of the fastening electric cylinder penetrates through the assembling plate and is connected with the long plate bolt; the connecting column bolt is arranged at the lower part of the rear end of the long plate, and the rear end of the connecting column is glued with a jacking disc; the second gear is connected to the front end of the second speed reducer in a shaft mode and is arranged on the front surface of the assembling plate; the clamping groove is formed in the outer side of the front portion inside the second gear.

Preferably, the standing mobile station structure comprises a platform, pulleys, a protective slide rail, connecting side plates, a measuring plate, a moving plate and a pointer, wherein the connecting side plates are mounted on the left side and the right side of the lower surface of the platform through bolts, and the connecting side plates are connected with the pulleys through shafts; the protection slide rails are all installed on the right side and the middle right side of the upper surface of the assembly base through bolts, and pulleys are inserted into the left side and the right side of each protection slide rail; the measuring plate is arranged on the upper surface of the assembling base through bolts and is arranged on the right side of the protective slide rail; the movable plate is installed on the lower portion of the right end of the platform through bolts, and a pointer is welded to the lower portion of the right end of the movable plate.

Preferably, the connecting arms are provided with two connecting arms, the two connecting arms are matched with the left end and the right end of the wrapping barrel, and the joint of the wrapping barrel and the connecting arms is fixed through bolts.

Preferably, installation cavity and interlude hole connection intercommunication, installation cavity and interlude hole inside peg graft and have the U type to place the seat, the U type place the rear end of seat and be provided with T shaped steel piece, the sealing plug set up to the T type, and the inside movable support of sealing plug has the translation screw rod, the translation screw rod with place seat threaded connection with the U type.

Preferably, the rotating cylinders in the assembling plate support a first gear and a connecting plate, and the first gear is meshed with the second gear.

Preferably, the lower part of the right end of the second speed reducer is in key connection with an output shaft of the second motor, and a second gear is supported at the front end of the second speed reducer.

Preferably, the clamping groove in the second gear is in close contact with the tightening disc on the connecting column.

Preferably, the long plate is supported by an output shaft of the fastening electric cylinder, and the long plate and the connecting column are assembled to form an L shape.

Preferably, the connecting side plate at the lower side of the platform is sleeved outside the anti-skid slide rail, and the pulley at the inner side of the connecting side plate is supported on the upper surface of the assembling base.

Preferably, the right side of the upper surface of the measuring plate is provided with scale marks in centimeters, the scale marks correspond to the pointer, the left side inside the measuring plate is provided with a T-shaped sliding groove, and the sliding groove is connected with the moving plate through a bolt and a nut.

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

1. according to the invention, the connecting arm and the wrapping barrel are arranged, so that the length can be adjusted.

2. In the invention, the installation cavity and the through hole are arranged to be matched with the U-shaped placing seat for installation and auxiliary movement.

3. According to the invention, the manual disc, the translation screw rod and the sealing plug are arranged and manually matched with the U-shaped placing seat to perform left-right translation.

4. In the invention, the arrangement of the assembling plate and the rotating shaft drives the connecting arm to support and assist in rotating for use.

5. In the invention, the first gear and the second gear are arranged and matched with the rotating shaft for transmission and rotation.

6. In the invention, the second gear is driven to rotate by the arrangement of the second speed reducer and the second motor.

7. In the invention, the arrangement of the fastening electric cylinder and the long plate realizes the driving of the connecting column to move back and forth for use.

8. According to the invention, the connecting column, the jacking disc and the clamping groove are arranged to fasten and fix the second gear, so that the connecting column, the jacking disc and the clamping groove are stably matched with the connecting arm for use.

9. According to the invention, the platform, the pulley, the protective slide rail and the connecting side plate are arranged to stably cooperate with the platform to translate, so that different positions of the body of a patient are controlled to face the X-ray receiving plate and the X-ray emitter to detect.

10. In the invention, the arrangement of the measuring plate, the moving plate and the pointer is accurately matched with the platform to adjust the position of the platform for use.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Figure 2 is a schematic diagram of the structure of the adjustable support arm structure of the present invention.

Fig. 3 is a schematic structural side view of the rotating bed structure of the present invention.

Fig. 4 is a schematic structural diagram of a positioning limiting seat structure of the present invention.

Fig. 5 is a schematic structural diagram of a standing mobile station structure of the present invention.

Fig. 6 is a schematic electrical wiring diagram of the present invention.

