CN203016973U - Medical imaging device and laser positioning lamp correction adjusting device thereof - Google Patents

Abstract

The utility model discloses a laser positioning lamp correction adjusting device which is assembled on a machine frame of a medical imaging device and used for correcting and adjusting a laser positioning lamp. The laser positioning lamp correction adjusting device comprises a base, a laser sleeve seat, a laser sleeve and a laser positioning lamp. The base is assembled on the machine frame of the medical imaging device, the laser sleeve seat is assembled on the base, the laser sleeve is assembled on the laser sleeve seat and can rotate relative to the laser sleeve seat, the laser positioning lamp is fixed on the laser sleeve, and the base is movably connected with the laser sleeve seat. The utility model further discloses the medical imaging device which comprises a machine frame of a round detection cavity and the laser positioning lamp correction adjusting device. The machine of the round diction cavity is provided for a detected object to enter and exit, and the laser positioning lamp correction adjusting device is assembled on the machine frame and positioned in the detection cavity. The laser positioning lamp correction adjusting device is simple in structure and convenient to operate, and rapidly enables a plane of a laser beam sector and a horizontal equipartition face of the detection cavity of the machine frame to coincide so as to achieve positioning of the laser positioning lamp.

Description

Medical imaging equipment and laser localized light comparing alignment formation thereof

Technical field

This utility model relates to technical field of medical instruments, relates in particular to a kind of medical imaging equipment and laser localized light comparing alignment formation thereof.

Background technology

The medical imaging equipment such as PET, CT all has frame and the rack-mounted laser localized light comparing of the cylindrical test chamber that the detected body of a confession passes.All can calibrate laser localized light comparing in the medical imaging equipment assembling process, regulate, overlap so that face is divided equally with the level of test chamber in the plane at the laser beam covering of the fan place that laser localized light comparing excites, and then guarantee the scanning accuracy of medical imaging equipment.Existing medical imaging equipment is to adjust the angle of laser localized light comparing by artificial directly hand rotation laser localized light comparing, and divide equally face by the plane at the artificial laser beam covering of the fan place of adjusting manually directly that the position of laser localized light comparing on the frame of medical imaging equipment make that laser localized light comparing excites with the level of the test chamber of frame and overlap, reach calibration and adjusting to laser localized light comparing.Although can realize calibration and adjusting to laser localized light comparing by directly regulating manually laser localized light comparing, operating process is more loaded down with trivial details, complicated, and is more consuming time, and calibration accuracy is not high yet.

In order to overcome the problems referred to above, necessary a kind of medical imaging equipment and the laser localized light comparing alignment formation thereof of providing.

The utility model content

Technical problem to be solved in the utility model is to provide a kind of medical imaging equipment and laser localized light comparing alignment formation thereof, simple in structure, easy to operate, the plane at the laser beam covering of the fan place that can make fast that laser localized light comparing excites is divided equally face with the level of test chamber and is overlapped, and reaches the purpose of quick location, calibration, adjusting laser localized light comparing.

This utility model is to solve the problems of the technologies described above the technical scheme that adopts to be: a kind of laser localized light comparing alignment formation, be mounted on the frame of medical imaging equipment, be used for the calibration adjustments laser localized light comparing, it comprises that base on the frame that is mounted on medical imaging equipment, group are located at that laser receiver, group on base is located on the laser receiver and laser sleeve that can the laser receiver rotates relatively and be fixed on laser localized light comparing, described base and the flexible connection of described laser receiver on the laser sleeve.

Further, described laser localized light comparing alignment formation also comprises adjusting rod, can coordinate with the laser sleeve laser sleeve is rotated relative to the laser receiver.

Further, described laser sleeve is provided with a plurality of adjustment holes that coordinate with adjusting rod.

Further, described adjustment hole is located on a laser sleeve end relative with the fixed laser positioning lamp, and is circumferencial direction and is evenly distributed on the laser sleeve.

Further, described laser localized light comparing alignment formation also comprises be used to the holding screw that prevents that described laser sleeve from rotating relative to described laser receiver.

