CN213181365U - High-efficient ray detection equipment of cylinder spare - Google Patents

Abstract

The utility model discloses a high-efficient ray detection equipment of drum spare, its characterized in that: including the lead frame and set up the censorship rolling bed of both ends import and export position about the lead frame, be provided with joint rolling bed, ray emission mechanism and ray receiving mechanism in the lead frame, every be provided with on the censorship rolling bed and slide extremely the work piece bracket on the joint rolling bed, wherein the work piece bracket includes the gyration supporting seat that a plurality of lines were arranged, every the correspondence is provided with two at least auxiliary stand around the gyration supporting seat, it is a plurality of to be provided with the drive on the rolling bed the gyration driving mechanism of gyration supporting seat around self axis gyration, ray emission mechanism ray receiving mechanism is located the both sides of the rolling bed of plugging into make the ray energy of ray emission pipe transmission by the receiving screen is received. The beneficial effects of the utility model include: compared with the prior art, the detection efficiency of the cylindrical part is obviously improved, the waiting time for replacing the cylindrical part is reduced, and the energy is saved.

Description

High-efficient ray detection equipment of cylinder spare

Technical Field

The utility model relates to a ray detection equipment field, concretely relates to high-efficient ray detection equipment of drum spare.

Background

The principle of industrially utilizing X-ray detection is as follows: when X-rays are absorbed by a substance, the molecules that make up the substance are broken down into positive and negative ions, known as ionization, and the number of ions is proportional to the amount of X-rays absorbed by the substance. The ionization effect is generated by air or other substances, and the ionization degree is measured by a meter, so that the quantity of the X-ray can be calculated. The image is converted into digital signals by an imager, and the digital signals are restored into images by computer-aided software to be subjected to image judgment, labeling, storage and the like.

For the ray detection of cylindrical parts in the existing X-ray detection equipment, the single cylindrical part is mostly horizontally conveyed and detected, so that the part changing time is long, the detection efficiency is low, the waiting time of a ray detection device is long, and the energy waste is large.

Disclosure of Invention

To the weak point among the above-mentioned prior art, the utility model provides a high-efficient ray detection equipment of drum spare, it has solved the inefficiency problem among the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a high-efficient ray detection equipment of cylinder spare which characterized in that: comprises a lead room and inspection rolling machines arranged at the inlet and outlet positions at the left and right ends of the lead room, wherein a connection rolling machine, a ray emission mechanism and a ray receiving mechanism are arranged in the lead room, each inspection rolling machine is provided with a workpiece bracket which can slide to the connection rolling machine, wherein the workpiece bracket comprises a plurality of rotary supporting seats which are arranged in a line, at least two auxiliary brackets are correspondingly arranged around each rotary supporting seat, the connection rolling bed is provided with a rotary driving mechanism for driving the plurality of rotary supporting seats to rotate around the axis of the rotary supporting seats, the ray emitting mechanism is positioned at one side of the connection rolling bed, the ray receiving mechanism is positioned at the other side of the connection rolling bed, and the ray transmitting tube of the ray transmitting mechanism and the receiving screen of the ray receiving mechanism are always in a positive alignment relationship, so that rays transmitted by the ray transmitting tube can be received by the receiving screen.

Further, the workpiece bracket further comprises a bottom plate, a plurality of rotary supporting seats are arranged in a row at equal intervals on the bottom plate, the lower portion of each rotary supporting seat is coaxially connected with a rotary gear, any two rotary gears are arranged between the rotary gears, a transmission gear meshed with the rotary gears is arranged on the bottom plate, a driving gear meshed with one transmission gear or one rotary gear is further arranged on the bottom plate, a transmission shaft hole matched with a rotary driving mechanism is formed in the upper portion of the driving gear, a cover plate is arranged above the bottom plate in a buckled mode, and the auxiliary support is arranged on the cover plate.

Furthermore, the top of the rotary support seat is a plane.

Further, the auxiliary stand includes the polished rod of vertical setting, be provided with the spacing claw that the liftable was adjusted the installation on the polished rod, spacing claw includes the connecting seat, be provided with a plurality of claw handles on the connecting seat every the top of gyration supporting seat all has two claw handles that are the splayed and distribute on the auxiliary stand.

