CN115252197A

CN115252197A - In-vitro embedded implant X-ray photography device and photography system

Info

Publication number: CN115252197A
Application number: CN202210878617.8A
Authority: CN
Inventors: 孙媛元; 吴轶群; 李洁; 王凤; 蓝耕良; 陶宝鑫
Original assignee: Ninth Peoples Hospital Shanghai Jiaotong University School of Medicine
Current assignee: Ninth Peoples Hospital Shanghai Jiaotong University School of Medicine
Priority date: 2022-07-25
Filing date: 2022-07-25
Publication date: 2022-11-01

Abstract

The invention discloses an in vitro embedded implant X-ray photography device and a photography system, wherein the photography device comprises: the camera shooting bracket is used for placing a film; embedding body adjusting part, embedding body adjusting part is established on the support of making a video recording and is located one side of film along the horizontal direction is movably, embedding body adjusting part includes first support, the second support with be used for fixed embedding body's embedding body mount, first support is movably established on the support of making a video recording, the first end of second support is connected in order to realize universal rotation with the embedding body mount through universal rotating assembly, the second end and the first support swing joint of second support, so that the embedding body mount of being connected with first end is portable in the vertical direction. The photographic arrangement can confirm the embedding direction of embedding body implant in accurate quick to reduce the time of planting body section experiment, improve the accuracy and the convenience of experimental result.

Description

In-vitro embedded implant X-ray photography device and photography system

Technical Field

The invention relates to the technical field of medical instruments, in particular to an in-vitro embedded implant X-ray photographing device and an in-vitro embedded implant X-ray photographing system.

Background

In the field of oral implantation, animal experiments are often performed to verify that an implant is combined with bone, then the implant is cut in the area and then embedded in vitro, the tube used in the laboratory is a cylindrical tube, and hard tissue slicing is performed after resin embedding.

However, after the implant and the bone are embedded into the tube by the embedding technology, because of the opaque effect of the embedding material and the bone, the position of the implant cannot be judged, and when the slicing process is performed, the implant is expected to be sliced vertically or horizontally to the long axis direction of the implant, so that the combination condition between the implant and the bone can be judged more accurately.

Disclosure of Invention

The invention aims to provide an in-vitro embedded implant X-ray photographic device which can accurately and quickly confirm the embedding direction of an embedded implant so as to reduce the time of an implant slicing experiment and improve the accuracy and convenience of an experiment result.

The in-vitro embedded implant X-ray photography device according to the embodiment of the invention comprises: the camera shooting bracket is used for placing a film; embedding body adjusting part, embedding body adjusting part is movably established along the horizontal direction on the support of making a video recording and be located one side of film, embedding body adjusting part includes first support, second support and is used for the embedding body mount of fixed embedding body, first support is movably established on the photographic support, the first end of second support with the embedding body mount is connected in order to realize universal rotation through universal rotating assembly, the second end of second support with first support swing joint, so that with first end is connected the embedding body mount is portable in the vertical direction.

According to some embodiments of the invention, the second end of the second bracket is hinged to the first bracket.

According to some embodiments of the present invention, the universal swivel assembly includes a universal ball and a ball socket having an opening, the universal ball is rotatably disposed in the ball socket, one of the ball socket and the universal ball is disposed on the embedding body fixing frame, and the other of the ball socket and the universal ball is disposed at the first end of the second bracket.

According to some embodiments of the invention, the ball detent is a resilient detent.

According to some embodiments of the invention, the embedding body holder is formed as a self-tapping conical screw.

According to some embodiments of the invention, the camera support comprises: the main support is provided with a guide sliding rail extending along the horizontal direction, and the first support is connected with the guide sliding rail in a sliding mode and can move along the horizontal direction; and the film fixing frame is used for fixing the film and is detachably arranged on the main bracket.

According to some embodiments of the invention, the main support comprises a horizontal support and a vertical support arranged perpendicular to each other, the film holder is supported between the horizontal support and the vertical support, and the guide rail is provided on the horizontal support.

According to some embodiments of the present invention, the apparatus further comprises a tooth-shaped stopper disposed on the main support and having a plurality of limiting tooth grooves along the horizontal direction, and the bottom of the film holder is movably fitted in different limiting tooth grooves, so that the film is inclined at different angles between the horizontal support and the vertical support.