Further, described laser receiver is provided with the installing hole that coordinates with holding screw.

Further, described base is provided with a groove of accommodating laser receiver corresponding site, and described laser receiver can slide along the groove of base.

Further, described laser localized light comparing alignment formation also comprises a plurality of the first screws, and described base is provided with the screwed hole with the first screw fit, and described laser receiver is fixed on base by the first screw.

Further, described screwed hole is to run through to be located on base, and is positioned at bottom portion of groove.

Further, described the first screw comprises head and the threaded portion that is connected with head, described laser receiver has the fluting that passes for the threaded portion of the first screw, the groove width width of described fluting is greater than place, the threaded portion diameter of a circle of the first screw, and less than the head place diameter of a circle of the first screw.

Further, described laser receiver also has the wall section that is formed at around fluting, and the head of described the first screw is undertaken in when the first screw is fixed to the laser receiver on base in described wall section.

Further, described laser receiver comprises the main part in the groove that is contained in base and the protuberance that is upwards protruded out setting by main part, and described fluting is located on described main part, and described laser sleeve group is located on described protuberance.

Further, described protuberance has to be and laterally runs through the fixing hole that arranges and be used for accommodating described laser localized light comparing, and described installing hole is communicated with setting with described fixing hole.

Further, described fluting is " U " shape and arranges, and described main part is the tabular setting.

Further, described laser receiver is "T"-shaped setting, and the main part of described laser receiver is " H " shape and arranges.

Further, described laser localized light comparing alignment formation also comprises a plurality of the second screws, and described base is fixed on the frame of medical imaging equipment by the second screw.

Further, described base is provided with first perforation and the second perforation of passing for the second screw, and described first bores a hole lays respectively at the opposite end of described groove longitudinally with the second perforation.

Further, described the first rounded setting of perforation, described the second perforation is the circular arc slotted hole, and is the vertical configuration setting with groove.

Further, described the first perforation place diameter of a circle is greater than the head place diameter of a circle of described the second screw, described biperforate groove width is greater than place, the threaded portion diameter of a circle of described the second screw, and less than the head place diameter of a circle of described the second screw.

Further, described base is take the second screw of passing the first perforation as fulcrum, and by pass biperforate the second screw with pass the first second screw of boring a hole between the two centered by the straight line of line place the relative frame of line swing.

Further, the wall section of described laser receiver can be connected on the head of described biperforate the second screw that passes base.

This utility model also provides a kind of medical imaging equipment for solving the problems of the technologies described above, comprise frame, described frame has the test chamber of the detected body turnover of a confession, described medical imaging equipment also comprises above-mentioned laser localized light comparing alignment formation, and described laser localized light comparing alignment formation is mounted on frame and is positioned at test chamber.

Further, described medical imaging equipment is the X ray computer tomographic apparatus.

Further, described medical imaging equipment is the positron emission tomography scanning device.

Further, described medical imaging equipment is MR imaging apparatus.

Further, described medical imaging equipment is PET-CT equipment.

This utility model contrast prior art has following beneficial effect: the laser localized light comparing alignment formation that adopts this utility model to provide, simple in structure, easy to operate, can make fast plane, laser beam covering of the fan place that laser localized light comparing excites divide equally face with the level of frame test chamber place cylinder and overlap, so realize fast, accurately location, calibration, the purpose of regulating laser localized light comparing.

Description of drawings

Fig. 1 is the structural representation of this utility model medical imaging equipment;

Fig. 2 is the perspective view of the laser localized light comparing alignment formation of this utility model medical imaging equipment, and wherein adjusting rod is not organized and established to the laser localized light comparing alignment formation;

Fig. 3 is the three-dimensional exploded view of laser localized light comparing alignment formation shown in Figure 2;

Fig. 4 is the perspective view of adjusting rod of the laser localized light comparing alignment formation of medical imaging equipment of the present utility model;

Fig. 5 a-5c is that this utility model uses the laser localized light comparing alignment formation to adjust the view of laser localized light comparing.