In the figure:

1. assembling a base; 2. erecting the box; 3. a first decelerator; 4. a first motor; 5. a lifting seat; 6. rotating the plate frame structure; 61. assembling a plate; 62. a rotating shaft; 63. a first gear; 64. a second decelerator; 65. a second motor; 66. a positioning limit seat structure; 661. fastening an electric cylinder; 662. a long plate; 663. connecting columns; 664. tightly pushing the disc; 665. a second gear; 666. a card slot; 7. adjusting the support arm structure; 71. a connecting arm; 72. a wrapping drum; 73. a mounting cavity; 74. a manual tray; 75. inserting holes; 76. translating the screw rod; 77. a sealing plug; 8. an X-ray receiving plate; 9. a U-shaped placing seat; 10. a radiation emitter; 11. a clamping plate; 12. operating the bolt; 13. a controller; 14. a control switch; 15. a standing mobile station structure; 151. a station; 152. a pulley; 153. a protective slide rail; 154. connecting the side plates; 155. measuring a plate; 156. moving the plate; 157. a pointer; 16. and (5) erecting a screw rod.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in fig. 1, a multifunctional X-ray scanning device for imaging department comprises an assembly base 1, a vertical box 2, a first speed reducer 3, a first motor 4, a lifting seat 5, a rotating plate frame structure 6, an adjusting support arm structure 7, an X-ray receiving plate 8, a U-shaped placing seat 9, a ray emitter 10, a clamping plate 11, an operating bolt 12, a controller 13, a control switch 14, a standing mobile platform structure 15 and a vertical screw rod 16, wherein the vertical box 2 is installed on a left bolt on the upper surface of the assembly base 1, and the first speed reducer 3 is installed on an upper bolt of the vertical box 2; the upper end of the first speed reducer 3 is provided with a first motor 4 through a bolt, the lower end of the first speed reducer 3 is connected with a vertical screw 16 through a key, and the lower end of the vertical screw 16 is arranged on the lower side of the interior of the vertical box 2 through a bearing; the lifting seat 5 is inserted into the vertical box 2, and a vertical screw 16 is connected with the lifting seat 5 through an internal thread; the rotating plate frame structure 6 is arranged on the front surface of the lifting seat 5; the adjusting support arm structure 7 is arranged at the front end of the rotating plate frame structure 6; the X-ray receiving plate 8 and the U-shaped placing seat 9 are fixed on the left side and the right side of the front surface of the adjusting support arm structure 7; the ray emitter 10 is arranged on the inner side of the U-shaped placing seat 9; an operating bolt 12 is movably embedded at the upper end of the clamping plate 11, and the operating bolt 12 is in threaded connection with the upper side inside the U-shaped placing seat 9; the controller 13 is mounted on the lower part of the left surface of the vertical box 2 through a bolt, and a control switch 14 is embedded at the left end of the controller 13; the standing mobile station structure 15 is installed on the right side of the upper surface of the assembly base 1.

As shown in fig. 2, in the above embodiment, specifically, the adjusting support arm structure 7 includes a connecting arm 71, a wrapping cylinder 72, a mounting cavity 73, a manual disc 74, a through hole 75, a translation screw 76 and a sealing plug 77, and the connecting arm 71 is inserted into the left and right sides inside the wrapping cylinder 72 and fixed by bolts; connecting arms 71 at different positions in the movable wrapping cylinder 72 reach proper positions according to requirements, and then bolts at the connecting positions are screwed down for fixing; the mounting cavity 73 is formed in the left side of the inner part of the connecting arm 71, and a sealing plug 77 is installed in the mounting cavity 73 in a bolt manner; a translation screw 76 is mounted at the right end of the manual disc 74 through a bolt; the through holes 75 are formed in the front end and the rear end of the inside of the connecting arm 71; the translation screw 76 is movably embedded in the middle part of the interior of the sealing plug 77; the manual disc 74 is rotated to rotate the translation screw 76 and drive the ray emitter 10 to move left and right to a proper position by matching with the U-shaped placing seat 9 in the installation cavity 73 and the translation screw 76.

As shown in fig. 3, in the above embodiment, specifically, the rotating plate frame structure 6 includes an assembling plate 61, a rotating shaft 62, a first gear 63, a second reducer 64, a second motor 65 and a positioning limiting seat structure 66, and the rear end of the assembling plate 61 is bolted to the front surface of the lifting seat 5; the rotating shaft 62 is arranged in the middle part of the inside of the assembling plate 61 through a bearing, and the connecting arm 71 is arranged at the front end of the rotating shaft 62 through a bolt; the first gear 63 is embedded on the outer wall of the rotating shaft 62; the second speed reducer 64 is mounted on the lower portion of the rear surface of the assembly plate 61 through a bolt, and a second motor 65 is mounted on the lower portion of the right end of the second speed reducer 64 through a bolt; the second motor 65 is driven to cooperate with the second speed reducer 64 to drive the second gear 665 to rotate; the positioning limiting seat structure 66 is arranged on the right side of the front surface of the assembling plate 61; the second gear 665 drives the first gear 63, the rotating shaft 62 and the connecting arm 71 to adjust the angle.