According to some embodiments of the present invention, the film holder includes a first parallel support and a second parallel support, and a connecting frame movably connected to the first parallel support and the second parallel support, the first parallel support is used for fixing the film, the bottom of the first parallel support is movably fitted in the limiting tooth socket, the second parallel support is parallel to the first parallel support and respectively located at two sides of the embedding body adjusting component along the horizontal direction, and the second parallel support corresponds to the position of the ball tube so that the ball tube and the film are projected in parallel.

According to some embodiments of the present invention, the connecting frame includes at least one set of upper and lower frames parallel to each other and spaced apart from each other in an up-down direction, two ends of the upper frame are movably connected to the first and second parallel frames, respectively, and two ends of the lower frame are movably connected to the first and second parallel frames, respectively.

According to some embodiments of the invention, the connecting frame comprises two sets of the upper and lower brackets, wherein one set of the upper and lower brackets is mounted on one side of the first and second parallel brackets and the other set of the upper and lower brackets is mounted on the opposite side of the first and second parallel brackets.

According to some embodiments of the invention, the second parallel support may be provided with a bulb fixing ring for fixing the bulb.

The invention also provides an in-vitro embedded implant X-ray shooting system.

The in-vitro embedded implant X-ray shooting system according to the embodiment of the invention comprises: the in vitro embedded implant X-ray photography device of the embodiment; the in-vitro embedded implant X-ray photographing device is detachably arranged on the photographing device and comprises a bulb tube, and the embedded body adjusting assembly is positioned between the bulb tube and the film.

Therefore, according to the in-vitro embedded implant X-ray photographing device and the in-vitro embedded implant X-ray photographing system provided by the embodiment of the invention, by arranging the photographing bracket for placing the film and the embedded body adjusting component, the embedded body adjusting bracket can adjust the position of the embedded body in the horizontal direction and the vertical direction, so that the embedded body can be in the photographing range of the X-ray, a better X-ray can be obtained, the universal rotation of the embedded body can be realized to adjust the photographing angle of the embedded body, the position of the embedded body in the embedded body can be clearly seen by photographing the X-ray, the embedding direction of the embedded body in the embedded body can be confirmed by adjusting the position and the photographing angle of the embedded body, namely, the embedded body can be adjusted to the position capable of clearly judging the embedding direction by adjusting the angle of the embedded body in the X-ray photographing process, then the embedding direction of the embedded body is marked, so that the embedding direction of the embedded body can be confirmed quickly when the embedded body is subjected to a slicing test, the time can be reduced, and the accuracy and the convenience of the test result can be improved.

Drawings

FIG. 1 is a schematic view of an arrangement of an in vitro embedded implant radiography apparatus according to an embodiment of the present invention with a film sheet at an angle;

FIG. 2 is a schematic view of a photographic film of an apparatus for radiography of an in vitro embedded implant according to an embodiment of the present invention at another angle;

FIG. 3 is a schematic view showing the structure of an in-vitro embedded implant radiography apparatus according to an embodiment of the present invention with the film at an angle;

FIG. 4 is a schematic view showing the structure of an embedded body radiograph with a film at another angle of an in vitro embedded implant radiography apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of an embedding body fixing frame and a universal ball of an in-vitro embedding implant X-ray photography device according to an embodiment of the invention;

FIG. 6 is a schematic structural view of an embedding body.

Reference numerals are as follows:

100: an in vitro embedded implant X-ray photography device;

1: camera support, 11: a main support, 111: horizontal bracket, 112: vertical support, 12: guide slide rail, 13: tooth stopper, 131: limiting tooth groove, 14: film holder, 15: first horizontal bracket, 16: second horizontal bracket, 17: link frame, 171: upper bracket, 172: a lower bracket;

2: embedding body adjusting component, 21: first bracket, 22: second bracket, 23: embedding body mount, 24: universal swivel assembly, 241: universal ball, 242: a spherical clamping groove;

200: an embedding body;

300: an implant;

400: a bulb tube;

500: film.