In figure:

Medical imaging equipment 100 frame 9 test chamber 90

Laser localized light comparing alignment formation 200 base 1 screwed holes 10

Groove 11 first perforation 12 second perforation 13

Laser receiver 2 main part 20 protuberances 21

Fixing hole 22 fluting 23 wall sections 24

Installing hole 25 laser sleeve 3 adjustment holes 31

Laser localized light comparing 4 first screw 5 heads 50,70

Threaded portion 51 holding screw 6 second screws 7

Adjusting rod 8

The specific embodiment

The utility model will be further described below in conjunction with drawings and Examples.

Please refer to the drawing 1 is to shown in Figure 4, and this utility model medical imaging equipment 100 comprises frame 9 and is mounted on laser localized light comparing alignment formation 200 on frame 9.Described frame 9 has the test chamber 90 of detected body (not shown) turnover of a confession.The cylindrical setting of described test chamber 90.200 groups of described laser localized light comparing alignment formations are located on frame 9 and are positioned at test chamber 90.Described medical imaging equipment 100 can be ct apparatus, can be also the positron emission tomography scanning device, can also be MR imaging apparatus, or PET-CT equipment.In the present embodiment take the positron emission tomography scanning device as example.

Please emphasis consult Fig. 2 to shown in Figure 4, described laser localized light comparing alignment formation 200 comprises that base 1, the group on the frame 9 that is mounted on medical imaging equipment 100 is located at that laser receiver 2, group on base 1 is located on laser receiver 2 and can be relative to the laser sleeve 3 that laser receiver 2 rotates, the adjusting rod 8 that is fixed on the laser localized light comparing 4 on laser sleeve 3 and coordinates with laser sleeve 3.Described laser receiver 2 is fixed on base 1 by the first screw 5, and base 1 slides up and down relatively.Described laser localized light comparing alignment formation 200 is by being mounted on the holding screw 6 and the relative motion that limits coordinating of laser sleeve 3 between laser sleeve 3 and laser receiver 2 on laser receiver 2.Described base 1 is fixed on the frame 9 of medical imaging equipment 100 by the second screw 7.Described the first screw 5 comprises head 50 and the threaded portion 51 that is connected with head 50.

Be fixed with laser localized light comparing 4 on described laser sleeve 3.Described laser localized light comparing 4 protrudes out an end of laser sleeve 3.Described laser sleeve 3 and group are established the relative end of laser positioning fixed 4 and are provided with and are the equally distributed a plurality of adjustment holes 31 of circumferencial direction, can coordinate with adjusting rod 8, and laser sleeve 3 is rotated relative to laser receiver 2, and then drive laser localized light comparing 4 rotations, to adjust the angle of laser localized light comparing 4.

Described laser receiver 2 is flexibly connected with base 1, roughly is "T"-shaped setting, and it comprises the main part 20 that roughly is tabular setting and the protuberance 21 that is protruded out setting by main part 20.Described protuberance 21 is provided with the fixing hole 22 of accommodating laser localized light comparing 4.Described fixing hole 22 is horizontal penetration state and is located on protuberance 21.The two ends of described main part 20 also offer " U " shape fluting 23 that is in communication with the outside, and are used for passing for the threaded portion 51 of the first screw 5.Described fluting 23 is to be located on main part 20 along the longitudinally of main part 20.The groove width width of described fluting 23 is less than the diameter of the head 50 of the first screw 5, and greater than the diameter of the threaded portion 51 of the first screw 5.Described main part 20 has the wall section 24 of fluting around 23 of being formed at.Described main part 20 is " H " shape and arranges.The head 50 of described the first screw 5 is undertaken on when the first screw 5 is fixed to laser receiver 2 on base 1 in wall section 24.Also be provided with the installing hole 25 that coordinates with holding screw 6 on described protuberance 21.Described installing hole 25 is communicated with setting with described fixing hole 22, can when turning to suitable angle with laser sleeve 3, pass for holding screw 6 so that the bottom butt of holding screw 6 to laser sleeve 3, is used for limiting laser sleeve 3 rotating between laser receiver 2 by adjusting rod 8.

