1. Field of the Invention
The present disclosure relates to an X-ray imaging system applicable to medical equipment, a nondestructive inspection apparatus and the like. More particularly, the present invention relates to a medical X-ray imaging system capable of reducing unnecessary X-ray exposure of a subject and an X-ray imaging system using the X-ray imaging system.
2. Description of the Related Art
An X-ray imaging system includes a radiation generating apparatus and an X-ray detecting device. The radiation generating apparatus typically includes an X-ray generating tube in a container and includes a movable diaphragm unit on a front side of an X-ray emission window provided in this container. The movable diaphragm unit has a function to adjust an X-ray field by shielding, using a restricting blade, a portion unnecessary for imaging among the X-ray emitted from the X-ray generating tube and to reduce exposure of the subject to X-ray.
As a movable diaphragm unit, