KR101209518B1 - Helical ct apparatus - Google Patents

Abstract

PURPOSE: A helical CT device is provided to prevent interference between members and accurately operate while generating the displacement of a table as a helical type in order to measure various shapes and properties of a subject. CONSTITUTION: A helical CT device comprises an X-ray generator(100), a detection unit(200), a table module(300), and a main frame(400). The X-ray generating unit emits X-ray beams. The detection unit senses the X-ray beams. The table module comprises a table, a pillar unit, a table base, and a rail supporting unit. The table module moves the table up and down and rotates in a horizontal direction, thereby moving a subject as a helical type with respect to the X-ray beams. The main frame supports the X-ray generating unit, the detection unit, and the table module.

Description

Helical CT device {HELICAL CT APPARATUS}

The present invention relates to an optical inspection device, and more particularly, to a helical CT device capable of measuring accurate three-dimensional shape through a single process while varying the displacement of a table so as to measure various shapes and properties of a subject. will be.

In industrial or medical X-ray CT apparatus, a stage is generally disposed between mutually arranged X-ray sources and X-ray detectors, and the X-ray beam is examined by irradiating an object such as an object to be examined or a human body. Perform

The X-ray beam is irradiated onto the subject while the subject is held on the stage. X-ray transmission data is obtained from the X-ray detector each time the stage is rotated at a predetermined minute angle or the X-ray source and the module of the detector are rotated.

1 is a conceptual diagram briefly showing the configuration of an X-ray analyzer of the prior art.

The sample S is disposed on a predetermined sample table, and the X-ray generator 11 directs the converging beam 14 of X-rays toward the surface of the sample S.

The detector 16 is arranged to detect the X-rays 15 scattered from the sample, and this configuration is common to the concept of X-ray diffraction analysis equipment or X-ray reflection analysis equipment.

In a conventional X-ray material analysis apparatus, an X-ray generator such as an X-ray tube and a detector are generally disposed to be fixed at a predetermined angle with respect to the central axis of the sample table.

In particular, in the case of X-ray diffraction analysis equipment, X-ray generator, detector and sample table due to the angle of incidence and scattering angle of X-ray diffraction analysis is limited to use to identify the structure of relatively homogeneous samples such as samples or fine particles .

Recently, the necessity for measuring various shapes and physical properties of an object is increasing, but there is a problem that conventional X-ray analyzers are difficult to meet these requirements. In particular, when the inspection of a subject having a complex three-dimensional shape is required, not only are there physical limitations in measuring each part individually, but even if such a measurement is possible, it is not practical to create an algorithm that can be combined and analyzed. there was.

The present invention has been made to solve the above problems, and provides a helical CT device capable of accurately driving and preventing interference between members while generating a displacement of a table in a helical type to measure various shapes and physical properties of a subject. The purpose is to.

In addition, an object of the present invention is to provide a helical CT device that can accurately control the distance and position to the X-ray beam to measure the three-dimensional shape at various angles of the subject and the physical properties at various focal points.

The helical CT device of the present invention includes an X-ray generator that emits an X-ray beam, a detector that detects the X-ray beam, and a table for seating the subject, and moves the subject to the X-ray beam by lifting and lowering the table. It provides a helical CT device comprising a table module for moving in a spiral relative to. Therefore, the three-dimensional shape and the physical properties of the subject can be accurately inspected through one process.

In addition, the helical CT device of the present invention, the X-ray beam provides a helical CT device, characterized in that emitted from the X-ray generating portion in a conical shape or a fan shape having a width larger than the height. Therefore, by accurately analyzing the signal of the X-ray beam detected by the detection unit in a predetermined control unit can be reproduced accurately.

In addition, the helical CT device of the present invention, the table module includes a lifting unit for supporting the rotational movement of the table, the support for supporting the lifting of the lifting unit and the support base and the table base for supporting the support from above. It provides a helical CT device. Thus, the structure is robust and accurate helical movement of the table is possible.

In addition, the helical CT device of the present invention, the holding portion is disposed in the height direction and the lifting rail for guiding the lifting and lowering of the lifting portion, disposed in the height direction through the ball nut provided in the lifting portion and transmits the rotational movement Provided is a helical CT device comprising a lifting shaft for converting into a linear movement and the lifting drive unit is disposed on the upper side to rotate the lifting shaft. Thus, reliability and structural simplicity of operation are provided.