Described base 1 roughly is tabular setting, which is provided with a groove 11 of accommodating the main part 20 of laser receiver 2.Described laser receiver 2 can slide by relative base 1 along the longitudinally of groove 11.Also be provided with screwed hole 10 on described base 1, can coordinate with the first screw 5, be used for laser receiver 2 is fixed to base 1.Described screwed hole 10 runs through base 1 and arranges, and is positioned at the bottom of groove 11.Also be provided with first perforation 12 and second perforation 13 of passing for the second screw 7 on described base 1.Described the first perforation 12 and second 13 opposite ends of longitudinally of being located at respectively the groove 11 of base 1 of boring a hole.Described the first perforation 12 rounded settings, its place diameter is greater than the head 70 place diameter of a circles of the second screw 7.Described the second perforation 13 is the circular arc slotted hole, and is the vertical configuration setting with described groove 11.Described the second perforation groove width of 13 is less than the head 70 place diameter of a circles of the second screw 7, and greater than place, threaded portion (not shown) diameter of a circle of the second screw 7.When base 1 is fixed on frame 9 by the second screw 7, base 1 can be to pass first perforation the second screw 7 of 12 as fulcrum, passing first perforation the second screw 7 of 12 and to pass second and bore a hole that the relative frame 9 of line swings centered by the second screw 7 place straight lines of 13, in order to adjust the upper-lower position on the plane, laser beam covering of the fan place that laser localized light comparing 4 excites.Described laser receiver 2 can be connected to when base 1 is assembled on frame 9 on the head 70 of the second screw 7 that passes the second perforation 13 near the wall section 24 of the second perforation 13 of bases 1, is used for restriction laser receiver 2 along the slip of groove 11.

During assembling, coordinating of the frame 9 of the first perforation 12 by passing base 1 and second perforation the second screw 7 of 13 and medical imaging equipment 100 at first is for base 1 is assembled to frame 9.At this moment, the head 70 that passes first perforation the second screw 7 of 12 is contained in the first perforation 12, and the head 70 that passes the second screw 7 of the second perforation 13 is undertaken in wall section (not label) around the second perforation 13 of base 1.Then laser localized light comparing 4 is mounted on laser sleeve 3.Then the laser sleeve 3 that group is provided with laser localized light comparing 4 is mounted in the fixing hole 22 of laser receiver 2, and will be fixed on laser receiver 2 with the laser sleeve 3 of laser localized light comparing 4 by the holding screw 6 in the installing hole 25 that is screwed into laser receiver 2.At this moment, the bottom of holding screw 6 is connected on laser sleeve 3, is used for limiting relatively rotating between laser sleeve 3 and laser receiver 2.To be located on base 1 with 2 groups of the laser receivers of laser localized light comparing 4 and laser sleeve 3 with the coordinating of screwed hole 10 of base 1 by the first screw 5 at last.At this moment, the head 50 of the first screw 5 is undertaken in wall section 24 around the fluting 23 of main part 20 of laser receiver 2.The main part 20 of laser receiver 2 is contained in the groove 11 of base 1, and can slide by relative base 1 along the longitudinally of groove 11.Can carry out calibration and the adjusting of laser localized light comparing 4 after assembling.

The calibration of laser localized light comparing 4, adjustment process see also shown in Fig. 5 a to Fig. 5 c.At first unscrewing holding screw 6 makes laser sleeve 3 to rotate relative to laser receiver 2.Then coordinating and rotary laser sleeve 3 of the adjustment hole 31 by adjusting rod 8 and laser sleeve 3 is so that the plane A at the laser beam covering of the fan place that laser localized light comparing 4 excites is horizontal.Then tighten holding screw 6 to limit the position of laser sleeve 3 relative laser receivers 2.Then unscrew the second screw 7, and to pass first perforation the second screw 7 of 12 as fulcrum, to pass first perforation the second screw 7 of 12 and to pass the second relative frame of the line base 1 that swings of boring a hole centered by the second screw 7 place straight lines of 13, make laser beam covering of the fan place plane A that laser localized light comparing 4 excites and the level of the test chamber 90 place cylinders of frame 9 divide equally face B parallel, shown in ginseng Fig. 5 b.Then tighten the second screw 7 that passes first perforation the 12, second perforation 13.Then unscrew the first screw 5, and make laser receiver 2 slide to adjust the position of laser receiver 2 relative bases 1 along the longitudinally of the groove 11 of base 1, the plane A at the laser beam covering of the fan place that makes that laser localized light comparing 4 excites divides equally face B with the level of the test chamber 90 place cylinders of frame 9 and overlaps, shown in ginseng Fig. 5 c.Tighten at last the first screw 5 with fixed laser receiver 2 to base 1.At this moment, namely completed fixing, calibrate and regulating of laser localized light comparing 4.