Furthermore, the claw handle is connected with the connecting seat in a turnover mode, and the turnover angle of the claw handle is limited to be from the horizontal direction to the vertical direction.

Furthermore, the inspection rolling machine comprises an inspection rolling machine support, a plurality of first conveying roller shafts are arranged on the inspection rolling machine support at intervals along the length direction, two ends of each first conveying roller shaft are arranged on the inspection rolling machine support through bearing seats, first roller structures used for supporting the workpiece brackets are further arranged at two ends of each first conveying roller shaft, each first conveying roller shaft is further provided with a first chain wheel, each inspection rolling machine support is provided with a first driving motor used for driving each first chain wheel on each first conveying roller shaft to move synchronously, an enclosure for shielding the first conveying roller shafts is further arranged on the upper portion of the inspection rolling machine support, the enclosure is open at one side opposite to the lead room, and a first stop block driven by an air cylinder is arranged on the inspection rolling machine support corresponding to one side.

Further, the connection rolling machine comprises a connection rolling machine bracket which is used for being installed at the bottom of the lead room, a plurality of second conveying roller shafts are arranged on the connection rolling bed support at intervals along the length direction, two ends of each second conveying roller shaft are arranged on the connection rolling bed support through bearing seats, a second roller structure for supporting and conveying the workpiece bracket is arranged on the second conveying roller shaft, the second conveying roller shaft is also provided with a second chain wheel, the connecting roller bed bracket is also provided with a second driving motor which drives the second chain wheel on each second conveying roller shaft to synchronously move, the upper part of the connecting rolling machine support is provided with a baffle for shielding two ends of the second conveying roller shaft, the connecting rolling machine support is also provided with two second stop blocks driven by cylinders, and the spacing distance between the two second stop blocks is equal to the length of one workpiece bracket.

Furthermore, the rotary driving mechanism comprises a bottom supporting plate arranged on the support of the connecting rolling machine, a vertical plate is arranged on the bottom supporting plate, a guide rail sliding block mechanism in the vertical direction is arranged on the vertical plate, a dragging plate is arranged on the guide rail sliding block mechanism, a servo motor is arranged on the dragging plate, an output shaft of the servo motor is connected with a rotary driving shaft through a synchronous belt transmission mechanism, the rotary driving shaft drives the rotary supporting seat, a lifting cylinder is arranged on the bottom supporting plate, a cylinder rod of the lifting cylinder is connected with the dragging plate and drives the dragging plate to do lifting motion, so that the rotary driving shaft is combined with the workpiece bracket and drives the rotary supporting seat to rotate.

Further, ray emission mechanism is including setting up the first cross slip table on plumbous room antetheca or back wall, ray emission pipe set up in on the first cross slip table, the stroke of first cross slip table horizontal direction is not less than the length of work piece bracket, the stroke of the vertical direction of first cross slip table is not less than the length of work piece that awaits measuring.

Further, ray receiving mechanism with ray emission mechanism sets up relatively, ray receiving mechanism is including setting up second cross slip table on the lead house antetheca or the back wall, the second cross slip table with the structure of first cross slip table is the same, just the second cross slip table with first cross slip table synchronous drive, still be provided with Z axle motion on the second cross slip table, receive the screen set up in on the Z axle motion, Z axle motion is including the drive receive the screen and be close to or keep away from ray emission tube's servo motor, guide rail slider mechanism, synchronous belt drive.

The beneficial effects of the utility model include: compared with the prior art, the detection efficiency of the cylindrical part is obviously improved, the waiting time for replacing the cylindrical part is reduced, and the energy is saved;

a plurality of workpieces can be simultaneously conveyed into the lead chamber through the workpiece bracket for detection, so that the times of workpiece replacement are reduced;

the inspection rolling machines are arranged at two ends of the lead room at the same time, so that alternate inspection can be realized, and the waiting time is reduced;

the ray transmitting tube and the receiving screen are arranged on the cross sliding table, so that multi-position detection can be met, and the size of the whole equipment can be reduced.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic structural view of the present invention without a lead chamber;

FIG. 3 is a schematic structural view of a workpiece carrier according to the present invention;

FIG. 4 is a schematic structural view of the inspection rolling machine of the present invention;

fig. 5 is a schematic structural view of the connection rolling bed of the present invention;

fig. 6 is a schematic structural diagram of a swing driving mechanism according to the present invention;

FIG. 7 is a schematic structural diagram of a ray emitting mechanism of the present invention;

fig. 8 is a schematic structural diagram of the ray receiving mechanism of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments and accompanying drawings.