In addition, the helical CT device of the present invention, the table module is arranged in the front and rear direction through the horizontal rail for guiding the front and rear direction transfer of the table base, the ball nut provided on the table base, the linear motion of the rotary motion It provides a helical CT device further comprising a rail support portion consisting of a horizontal axis for converting the horizontal axis and the horizontal driving portion for rotating the horizontal axis. Therefore, since the table module can be moved in the Y-axis direction, it is possible to inspect the exact position of the X-ray beam.

In addition, the helical CT device of the present invention, further comprising a main frame for supporting the X-ray generating unit, the detection unit and the table module on the upper side, wherein the rail support is arranged to be transportable in both directions with respect to the main frame Provided is a helical CT device. Therefore, the table can move in all directions.

In addition, the helical CT apparatus of the present invention provides a helical CT apparatus, wherein the detection unit is disposed to be transportable in both directions with respect to the main frame, and the X-ray generator is fixed to the main frame. . Therefore, it is easy to adjust the relative distance between the detector, the table module and the X-ray generator.

In addition, the helical CT device of the present invention is disposed on the upper side of the main frame, and provides a helical CT device further comprises a transfer rail for guiding the transfer in both directions of the table module and the detector support. do. Therefore, the structural reliability is simple and the operation reliability is improved.

In addition, the helical CT device of the present invention is disposed between the table module and the detector support of the main frame, characterized in that it further comprises a stopper for limiting the transfer of the both sides of the table module and the detector support. Provide a helical CT device. Therefore, it is possible to prevent interference between undesirable members.

On the other hand, the helical CT device of the present invention, the main frame, the X-ray generator is fixedly coupled to the main frame, the detection unit arranged to be transported to both sides with respect to the main frame and the main frame in the front and rear directions and both directions A table base disposed to be transportable, a support portion supported on the table base, a lift portion disposed to move up and down relative to the support portion, and disposed to be rotatable in a horizontal direction with respect to the lift portion, and having a subject seated on an upper surface thereof. It provides a helical CT device comprising a table module having a table. Therefore, the helical type inspection can be easily performed as a whole module.

In addition, the helical CT device of the present invention, when the inspection of the subject, the table provides a helical CT device, characterized in that the X-ray beam is irradiated while moving up and down simultaneously with the rotation. Therefore, accurate measurement of the three-dimensional shape is possible.

In addition, the helical CT device of the present invention provides a helical CT device further comprises a shutter device disposed on the path of the X-ray beam to limit the size and shape of the X-ray beam. Therefore, since the X-ray beam can be emitted accurately, undesirable exposure is minimized and accurate image reproduction is possible.

The helical CT device according to the present invention has an effect of accurately measuring the shape of a three-dimensional object by moving in a spiral by simultaneously rotating and lifting the table with respect to the X-ray beam.

In addition, the table module is equipped with a structure that can be accurately transported in the X-axis and Y-axis direction to accurately determine the focus and position of the X-ray beam can further improve the accuracy of the inspection, the detection unit in the X-axis direction By allowing it to be transported, the efficiency of inspection of the object shape and physical properties is maximized.

In addition, as a simple structure to enable a variety of movement and movement of the member, durability and operation reliability is guaranteed and there is an effect capable of accurate and various inspections.

1 is a conceptual diagram of a material analysis instrument using X-ray of the prior art.
Figure 2 is a perspective view of the helical CT device of the present invention as viewed from the X-ray generator.
Figure 3 is a rear view showing the helical CT device of the present invention from the rear side.
Figure 4 is a perspective view of the helical CT device of the present invention as seen from the detection unit side.

Hereinafter, with reference to the accompanying drawings will be described in more detail the helical CT device according to the present invention.

2 is a perspective view of the helical CT device according to the present invention viewed from the X-ray generating unit side, FIG. 3 is a rear view showing the helical CT device shown in FIG. 2 from the rear side, and FIG. 4 is a detection unit side of the helical CT device of the present invention. This is a perspective view from above.