Detailed Description

The X-ray photographing apparatus 100 for an in-vitro embedded implant and the X-ray photographing system for an in-vitro embedded implant according to the present invention will be described in detail with reference to the accompanying drawings and the detailed description.

The prior art is in the oral implantation field, especially dental test field, when carrying out the animal experiment to the condition that implant and bone are united, carry out external embedding after cutting bone 300 with implant region and embedding material together usually and form embedding body 200, because embedding material and implant 300 are nontransmissive photography, can't accurately judge the position of embedding direction and implant 300 when handling embedding body 200, need experimental doctor to cut into slices according to experience and sensation, the embedding direction is judged while cutting edge, make the embedding direction of finding the implant that can't be accurate quick, for example, can't accurately slice in the major axis direction of perpendicular or being on a parallel with the implant, lead to the test time overlength, perhaps influence the experimental result even.

In order to find the embedding direction of the implant 300 and perform slicing, the inventor finds that an X-ray can be obtained by photographing the embedding body 200 by using a photographing device, the X-ray can display the position of the implant 300, the embedding direction of the implant 300 can be found according to the obtained X-ray, but because the position of the implant 300 in the embedding body 200 cannot be directly observed and predicted, the position of the implant 300 can be beyond the photographing range and the position of the implant 300 cannot be judged during photographing, or the angle and the position of the implant 300 displayed in the X-ray film 500 are more deviated, so that a testing doctor cannot judge the embedding direction of the implant 300 according to the X-ray, and therefore the inventor provides an in-vitro embedded implant X-ray photographing device 100, the position of the embedding body 200 can be adjusted by the in-vitro embedded implant X-ray photographing device 100, the display of the implant on the X-ray is clearer, and the testing doctor can judge the position and the direction of the implant according to the X-ray and perform marking, thereby quickly and effectively finding the embedding direction of the implant 300, reducing the testing efficiency and improving the testing efficiency.

An in vitro embedded implant X-ray photographing apparatus 100 according to an embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to fig. 1 to 4, an in vitro embedded implant radiography apparatus 100 according to an embodiment of the present invention comprises a camera support 1 and an embedded body adjusting assembly 2. The camera support is used for placing the film 500, and the embedding body adjusting assembly 2 is used for carrying and adjusting the position of the embedding body 200 so as to enable the implant 300 to be presented on the X-ray film, and to enable the image presented by the implant on the X-ray film to be found and confirmed more easily, wherein the embedding direction is the direction for slicing the implant 300 in the embedding body 200, such as the axial direction of the implant 300 or the direction parallel to the axial direction of the implant 300 and the direction perpendicular to the axial direction of the implant 300.

Referring to fig. 1 to 4, the embedding body adjusting assembly 2 is movably provided on the photographing bracket 1 in a horizontal direction at one side of the film 500, so that the embedding body 200 having the implant is fixed to the embedding body adjusting assembly 2, and the embedding body adjusting assembly 2 is movable in the horizontal direction on the photographing bracket 1, so that the embedding body 200 is movable in the horizontal direction with respect to the position of the film 500, thereby adjusting the distance between the embedding body 200 and the film 500 in the horizontal direction.

The embedding body adjusting assembly 2 can comprise a first support 21, a second support 22 and an embedding body fixing frame 23 for fixing the embedding body 200, the first support 21 is movably arranged on the camera shooting support 1, the first end of the second support 22 is connected with the embedding body fixing frame 23 through a universal rotating assembly 24 to realize universal rotation, namely, the embedding body fixing frame 23 is arranged at the first end of the second support 22, and the second end of the second support 22 is movably connected with the first support 21, so that the embedding body fixing frame 23 connected with the first end can move in the vertical direction. While the first carriage 21 is movable in the horizontal direction on the camera carriage to effect a movement of the embedding body adjusting assembly 2 in the horizontal direction.