As shown in figure 1, the high-efficiency ray detection equipment for the cylindrical parts mainly comprises a lead room 1 and inspection rolling machines 2 arranged at the inlet and outlet positions of the left end and the right end of the lead room 1, ray detection is carried out in the lead room 1, the inspection rolling machines 2 at the two ends are alternately inspected, and the detection efficiency is improved.

As shown in fig. 2, the lead room 1 in this embodiment is provided with a docking roller bed 3, a radiation emitting mechanism 4 and a radiation receiving mechanism 5. Each inspection rolling machine 2 is provided with a workpiece bracket 6 which can slide to the connection rolling machine 3, and a workpiece to be detected is placed on the workpiece bracket 6. The workpiece bracket 6 comprises a plurality of rotary supporting seats 61 which are arranged in a row, and the rotary supporting seats 61 can rotate to drive the workpieces to rotate. At least two auxiliary supports 62 are correspondingly arranged around each rotary supporting seat 61 and used for assisting in supporting the workpiece to be placed and inclined. The connecting roller bed 3 is provided with a rotary driving mechanism 7 for driving the plurality of rotary supporting seats 61 to rotate around the axis of the rotary supporting seats. The ray emitting mechanism 4 is located on one side of the connecting rolling bed 3, the ray receiving mechanism 5 is located on the other side of the connecting rolling bed 3, and the ray emitting tube 41 of the ray emitting mechanism 4 and the receiving screen 51 of the ray receiving mechanism 5 are always in a facing relationship, so that rays emitted by the ray emitting tube 41 can be received by the receiving screen 51.

As shown in fig. 3, in this embodiment, the workpiece carrier 6 further includes a bottom plate 63, a plurality of the rotary supporting seats 61 are arranged in a row at equal intervals on the bottom plate 63, a rotary gear 64 is coaxially connected to a lower portion of each rotary supporting seat 61, a transmission gear 65 for meshing transmission is disposed between any two rotary gears 64, a driving gear 66 meshed with one of the transmission gears 65 or the rotary gear 64 is further disposed on the bottom plate 63, and the rotation of the driving gear 66 can drive all the rotary supporting seats 61 to rotate synchronously in the same direction. The upper part of the driving gear 66 is provided with a transmission shaft hole 67 matched with the rotary driving mechanism 7. A cover plate 68 is buckled above the bottom plate 63, and the auxiliary support 62 is arranged on the cover plate 68.

The cylinder member adhered to in this embodiment is a cylinder member with a plane bottom surface, and therefore the top of the rotary support seat 61 is also a plane, but the rotary support seat 61 may be designed into other shapes according to the characteristics of the cylinder member under the design concept of the present invention, for example, the top surface is conical or cylindrical for positioning the cylinder member.

As shown in fig. 3, the auxiliary bracket 62 includes a polish rod 620 vertically disposed, and a limiting claw 621 capable of being adjusted and mounted in a lifting manner is disposed on the polish rod 620, and can be adjusted to a proper position according to the length of a workpiece to be mounted and fixed. The limiting claw 621 comprises a connecting seat 601, and a plurality of claw handles 602 are arranged on the connecting seat. Each auxiliary support 62 is provided with two claw handles 602 distributed in a shape like a Chinese character 'ba' above the corresponding rotary support seat 61, and the claw handles 602 on two adjacent auxiliary supports 62 can form a diamond frame for auxiliary support of a limiting workpiece.

In this embodiment, the claw handle 602 is connected to the connecting seat 601 in a turning manner, and the turning angle is limited to be from the horizontal direction to the vertical direction.

As shown in fig. 4, the inspection roller machine 2 includes an inspection roller machine support 21, a plurality of first conveyor roller shafts 22 arranged at intervals in the longitudinal direction on the inspection roller machine support 21, and both ends of the first conveyor roller shafts 22 are provided on the inspection roller machine support 21 through bearing blocks. The two ends of the first conveying roller shaft 22 are also provided with a first roller structure 23 for supporting the workpiece carrier 6. The first conveying roller shafts 22 are further provided with first chain wheels 24, and the inspection rolling machine support 21 is provided with a first driving motor 25 which drives the first chain wheels 24 on each first conveying roller shaft 22 to move synchronously. An output shaft of a first drive motor 25 is bridged over a first sprocket 24 provided on each of the first conveyor roller shafts 22 via a chain, and is capable of synchronously driving each of the first conveyor roller shafts 22 to rotate, thereby moving the workpiece carrier 6.