The helical CT device 10 of the present invention basically includes an X-ray generator 100, a detector 200, and a table module 300.

The X-ray generator 100 is used for various types of equipment for emitting X-rays, X-ray tube having an electron gun and a target therein is used, preferably a closed type (closed type) having a substantially vacuum inside and high output X-ray generator can be used. In addition, of course, an open type X-ray tube 110 may be applied.

The detector 200 includes a detector (not shown) for detecting X-rays passing through a subject, and the detector transmits the detected X-rays to an electric signal and transmits the detected X-rays to a controller (not shown). Provides data for analysis.

In the helical CT device 10 of the present invention, the table 310 is moved up and down while rotating between the X-ray generator 100 and the detector 200 while the subject is seated.

The X-ray beam 101 from the X-ray generator 100 may be emitted in various shapes. In the drawing, the X-ray beam 101 is shown to be emitted in a cone shape. In detail, when the X-ray beam 101 is emitted from the X-ray source 111 of the X-ray tube 110, the cross-sectional area gradually diffuses to reach the detection unit 200.

However, the shape of the X-ray beam 101 is not necessarily limited thereto, but may be formed in a square pyramid shape, or a fan shape having a relatively small vertical width. In the present invention, as the table 310 rotates with respect to the X-ray beam 101, the concept detected by the detector 200 is presented as the object is seated on the table 310. It moves in a spiral shape. According to this concept, the X-ray beam 101 is formed so that the left and right widths at the portion where the subject is disposed can cover the width of the subject, but the height in the vertical direction is preferably limited to some extent. That is, the predetermined pixel for detecting the X-ray beam 101 in the detection unit 200 is a pixel having a limited height, and it is more preferable in forming an algorithm for checking a three-dimensional shape that the subject moves up and down while rotating in this area. can do.

Therefore, the X-ray generator 100 may further include a shutter device (not shown) that limits the width and / or height of the X-ray beam 101 adjacent to the X-ray source 111.

In the helical CT device 10 of the present invention, it is easy to control the position of the X-ray generator 100, the detector 200, and the table module 300 as a whole as a module. Therefore, the members are coupled to the main frame 400 supporting the entire member with respect to the ground.

The X-ray generator 100 is fixedly coupled to the main frame 400, and the table module 300 and / or the detector 200 are moved relative to the X-ray generator 100 as described below. It is preferable to control. However, the X-ray generator 100 may also be coupled to vary in position in the main frame 400.

The X-ray generator 100 includes an X-ray tube supporter 120 and an X-ray tube supporter 120 that is fixed to the main frame 400 while supporting the X-ray tube 110 and the X-ray tube 110. The X-ray tube 110 includes members for generating X-rays, such as an electron generating unit and a target, and has an approximately hollow columnar shape, and emits the X-ray beam 101 toward the side from the end side. However, in general, since the X-ray tube 110 has a predetermined inclined surface due to the placement of the target, the X-ray tube 110 may be arranged to have a predetermined slope on a plane with respect to the main frame 400.

The X-ray tube supporter 120 is a member coupled to the main frame 400 at the lower end side while fixing the X-ray tube 110 at a predetermined height at the upper end side, and according to the arrangement relationship of the X-ray tube 110. It is preferable to be disposed at the corner of the main frame 400 so that the obstacle to the movement of the module 300 is minimized, but is not necessarily limited thereto. When the X-ray tube supporter 120 is disposed at the corner portion of the main frame 400, the X-ray tube supporter 120 may have a '-' shape to correspond to the shape of the corner portion of the main frame 400 to maximize space utilization.

The table module 300 includes a power member for rotating and linearly rotating the table, including a table 310, and as described above, the table 310 performs a helical motion with respect to the X-ray beam 101. Each member is coupled to each other to allow movement.

In detail, the table 310 may have an upper surface having a substantially flat plate shape and the subject may be seated on the upper surface. A lifting unit 320 is provided as a structure for directly supporting the table 310, and the lifting unit 320 supports the table 310 in a horizontal direction so as to be rotatable in a horizontal direction on the upper side of the table 310. ) Is arranged to move up and down in a state provided with a rotation driving unit (not shown) and a power transmission unit (not shown) to rotate.