Adopt the laser localized light comparing alignment formation 200 of medical imaging equipment 100 of the present utility model simple in structure, operating aspect, and can make fast laser beam covering of the fan place plane A that laser localized light comparing 4 excites divide equally face B with the level of frame test chamber 90 place cylinders and overlap, reach quickly and accurately the purpose of calibrating, regulating laser localized light comparing 4.

Although this utility model discloses as above with preferred embodiment; so it is not to limit this utility model; any those skilled in the art; within not breaking away from spirit and scope of the present utility model; when doing a little modification and perfect, therefore protection domain of the present utility model is worked as with being as the criterion that claims were defined.

Claims (26)

1. a laser localized light comparing alignment formation (200), be mounted on the frame (9) of medical imaging equipment (100), be used for the calibration adjustments laser localized light comparing, it is characterized in that, comprise the base (1) on the frame (9) that is mounted on medical imaging equipment, group is located at the laser receiver (2) on base (1), group is located at the upper and laser sleeve (3) that can rotate relative to laser receiver (2) of laser receiver (2) and is fixed on laser localized light comparing (4) on laser sleeve (3), described base (1) is flexibly connected with described laser receiver (2).

2. laser localized light comparing alignment formation as claimed in claim 1 (200), it is characterized in that, described laser localized light comparing alignment formation also comprises adjusting rod (8), can coordinate with laser sleeve (3) laser sleeve (3) is rotated relative to laser receiver (2).

3. laser localized light comparing alignment formation as claimed in claim 2 (200), is characterized in that, described laser sleeve (3) is provided with a plurality of adjustment holes (31) that coordinate with adjusting rod (8).

4. laser localized light comparing alignment formation as claimed in claim 3 (200), it is characterized in that, described adjustment hole (31) is located on laser sleeve (a 3) end relative with fixed laser positioning lamp (4), and is circumferencial direction and is evenly distributed on laser sleeve (3).

5. laser localized light comparing alignment formation as described in any one in claim 2 to 4 (200), it is characterized in that, described laser localized light comparing alignment formation also comprises be used to the holding screw (6) that prevents that described laser sleeve (3) from rotating relative to described laser receiver (2).

6. laser localized light comparing alignment formation as claimed in claim 5 (200), is characterized in that, described laser receiver (2) is provided with the installing hole (25) that coordinates with holding screw (6).

7. laser localized light comparing alignment formation as claimed in claim 6 (200), it is characterized in that, described base (1) is provided with a groove (11) of accommodating laser receiver (2) corresponding site, and described laser receiver (2) can slide along the groove (11) of base (1).

8. laser localized light comparing alignment formation as claimed in claim 7 (200), it is characterized in that, described laser localized light comparing alignment formation also comprises a plurality of the first screws (5), described base (1) is provided with the screwed hole (10) that coordinates with the first screw (5), and described laser receiver (2) is fixed on base (1) by the first screw (5).

9. laser localized light comparing alignment formation as claimed in claim 8 (200), is characterized in that, described screwed hole (10) runs through to be located on base (1), and be positioned at bottom groove (11).

10. laser localized light comparing alignment formation as claimed in claim 8 (200), it is characterized in that, described the first screw (5) comprises head (50) and the threaded portion (51) that is connected with head (50), described laser receiver (2) has the fluting (23) that passes for the threaded portion (51) of the first screw (5), the groove width width of described fluting (23) is greater than place, threaded portion (51) diameter of a circle of the first screw (5), and less than head (50) the place diameter of a circle of the first screw (5).