In this embodiment, the upper portion of the inspection rolling machine support 21 is further provided with a barrier 26 for shielding the first conveying roller shaft 22, and the main purpose is to improve the safety performance. The side of the enclosure 26, which is opposite to the lead room 1, is open, so that the workpiece bracket 6 can slide out conveniently. A first stop block 27 driven by an air cylinder is arranged on the inspection rolling bed support 21 corresponding to the open side of the enclosure 26, and the first stop block 27 is used for lifting the workpiece bracket 6 when the workpiece bracket 6 slides to the inspection rolling bed 2, so that the workpiece bracket 6 is limited from temporarily sliding out, and a worker or a manipulator can conveniently take and change workpieces.

As shown in fig. 5, the connection roller machine 3 includes a connection roller machine support 31 for being installed at the bottom of the lead chamber 1, the connection roller machine support 31 is provided with a plurality of second conveying roller shafts 32 at intervals along the length direction, and both ends of the second conveying roller shafts 32 are disposed on the connection roller machine support 31 through bearing seats. The second conveying roller shaft 32 is provided with a second roller structure 33 for lifting and conveying the workpiece carrier 6. The second conveying roller shaft 32 is further provided with a second chain wheel 34, and the connecting roller bed support 31 is further provided with a second driving motor 35 for driving the second chain wheel 34 on each second conveying roller shaft 32 to synchronously move. A driving sprocket is provided on the output shaft of the second driving motor, and a pair of chains is engaged with the second sprocket 34 on each of the second conveyor roller shafts 32, thereby achieving synchronous driving.

In addition, a baffle 36 for shielding both ends of the second conveying roller shaft 32 is arranged at the upper part of the connecting roller bed bracket 31. The refuting rolling machine support 31 is further provided with two second stop blocks 37 driven by cylinders, the interval distance between the two second stop blocks 37 is equal to the length of one workpiece bracket 6, when the workpiece bracket 6 is sent into the lead room 1 and reaches a preset position on the refuting rolling machine 3, the two second stop blocks 37 extend out to limit the workpiece bracket 6, on one hand, accurate positioning is provided for connection of the rotary driving mechanism 7, and on the other hand, displacement of the workpiece in the ray detection process is prevented.

As shown in fig. 6, the rotary drive mechanism 7 includes a bottom pallet 71 disposed on the docking roller bed support 31. The bottom supporting plate 71 is provided with a vertical plate 72. And a guide rail sliding block mechanism in the vertical direction is arranged on the vertical plate 72. The guide rail sliding block mechanism is provided with a carriage 73, the carriage 73 is provided with a servo motor 74, the servo motor 74 is located on the outer side of the connecting rolling machine 3, an output shaft of the servo motor 74 is connected with a rotary driving shaft 76 through a synchronous belt transmission mechanism 75, the rotary driving shaft 76 drives the rotary supporting seat 61, and the synchronous belt transmission mechanism 75 extends to the inner side of the connecting rolling machine 3, so that the rotary driving shaft 76 can be combined with the transmission shaft hole 67. In addition, a lifting cylinder 77 is arranged on the bottom supporting plate 71, a cylinder rod of the lifting cylinder 77 is connected with the carriage 73 and drives the carriage 73 to do lifting motion, so that the rotary driving shaft 76 is combined with or separated from the workpiece bracket 6, and the rotary supporting seat 61 is driven to rotate in a controllable manner.

As shown in fig. 7, the ray emission mechanism 4 in this embodiment includes a first cross sliding table 42 disposed on the front wall or the rear wall of the lead chamber 1, the ray emission tube 41 is disposed on the first cross sliding table 42, the horizontal stroke of the first cross sliding table 42 is not less than the length of the workpiece bracket 6, and the vertical stroke of the first cross sliding table 42 is not less than the length of the workpiece to be measured, so as to ensure that the workpieces entering the lead chamber 1 can all be irradiated by rays.