And embedding body mount 23 and second support 22 are connected through universal rotating assembly 24, thus the embedding body mount can realize universal rotation, make embedding body mount 23 can remove and can realize universal rotation relatively second support 22 along horizontal direction and vertical direction, thereby can be in the horizontal direction, adjust the position of embedding body 200 in the vertical direction, and embedding body 200 can realize universal rotation, and then when making a video recording to embedding body 200, can adjust the position of embedding body 200 from a plurality of directions in order to avoid embedding body 200 to surpass the X piece shooting scope, and can see planting body 300 in embedding body 200 through X piece shooting, through adjusting the position of embedding body 200, also can adjust the position of planting body 300, make the direction that can clearly see planting body 300 at the X piece, with can confirm the embedding direction of planting body 300, then can mark on embedding body 200 according to the embedding direction of acquireing, slice according to the direction of mark, not only can accurately confirm the direction of embedding body 200, also need not confirm the embedding body processing time of slicing repeatedly, and avoid destroying the embedding body and make the experiment effect also more accurate.

Therefore, according to the in vitro embedded implant X-ray photography device 100 provided by the embodiment of the invention, by arranging the camera bracket 1 and the embedded body adjusting component 2 for placing the film 500, the embedded body 200 adjusting bracket can adjust the position of the embedded body 200 in the horizontal direction and the vertical direction, so that the embedded body 200 can be in the X-ray shooting range to obtain better X-rays, and can realize universal rotation of the embedded body 200 to adjust the shooting angle of the embedded body 200, because the position of the embedded body 300 in the embedded body 200 can be clearly seen when the X-ray is shot, the embedding direction of the embedded body 300 in the embedded body 200 can be confirmed by adjusting the position and the shooting angle of the embedded body 200, namely, the embedded body 200 can be adjusted to the position capable of clearly judging the embedding direction by adjusting the angle of the embedded body 300 in the X-ray shooting, then the embedding direction of the embedded body 200 is marked, so that the embedding direction of the embedded body 200 can be confirmed, thus when the embedded body 300 is subjected to a slicing test, the embedding direction can be accurately and quickly confirmed, further, the test time can be reduced, and the test result accuracy and the convenience of the test can be improved.

In some embodiments of the present invention, the second end of the second bracket 22 is hinged with the first bracket 21, thereby enabling the movable connection of the second end of the second bracket 22 with the first bracket 21, such that the first end of the second bracket 22 can swing around the hinge point of the first bracket 21 and the second bracket 22 to enable the movement in the vertical direction. Or the second end of the second bracket 22 may be connected to the first bracket 21 through a gear structure to realize the vertical movement of the first end of the second bracket 22. In other embodiments of the present invention, the first bracket 21 may be provided with a sliding slot extending along the vertical direction, and the second end of the second bracket 22 is provided with a pulley engaged with the sliding slot, and the pulley slides along the sliding slot to realize the movement of the first end of the second bracket 22 along the vertical direction.

In some embodiments of the present invention, the universal rotating assembly 24 includes a universal ball 241 and a spherical slot 242 having an opening, the universal ball 241 is rotatably disposed in the spherical slot 242, one of the spherical slot 242 and the universal ball 241 is disposed on the embedding body fixing frame 23, and the other of the spherical slot 242 and the universal ball 241 is disposed at the first end of the second support 22, and the universal rotation can be achieved by the cooperation of the universal ball 241 and the spherical slot 242. In some specific examples of the present invention, the spherical clamping groove 242 may be provided on the embedding body fixing frame 23, and the universal ball 241 is provided at the first end of the second support 22; in other examples of the present invention, the spherical engaging slot 242 may be disposed at the first end of the second support 22, and the universal ball 241 is disposed on the embedding body fixing frame 23, so as to realize universal rotation of the embedding body fixing frame 23 relative to the second support 22 through the rotatable connection of the universal ball 241 and the spherical engaging slot 242.

Optionally, the ball-shaped engaging groove 242 is an elastic engaging groove, that is, the ball-shaped engaging groove 242 has elasticity, so that the universal ball 241 can be conveniently engaged into the ball-shaped engaging groove 242, and the ball-shaped engaging groove 242 can be engaged with the universal ball 241.

In some embodiments of the present invention, the embedding body holder 23 can be formed as a self-tapping conical screw, so that the self-tapping conical screw can be screwed into the embedding body 200 to achieve a fixed connection with the embedding body 200, the structure is simple and the fixation with the embedding body 200 can be achieved.