The lifting unit 320 is supported by the support 330, the support 330 is a column-shaped member disposed in a direction substantially perpendicular to the main frame 400 to transfer the lifting unit 320. Support it.

The support portion 330 is provided with a lifting rail 322 to guide the transport while supporting the lifting portion 320 to the front side, the lifting portion 320 is guided to the lifting rail 322 to the rear side It may be provided with a predetermined guide means such as grooves or rollers. Two lifting rails 322 are preferably arranged on both sides.

Power means may be provided in the support portion 330 in order to provide the driving force of the lifting movement of the lifting unit 320, in the embodiment of the present invention, the lifting shaft 321 on the front side of the support portion 330 Longitudinally disposed in this longitudinal direction, the lifting drive unit 323 for rotating the lifting shaft 321 is disposed. The lifting driving unit 323 is sufficient to be properly disposed in the selected portion, but is preferably coupled to the upper end side of the support portion 330 in order to maximize space utilization.

The lifting shaft 321 may be preferably made of a screw shaft, according to this concept, the lifting unit 320 may be provided with a ball nut. Therefore, as the lifting shaft 321 inserted into the ball nut provided in the lifting unit 320 rotates, the rotational motion may be converted into the vertical movement of the lifting unit 320 in the vertical direction. However, as the power providing means for vertically conveying the lifting unit 320, various means such as a belt or a gear may be used.

The holding unit 330 may be fixedly disposed on the main frame 400, but the entire table module 300 is selected to select an appropriate front and rear position during the helical movement of the X-ray beam 101 of the table 310. It is preferable to have a structure that can be transported forward and backward with respect to the main frame 400.

Thus, the support 330 may be fixed to and supported by the table base 340. The table base 340 is a substantially flat member and supports the support 330 at the rear side in the example of the figure, and may support the rotational movement of the lower end side of the lifting shaft 321 at a portion thereof.

As described above, an example in which the table base 340 is horizontally moved forwards and backwards with respect to the main frame 400 is provided. For this structure, the main base 400 has guide means for horizontal movement of the table base 340. And a power supply means may be provided.

Specifically, the main frame 400 is provided with a horizontal rail 332 across the front and rear. The horizontal rail 332 is disposed below the table base 340 to guide the horizontal transfer of the table base 340, it is preferable that the two arranged on both sides for the guide of the accurate transfer, but the horizontal rail 332 The number and arrangement of can be made optionally.

In addition, a driving unit may be disposed to move the table base 340 forwards and backwards, and thus a horizontal shaft 331 is provided to be substantially parallel to the horizontal rail 332 to provide power to the horizontal shaft 331. The horizontal driving unit 333 may be provided. As described above, the horizontal shaft 331 is composed of a screw shaft is coupled in a way that is screwed to the ball nut disposed on the holding portion 330 to convert the rotational movement to linear movement, power such as a belt or gear Of course, the delivery means may be applied.

Although the horizontal driving unit 333 is illustrated as being disposed on the rear side, it may be provided in the front, as well as may be arranged in various positions according to the selection.

In some cases, there is a need to adjust the distance of the subject from the X-ray source 111 in the inspection process. Therefore, the table module 300 of the helical CT device 10 according to the concept of the present invention may further include a structure that can be transferred to both sides in a state in which the horizontal rail 332 supports the table base 340. .

The horizontal rail 332 is fixed to the rail support portion 350, which is a predetermined support member, to be transported to both sides with respect to the main frame 400. The rail support part 350 is transported to both sides with respect to the main frame 400 in a state in which the horizontal support part 331 and the horizontal driving part 333 are supported. The upper surface of the 400 may be provided with a conveying rail 342 of both sides long.

The length of the conveying rail 342 is preferably arranged to be disposed across most of the transverse direction of the main frame 400 when the detection unit 200 is arranged to be transported as will be described later, the length is May be made selectively.