As shown in fig. 8, the radiation receiving mechanism 5 is disposed opposite to the radiation emitting mechanism 4, that is, the radiation emitting mechanism 4 is disposed on the front wall of the lead room 1, and the radiation receiving mechanism 5 is disposed on the rear wall of the lead room 1, and vice versa. The ray receiving mechanism 5 comprises a second cross sliding table 52, wherein the second cross sliding table 52 has the same structure as the first cross sliding table 42, and the second cross sliding table 52 and the first cross sliding table 42 are driven synchronously. The difference is that the Z-axis moving mechanism 53 is further disposed on the second cross sliding table 52, so that the receiving screen 51 can move opposite to the radiation emitting tube 41, which is more beneficial to imaging, and therefore the receiving screen 51 can realize three-axis movement. In this embodiment, the receiving screen 51 is disposed on the Z-axis moving mechanism 53, the Z-axis moving mechanism includes a servo motor, a guide rail slider mechanism, and a synchronous belt transmission device, which drive the receiving screen 51 to approach or depart from the radiation emitting tube 41, and the relative movement with respect to the radiation emitting tube 41 can be realized by the above structure.

The technical solutions provided by the embodiments of the present invention are described in detail above, and the principles and embodiments of the present invention are explained herein by using specific examples, and the descriptions of the above embodiments are only applicable to help understand the principles of the embodiments of the present invention; meanwhile, for a person skilled in the art, according to the embodiments of the present invention, there may be variations in the specific implementation manners and application ranges, and in summary, the content of the description should not be construed as a limitation to the present invention.

Claims (10)

1. The utility model provides a high-efficient ray detection equipment of cylinder spare which characterized in that: the inspection rolling machine comprises a lead room (1) and inspection rolling machines (2) arranged at the inlet and outlet positions at the left end and the right end of the lead room (1), wherein a connection rolling machine (3), a ray emission mechanism (4) and a ray receiving mechanism (5) are arranged in the lead room (1), a workpiece bracket (6) capable of sliding to the connection rolling machine (3) is arranged on each inspection rolling machine (2), the workpiece bracket (6) comprises a plurality of rotary supporting seats (61) arranged in a straight line, at least two auxiliary supports (62) are correspondingly arranged around each rotary supporting seat (61), a rotary driving mechanism (7) for driving the plurality of rotary supporting seats (61) to rotate around the axis of the rotary supporting seat is arranged on the connection rolling machine (3), the ray emission mechanism (4) is positioned at one side of the connection rolling machine (3), and the ray receiving mechanism (5) is positioned at the other side of the connection rolling machine (3), and the ray transmitting tube (41) of the ray transmitting mechanism (4) and the receiving screen (51) of the ray receiving mechanism (5) are always in a positive relationship, so that the rays transmitted by the ray transmitting tube (41) can be received by the receiving screen (51).

2. The efficient radiation detection device for cylindrical parts as claimed in claim 1, wherein: workpiece carrier (6) still include bottom plate (63), and is a plurality of gyration supporting seat (61) in equidistant row on bottom plate (63), every gyration supporting seat (61) lower part coaxial coupling has slewing gear (64), arbitrary two be provided with a meshing driven drive gear (65) between slewing gear (64), still be provided with on bottom plate (63) with one of them drive gear (65) or slewing gear (64) meshed driving gear (66), driving gear (66) upper portion have with slewing drive mechanism (7) complex transmission shaft hole (67), bottom plate (63) top lock is provided with apron (68), auxiliary stand (62) set up in on apron (68).

3. The high-efficiency ray detection device for the cylindrical member as claimed in claim 1 or 2, wherein: the top of the rotary supporting seat (61) is a plane.

4. The efficient radiation detection device for cylindrical parts as claimed in claim 1, wherein: auxiliary stand (62) are including polished rod (620) of vertical setting, be provided with spacing claw (621) that the liftable was adjusted the installation on polished rod (620), spacing claw (621) are including connecting seat (601), be provided with a plurality of claw handles (602) on the connecting seat the top of gyration supporting seat (61) is every all there are two claw handles (602) that are the splayed and distribute on auxiliary stand (62).

5. The efficient radiation detection device for cylindrical parts as claimed in claim 4, wherein: the claw handle (602) is connected with the connecting seat (601) in a turnover mode, and the turnover angle of the claw handle is limited to be from the horizontal direction to the vertical direction.