In some embodiments of the present invention, the camera support 1 may include a main support 11 and a film holder 14 for holding a film 500, the main support 11 is provided with a guide rail 12 extending in a horizontal direction, and the first support 21 is slidably connected to the guide rail 12 and is movable in the horizontal direction; film mount 14 detachably establishes on main support 11, through the sliding connection of first support 21 with direction slide rail 12, make embedding body mount 23 movable along the horizontal direction on main support 11, film mount 14 is used for placing film 500 and establishes the one end at main support 11 along the horizontal direction, embedding body mount 23 moves so that embedding body 200 is movable between film 500 and bulb 400 along the horizontal direction, and then adjusts the effect of making a video recording of embedding body 200 when carrying out X piece and making a video recording.

In some examples, the main support 11 may include a horizontal support 111 and a vertical support 112 disposed perpendicular to each other, the film holder 14 is supported between the horizontal support 111 and the vertical support 112, the guide rail 12 is disposed on the horizontal support 111, such that the guide rail 12 can be fixed on the horizontal support 111 and extend in a horizontal direction, and the film holder 14 is fixed between the horizontal support 111 and the vertical support 112, so as to not only fixedly support the horizontal support 111 and the vertical support 112, but also position the film holder 14 through the horizontal support 111 and the vertical support 112, such that the structure of the main support 11 and the film holder 14 is more stable and compact.

In some specific examples of the present invention, the horizontal bracket 111 may be formed as a horizontal plate-shaped structure, and the guide rail 12 may be fixed on the surface of the horizontal bracket 111 or embedded in the horizontal bracket 111, or the horizontal bracket 111 may be formed by a plurality of brackets, the guide rail 12 may be fixed on the horizontal bracket 111, and the lower end of the first bracket 21 may be provided with a guide sliding structure that is slidably fitted with the guide rail 12; the vertical bracket 112 may also be formed in a plate shape or other structure formed of a plurality of brackets as long as it can support the fixing frame, and in the example shown in fig. 1, the vertical bracket 112 is vertically provided on the surface of the horizontal bracket 111 at one end of the horizontal bracket 111 in the horizontal direction.

Optionally, the main frame 11 may further include a tooth stopper 13, the tooth stopper 13 is disposed on the main frame 11 and is provided with a plurality of limiting tooth grooves 131 along the horizontal direction, and the bottom of the film holder 14 is movably fitted in different limiting tooth grooves 131, so that the film 500 is inclined at different angles between the horizontal frame 111 and the vertical frame 112, so that the inclination angle of the film 500 with respect to the horizontal direction or the vertical direction can be adjusted by the tooth stopper 13, so as to guide the X-ray photographed film 500 to be parallel to the bulb 400.

In the example shown in fig. 1 to 4, the tooth stopper 13 is provided on the horizontal bracket 111, a plurality of stopper teeth 131 are horizontally spaced, the film holder 14 is supported between the horizontal bracket 111 and the vertical bracket 112, and the horizontal distance between the film 500 positioned thereon and the vertical bracket 112 can be adjusted by adjusting the bottom of the film holder 14 to be positioned in different stopper teeth 131, thereby adjusting the inclination angle of the film 500 with respect to the horizontal bracket 111 and the vertical bracket 112.

Further, the film holder 14 may include a first parallel support 15 and a second parallel support 16, and a connection frame 17 movably connected to the first parallel support 15 and the second parallel support 16, the first parallel support is used for fixing the film 500, the bottom of the first parallel support 15 is movably fitted in the limiting tooth socket 131, the second parallel support 16 is parallel to the first parallel support 15 and respectively located at two sides of the embedding body adjusting assembly 2 along the horizontal direction, and the second parallel support 16 corresponds to the bulb 400 in position so that the bulb 400 is projected parallel to the film 500.