As shown in fig. 4, in the above embodiment, specifically, the positioning limiting seat structure 66 includes a fastening electric cylinder 661, an elongated plate 662, a connecting column 663, a tightening disk 664, a second gear 665 and a clamping groove 666, the fastening electric cylinder 661 is bolted to the upper right portion of the rear surface of the assembling plate 61, and an output shaft of the fastening electric cylinder 661 passes through the assembling plate 61 and is bolted to the elongated plate 662; the fastening electric cylinder 661 is driven to drive the connecting column 663 and the tightening disc 664 at the lower part of the long plate 662 to tighten the clamping groove 666 at the inner side of the second gear 665 for fixing; the connecting column 663 is arranged at the lower part of the rear end of the long plate 662 through bolts, and the rear end of the connecting column 663 is glued with a jacking disc 664; the second gear 665 is connected to the front end of the second reducer 64, and the second gear 665 is arranged on the front surface of the assembling plate 61; the clamping groove 666 is formed in the outer side of the front inside the second gear 665.

As shown in fig. 5, in the above embodiment, specifically, the standing mobile station structure 15 includes a platform 151, a pulley 152, a protective sliding rail 153, a connecting side plate 154, a measuring plate 155, a moving plate 156 and a pointer 157, the connecting side plate 154 is mounted on the left and right sides of the lower surface of the platform 151 by bolts, and the pulley 152 is coupled to the connecting side plate 154; the patient stands on the platform 151, and then moves the platform 151 back and forth through the pulley 152 according to the requirement; the protection slide rails 153 are all installed on the right side and the middle right side of the upper surface of the assembly base 1 through bolts, and pulleys 152 are inserted into the left side and the right side of the protection slide rails 153; the measuring plate 155 is mounted on the upper surface of the assembly base 1 through bolts, and the measuring plate 155 is arranged on the right side of the protective slide rail 153; bolts and nuts at the joint of the moving plate 156 and the measuring plate 155 are screwed and fixed; the moving plate 156 is mounted at the lower part of the right end of the platform 151 through bolts, and a pointer 157 is welded at the lower part of the right end of the moving plate 156; the pointer 157 is translated on the measurement plate 155 at a position that controls the movement of the stage 151.

In the above embodiment, specifically, the first motor 4 is a motor with a model number of 5IK90 GU-CF.

In the above embodiment, specifically, the controller 13 uses a PLC of model FX 2N-48.

In the above embodiment, specifically, the second motor 65 is a motor with a model number of 5IK90 GU-CF.

In the above embodiment, specifically, the fastening electric cylinder 661 is an electric cylinder of PA60-50 type.

In the above embodiment, specifically, the control switch 14 is electrically connected to the controller 13, the first motor 4 is electrically connected to the controller 13, the second motor 65 is electrically connected to the controller 13, and the fastening electric cylinder 661 is electrically connected to the controller 13.

Principle of operation

The working principle of the invention is as follows: before use, the connecting arms 71 at different positions in the movable wrapping cylinder 72 reach proper positions according to requirements, then bolts at the joints are screwed up to be fixed, then the manual disc 74 is rotated to enable the translation screw 76 to rotate and to be matched with the installation cavity 73 and the U-shaped placing seat 9 in the translation screw 76 to drive the ray emitter 10 to move left and right to reach proper positions, after preparation before use is completed, a patient stands on the platform 151 during use, then the platform 151 moves back and forth according to requirements through the pulley 152, meanwhile, the pointer 157 translates on the measuring plate 155, finally, bolts and nuts at the joints of the moving plate 156 and the measuring plate 155 are screwed up to be fixed, after primary adjustment, the first motor 4 is driven to be matched with the first reducer 3 to enable the vertical screw 16 to rotate so as to drive the lifting seat 5 and the connecting arms 71 in front to carry out lifting adjustment, after adjustment, scanning work can be carried out through the ray emitter 10 matched with the X-ray receiving plate 8, drive second motor 65 cooperation second reduction gear 64 and drive second gear 665 and rotate at the in-process of scanning, and second gear 665 drives first gear 63 simultaneously, axis of rotation 62 and linking arm 71 carry out the regulation of angle and use, and drive fastening electric cylinder 661 drives spliced pole 663 and the tight dish 664 top of the tight inboard draw-in groove 666 of second gear 665 of long plate 662 lower part and fixes after accomplishing the regulation of angle, can use at the in-process auxiliary regulation of scanning like this.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.