6. The efficient radiation detection device for cylindrical parts as claimed in claim 1, wherein: the inspection rolling machine (2) comprises an inspection rolling machine support (21), a plurality of first conveying roller shafts (22) are arranged on the inspection rolling machine support (21) at intervals along the length direction, two ends of each first conveying roller shaft (22) are arranged on the inspection rolling machine support (21) through bearing seats, first roller structures (23) used for supporting the workpiece bracket (6) are further arranged at two ends of each first conveying roller shaft (22), first chain wheels (24) are further arranged on the first conveying roller shafts (22), the inspection rolling machine support (21) is provided with first driving motors (25) for driving the first chain wheels (24) on each first conveying roller shaft (22) to move synchronously, a baffle (26) for shielding the first conveying roller shafts (22) is further arranged at the upper part of the inspection rolling machine support (21), and the baffle (26) is open at one side opposite to the lead (1), a first stop block (27) driven by an air cylinder is arranged on the inspection rolling bed support (21) corresponding to one side of the opening.

7. The efficient radiation detection device for cylindrical parts as claimed in claim 1, wherein: the connection rolling bed (3) comprises connection rolling bed supports (31) arranged at the bottom of the lead house (1), a plurality of second conveying roller shafts (32) are arranged on the connection rolling bed supports (31) at intervals along the length direction, two ends of each second conveying roller shaft (32) are arranged on the connection rolling bed supports (31) through bearing seats, second roller structures (33) used for supporting and conveying the workpiece brackets (6) are arranged on the second conveying roller shafts (32), second chain wheels (34) are further arranged on the second conveying roller shafts (32), second driving motors (35) used for driving the second chain wheels (34) on the second conveying roller shafts (32) to move synchronously are further arranged on the connection rolling bed supports (31), and baffle plates (36) used for shielding two ends of each second conveying roller shaft (32) are arranged at the upper parts of the connection rolling bed supports (31), the refuting roller machine support (31) is further provided with two second stop blocks (37) driven by cylinders, and the interval distance between the two second stop blocks (37) is equal to the length of one workpiece bracket (6).

8. The efficient radiation detection device for cylindrical parts as claimed in claim 7, wherein: the rotary driving mechanism (7) comprises a bottom supporting plate (71) arranged on the connecting rolling bed support (31), a vertical plate (72) is arranged on the bottom supporting plate (71), a guide rail sliding block mechanism in the vertical direction is arranged on the vertical plate (72), a dragging plate (73) is arranged on the guide rail sliding block mechanism, a servo motor (74) is arranged on the dragging plate (73), an output shaft of the servo motor (74) is connected with a rotary driving shaft (76) through a synchronous belt transmission mechanism (75), the rotary driving shaft (76) drives the rotary supporting seat (61), a lifting cylinder (77) is arranged on the bottom supporting plate (71), a cylinder rod of the lifting cylinder (77) is connected with the dragging plate (73) and drives the dragging plate (73) to do lifting motion, so that the rotary driving shaft (76) is combined with the workpiece bracket (6), and drives the rotary supporting seat (61) to rotate.

9. The efficient radiation detection device for cylindrical parts as claimed in claim 1, wherein: ray emission mechanism (4) including setting up first cross slip table (42) on plumbous room (1) antetheca or back wall, ray emission pipe (41) set up in on first cross slip table (42), the stroke of first cross slip table (42) horizontal direction is not less than the length of work piece bracket (6), the stroke of the vertical direction of first cross slip table (42) is not less than the length of the work piece that awaits measuring.

10. The efficient radiation inspection apparatus for cylindrical objects as claimed in claim 9, wherein: ray receiving mechanism (5) with ray emission mechanism (4) sets up relatively, ray receiving mechanism (5) are including setting up second cross slip table (52) on plumbous room (1) antetheca or the back wall, second cross slip table (52) with the structure of first cross slip table (42) is the same, just second cross slip table (52) with first cross slip table (42) synchronous drive, still be provided with Z axle motion (53) on second cross slip table (52), receive screen (51) set up in on Z axle motion (53), Z axle motion is including the drive receive screen (51) and be close to or keep away from servo motor, guide rail slider mechanism, the synchronous belt drive of ray emission pipe (41).

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