In other words, the first parallel support 15 and the second parallel support 16 are horizontally disposed at both sides of the embedding body adjusting assembly 2, the first parallel support 15 is used for fixing the film 500, the second parallel support 16 is used for corresponding to the ball tube 400, the embedding body 200 is horizontally movable between the first parallel support 15 and the second parallel support 16, the connecting frame 17 is movably connected with the first parallel support 15 and the second parallel support 16 respectively, when the first parallel support 15 is movably matched with the tooth-shaped stopper 13 to be inclined at different angles, the second parallel support 16 is movably connected with the connecting frame 17 to be capable of moving along with the inclination with the first parallel support 15 and always keeping parallel with the first parallel support 15, so that the ball tube 400 can be parallel with the film 500 of the first parallel support 15 when the ball tube 400 is parallel with the second parallel support 16 correspondingly, thereby realizing the parallel projection of the ball tube 400 and the film 500.

In some examples of the present invention, the connecting frame 17 may include at least one set of an upper frame 171 and a lower frame 172 that are parallel to each other and are spaced apart in the up-down direction, two ends of the upper frame 171 are movably connected to the first parallel frame and the second parallel frame 16, respectively, two ends of the lower frame 172 are movably connected to the first parallel frame 15 and the second parallel frame 16, respectively, that is, two ends of the upper frame 171 in the horizontal direction are movably connected to the first parallel frame 15 and the second parallel frame 16, respectively, and two ends of the lower frame 172 in the horizontal direction are movably connected to the first parallel frame 15 and the second parallel frame 16, respectively, wherein the lower frame 172 and the upper frame 171 are spaced apart in the up-down direction and parallel to fix the first parallel frame 15 and the second parallel frame 16, and the first parallel frame 15 and the second parallel frame 16 can be kept parallel at all times when they are moved.

Alternatively, the connecting bracket 17 includes two sets of upper and

lower brackets

171 and 172, wherein one set of upper and

lower brackets

171 and 172 is provided on one side of the first and second parallel brackets 15 and 16, and the other set of upper and

lower brackets

171 and 172 is provided on the opposite side of the first and second parallel brackets 15 and 16. That is, two sets of upper brackets 171 and lower brackets 172 are provided on opposite sides of the first parallel bracket 15 and the second parallel bracket 16, respectively, so that the positioning support effect of the first parallel bracket 15 and the second parallel bracket 16 can be further improved. In the example shown in fig. 1 to 4, two sets of upper brackets 171 and lower brackets 172 are respectively provided on the left and right sides of the first parallel bracket 15, wherein the upper brackets 171 of each set are movably connected to the top of the first parallel bracket 15 and the top of the second parallel bracket 16, respectively, and the lower brackets 172 of each set are movably connected to the bottom of the first parallel bracket 15 and the second parallel bracket 16, respectively.

In some specific examples, the connecting frame 17, the first parallel support 15 and the second parallel support 16 may be formed as a movably deformable rectangular parallelepiped frame, the first parallel support 15 and the second parallel support 16 may be formed as opposite sides of the rectangular parallelepiped frame, the film 500 may be fixed on one side of the rectangular parallelepiped frame, the rectangular parallelepiped frame is movably deformed to incline the first parallel support 15 so that the film 500 may be inclined at different angles to achieve parallel projection with the bulb 400, and the connecting frame 17, the first parallel support 15 and the second parallel support 16 are formed as a frame structure to also facilitate adjustment of the embedding body adjusting assembly 2 located therein.

Further, the second parallel bracket 16 may be provided with a bulb 400 fixing ring for fixing the bulb 400, so that the bulb 400 can be fixed, and the parallelism between the bulb 400 and the film 500 can be improved to improve the effect of parallel projection.

The invention also provides an in-vitro embedded implant X-ray shooting system.

The in-vitro embedded implant X-ray shooting system according to the embodiment of the invention can comprise a shooting device 100 and a shooting device, wherein the shooting device is the in-vitro embedded implant X-ray shooting device 100 of any one of the embodiments; the photographic device, the in vitro embedded implant X-ray photographic device 100 is detachably arranged on the photographic device, the photographic device comprises a bulb tube 400, and an embedded body adjusting component 2 is positioned between the bulb tube 400 and a film 500.