As described above, when defining the front and rear of the main frame 400 in the Y-axis, the X-axis in both directions, and the Z-axis in the height direction, based on the arrangement of Figure 2, the transport rail coupled to the main frame 400 A rail support part 350 is disposed along the 342 so as to be transported in the X axis direction, and the table base 340 is movable in the Y axis direction along the horizontal rail 332 coupled to the rail support part 350. The support base 330 is disposed upright on the table base 340 so that the lifting unit 320 supporting the table 310 in the upper direction along the lifting rail 322 disposed therein is in the Z-axis direction. It is arranged to be transportable. In addition, the lifting unit 320 is disposed so that the table 310 is rotatable about an axis parallel to the Z axis. In this case, the table module 300 of the helical CT device 10 of the present invention merges the movement of the lifting unit 320 and the rotation of the table 310 to helically move the subject with respect to the X-ray beam 101. As a result, accurate three-dimensional shape or physical property can be measured, and the distance and focus of the X-ray beam 101 can be focused through the horizontal transfer of the table base 340 and the rail support 350.

Meanwhile, the detector 200 may be fixedly arranged to face the X-ray tube 110 based on the position of the table 310 in the main frame 400, but the detector may be used to inspect a subject having various physical properties or shapes. Preferably, the distance in the X-axis direction with respect to the X-ray tube 110 or the subject of the 200 is variable.

Therefore, the detection unit 200 has a configuration that can be linearly transferred to both sides with respect to the main frame 400, a separate guide means may be provided to guide the transfer of the detection unit 200 is structural For the sake of simplicity, the guide portion for conveying the detection unit 200 preferably shares a conveying rail 342 for guiding the X-axis conveyance of the table module 300.

However, since the motion of the detector 200 must be controlled separately, the adjustment driver 223 may be coupled to the main frame 400. The adjustment driving unit 223 is connected to the adjustment shaft 221 and transmits the rotational power, like the other conveying means, the adjustment shaft 221 is made of a screw shape is arranged to penetrate through the lower end portion of the detection unit 200 It is possible to convert the rotational motion to linear motion by the ball nut, the power transmission means can be replaced by a gear or a belt, of course.

In addition, the table module 300 is preferably transported over the entire area between the X-ray generator 100 and the detection unit 200, accordingly, the transport rail 342 and the feed shaft 341 is the main frame 400 It can be formed long over both sides of as described above. By the way, the transport distance of the detection unit 200 is bound to be quite limited with respect to the transport distance of the table module 300.

Therefore, the adjustment shaft 221 is also arranged on the other side of the main frame 400 is deviated and made in parallel with the feed shaft 341, it may be formed shorter than the feed shaft 341.

In more detail, the structure of the detector 200 is arranged to correspond to the height of the X-ray source 111, which is approximately vertical in order to support the main frame 400. A detector support 210 disposed thereon supports the detector. The detector support part 210 is supported by the detector base 220 at the lower side, and the detector base 220 is seated on the transfer rail 342 as described above to guide the transfer.

The detector base 220 is provided with a ball nut at a portion thereof so that the adjustment shaft 221 penetrates. The adjustment guide is disposed adjacent to and parallel to the adjustment shaft 221 in order to guide the accurate transfer of the detection unit 200. It is preferable that 222 is further provided.

The adjustment guide 222 may be supported by a bracket (not shown) with the adjustment shaft 221 on one side, and fixed by another bracket (not shown) with the adjustment driver 223 on the other side. Can be. The bracket provided on one side of the stopper part fixes the adjusting shaft 221 and the adjusting guide 222 to guide the accurate feeding and also functions as a stopper for limiting the X-axis feeding of the detection unit 200. It is defined as (224).

On the other hand, as described above, since the feed shaft 341 is formed to be relatively long, interference may occur between the lower end side of the detector 200 and the feed shaft 341 according to the transfer of the detector 200. Therefore, the lower end of the detector support 210 is preferably further provided with a groove-shaped groove 211 formed upwardly so that the feed shaft 341 can be penetrated.

The stopper part 224 may also function as a stopper of the table module 300 by limiting the transfer of the lower end of the table module 300 from one side, in which case the position of the stopper part 224 is appropriately selected. It should be noted that there is an advantage that can prevent the undesirable contact between the table 310 and the detector.

The helical CT device 10 according to the concept of the present invention allows the table 310 to rotate and move up and down simultaneously with respect to the X-ray beam 101 so as to spirally move to accurately check the shape of a three-dimensional object. .