11. laser localized light comparing alignment formation as claimed in claim 10 (200), it is characterized in that, described laser receiver (2) also has fluting (23) the wall section (24) on every side of being formed at, and the head (50) of described the first screw (5) is fixed to base (1) at the first screw (5) with laser receiver (2) and was undertaken in described wall section (24) when upper.

12. laser localized light comparing alignment formation as claimed in claim 11 (200), it is characterized in that, described laser receiver (2) comprises the main part (20) in the groove (11) that is contained in base (1) and the protuberance (21) that is upwards protruded out setting by main part (20), described fluting (23) is located on described main part (20), and described laser sleeve (3) group is located on described protuberance (21).

13. laser localized light comparing alignment formation as claimed in claim 12 (200), it is characterized in that, described protuberance (21) has to be and laterally runs through the fixing hole (22) that arranges and be used for accommodating described laser localized light comparing (4), and described installing hole (25) is communicated with setting with described fixing hole (22).

14. laser localized light comparing alignment formation as claimed in claim 12 (200) is characterized in that, described fluting (23) is " U " shape and arranges, and described main part (20) is the tabular setting.

15. laser localized light comparing alignment formation as claimed in claim 12 (200) is characterized in that, described laser receiver (2) is "T"-shaped setting, and the main part (20) of described laser receiver (2) is " H " shape and arranges.

16. laser localized light comparing alignment formation as claimed in claim 11 (200), it is characterized in that, described laser localized light comparing alignment formation also comprises a plurality of the second screws (7), and described base (1) is fixed on the frame of medical imaging equipment by the second screw (7).

17. laser localized light comparing alignment formation as claimed in claim 16 (200), it is characterized in that, described base (1) is provided with the first perforation (12) and the second perforation (13) that supplies the second screw (7) to pass, and described the first perforation (12) and the second perforation (13) lay respectively at the opposite end of described groove (11) longitudinally.

18. laser localized light comparing alignment formation as claimed in claim 17 (200) is characterized in that, described first perforation (12) rounded setting, and described the second perforation (13) is the circular arc slotted hole, and is the vertical configuration setting with groove (11).

19. laser localized light comparing alignment formation as claimed in claim 18 (200), it is characterized in that, described the first perforation (12) place diameter of a circle is greater than head (70) the place diameter of a circle of described the second screw (7), the groove width of described the second perforation (13) is greater than place, the threaded portion diameter of a circle of described the second screw (7), and less than head (70) the place diameter of a circle of described the second screw (7).

20. laser localized light comparing alignment formation as claimed in claim 18 (200), it is characterized in that, described base (1) is take the second screw (7) of passing the first perforation (12) as fulcrum, and by the second screw (7) of passing the second perforation (13) and pass first bore a hole (12) the second screw (7) between the two centered by the straight line of line place the relative frame of line swing.

21. laser localized light comparing alignment formation as claimed in claim 18 (200), it is characterized in that, the wall section (24) of described laser receiver (2) can be connected on the head (70) of the second screw (7) of described the second perforation (13) of passing base (1).

A 22. medical imaging equipment (100), it comprises frame (9), described frame (9) has the test chamber (90) of the detected body turnover of a confession, it is characterized in that, described medical imaging equipment (100) also comprises laser localized light comparing alignment formation as described in any one in claim 1 to 21 (200), and described laser localized light comparing alignment formation (200) is mounted on frame (9) and goes up and be positioned at test chamber.

23. medical imaging equipment as claimed in claim 22 (100) is characterized in that, described medical imaging equipment (100) is the X ray computer tomographic apparatus.

24. medical imaging equipment as claimed in claim 22 (100) is characterized in that, described medical imaging equipment (100) is the positron emission tomography scanning device.

25. medical imaging equipment as claimed in claim 22 (100) is characterized in that, described medical imaging equipment (100) is MR imaging apparatus.

26. medical imaging equipment as claimed in claim 22 (100) is characterized in that, described medical imaging equipment (100) is PET-CT equipment.

Images