According to the in-vitro embedded implant X-ray shooting system provided by the embodiment of the invention, by arranging the in-vitro embedded implant X-ray shooting device 100 of the embodiment, the position of the embedded body 200 can be adjusted in the horizontal direction and the vertical direction, so that the embedded body 200 can be positioned in the X-ray shooting range to obtain better X-rays, the shooting angle of the embedded body 200 can be adjusted to clearly know the position of the implant, the embedding direction of the implant in the embedded body 200 is confirmed, then the embedding direction of the embedded body 200 is marked, so that the embedding direction of the embedded body 200 can be confirmed, thus when the implant is subjected to a slicing test, the embedding direction can be accurately and quickly confirmed and the implant can be sliced, the test time can be further reduced, and the accuracy and convenience of the test result can be improved

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. An in vitro embedded implant X-ray photography device, comprising:

the camera shooting bracket is used for placing a film;

embedding body adjusting part, embedding body adjusting part is movably established along the horizontal direction on the support of making a video recording and be located one side of film, embedding body adjusting part includes first support, second support and is used for the embedding body mount of fixed embedding body, first support is movably established on the photographic support, the first end of second support with the embedding body mount is connected in order to realize universal rotation through universal rotating assembly, the second end of second support with first support swing joint, so that with first end is connected the embedding body mount is portable in the vertical direction.

2. The apparatus according to claim 1, wherein the second end of the second frame is hinged to the first frame.

3. The in vitro embedded implant X-ray photography device of claim 1, wherein the universal swivel assembly comprises a universal ball and a ball socket with an opening, the universal ball is rotatably disposed in the ball socket, one of the ball socket and the universal ball is disposed on the embedded body fixing frame, and the other of the ball socket and the universal ball is disposed at the first end of the second bracket.

4. The in vitro embedded implant X-ray photography device of claim 3, wherein the spherical clamping groove is an elastic clamping groove.

5. The in vitro embedded implant X-ray photography device of claim 1, wherein the embedded body fixture is formed as a tapered self-tapping screw.

6. The in vitro embedded implant X-ray photography device of claim 1, wherein the camera support comprises:

the main support is provided with a guide sliding rail extending along the horizontal direction, and the first support is connected with the guide sliding rail in a sliding mode and can move along the horizontal direction;

and the film fixing frame is used for fixing the film and detachably arranged on the main bracket.

7. The apparatus according to claim 6, wherein said main frame comprises a horizontal frame and a vertical frame, said horizontal frame and said vertical frame are vertically disposed, said film holder is supported between said horizontal frame and said vertical frame, and said guide rail is disposed on said horizontal frame.

8. The in vitro embedded implant X-ray photography device of claim 7, further comprising a tooth-shaped stopper, wherein the tooth-shaped stopper is disposed on the main support and has a plurality of limiting tooth slots along the horizontal direction, and the bottom of the film holder is movably fitted in different limiting tooth slots, so that the film is inclined at different angles between the horizontal support and the vertical support.

9. The apparatus according to claim 8, wherein the film holder comprises a first parallel support and a second parallel support and a connecting frame movably connected to the first parallel support and the second parallel support, the first parallel support is used for fixing the film, the bottom of the first parallel support is movably fitted in the limiting tooth slot, the second parallel support is parallel to the first parallel support and is respectively located at two sides of the embedding body adjusting assembly along the horizontal direction, and the second parallel support corresponds to the bulb tube in position so that the bulb tube and the film are projected in parallel.

10. The apparatus according to claim 9, wherein the connecting frame comprises at least one set of upper and lower frames parallel to each other and spaced apart from each other in the up-down direction, the upper frame is movably connected at two ends thereof to the first and second parallel frames, respectively, and the lower frame is movably connected at two ends thereof to the first and second parallel frames, respectively.

11. The apparatus according to claim 10, wherein said connecting frame comprises two sets of said upper and lower frames, one set of said upper and lower frames being mounted on one side of said first and second parallel frames and the other set of said upper and lower frames being mounted on the opposite side of said first and second parallel frames.

12. The in vitro embedded implant radiography apparatus according to claim 9, wherein the second parallel support is provided with a bulb fixation ring for fixation of the bulb.

13. The utility model provides an in vitro embedding planting body X piece system of clapping which characterized in that includes:

the in vitro embedded implant X-ray photography device according to any one of claims 1-12;

the in-vitro embedded implant X-ray photographing device is detachably arranged on the photographing device and comprises a bulb tube, and the embedded body adjusting assembly is positioned between the bulb tube and the film.