In addition, the table module 300 is provided with a structure that can be accurately transported in the X-axis and Y-axis direction to accurately determine the focus and position of the X-ray beam 101 can further improve the accuracy of the inspection The detector 200 may be transferred in the X-axis direction, thereby maximizing the efficiency of subject inspection.

Since the configuration of the helical CT device 10 of the present invention is a simple structure to enable a variety of movement and movement of the members, it should be noted that durability and operation reliability is guaranteed and accurate and versatile inspection is possible.

In the foregoing, the present invention has been described in detail based on the embodiments and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

10 ... helical CT device 100 ... X-ray generator
101 X-ray beam 110 X-ray tube
111 X-ray source 120 X-ray tube support
200 ... detector 210 ... detector support
220 detector base 221 adjustment shaft
222 ... Adjustment guide 223 ... Adjustment drive
300 ... Table Module 310 ... Table
320 ... elevator 321 ... elevator shaft
322 Lift Rail 323 Lift Drive
330 ... Holding part 331 ... Horizontal axis
332 Horizontal Rail 333 Horizontal Drive
340 ... table base 341
342 Transfer rail 343.
350 rail support 400 main frame

Claims (13)

An X-ray generator for emitting an X-ray beam;
A detector detecting an X-ray beam;
A table on which a subject is seated, a lifting part supporting a rotational movement of the table, a support part supporting lifting and lowering of the lifting part, a table base supporting the support part from above, and supporting the table base on the upper side A table module having a rail support and moving the subject in a spiral manner with respect to the X-ray beam by moving the table in a descending and horizontal direction; And
And a main frame supporting the X-ray generator, the detector, and the table module at an upper side thereof.
The lifting portion is guided in the vertical direction by the holding portion,
The table base is a helical CT device, characterized in that the front and rear conveyance is guided by the rail support. The method of claim 1,
The X-ray beam is helical CT device, characterized in that emitted from the X-ray generator in a conical shape. The method of claim 1,
The X-ray beam is helical CT device, characterized in that emitted from the X-ray generating portion in a fan shape having a width larger than the height. delete The method of claim 1,
The support portion is disposed in the height direction and the lifting rail for guiding the lifting of the lifting unit, the lifting shaft and the upper end is arranged in the height direction through the ball nut provided in the lifting unit and converts into a linear movement by transmitting a rotational movement A helical CT device, characterized in that it comprises a lifting drive unit which is disposed on the side to rotate the lifting shaft. The method of claim 1,
The rail support portion, a horizontal rail for guiding the front and rear direction transfer of the table base from the upper side, is disposed in the front and rear direction through the ball nut provided on the table base and rotates the horizontal axis and the horizontal axis for converting the rotational movement into a linear movement Helical CT device, characterized in that consisting of a horizontal drive. The method according to claim 6,
The rail support portion, the helical CT device, characterized in that arranged to be transportable in both directions with respect to the main frame. The method of claim 7, wherein
The detection unit is disposed to be transferable in both directions with respect to the main frame,
The X-ray generator, characterized in that the helical CT device is fixed to the mainframe. 9. The method of claim 8,
Helical CT device further comprises; a conveying rail disposed on the main frame, the conveying rail for guiding the conveyance in both directions of the table module and the detection unit. 10. The method of claim 9,
And a stopper unit disposed between the table module and the detection unit of the main frame and configured to limit the transfer of the table module and the detection unit in both directions. An X-ray generator for emitting an X-ray beam;
A detector detecting an X-ray beam;
And a table module having a table on which a subject is seated, a lifting part supporting a rotational movement of the table, a support part supporting lifting and lowering of the lifting part, and a table base supporting the support part from above. ,
The support portion is disposed in the height direction and the lifting rail for guiding the lifting of the lifting unit, the lifting shaft and the upper end is arranged in the height direction through the ball nut provided in the lifting unit and converts into a linear movement by transmitting a rotational movement A helical CT device, characterized in that it comprises a lifting drive unit which is disposed on the side to rotate the lifting shaft. The method of claim 11,
The helical CT device, characterized in that the X-ray beam is irradiated while the table is raised and lowered at the same time when the subject is examined. The method of claim 12,
And a shutter device disposed on a path of the X-ray beam to limit the size and shape of the X-ray beam.

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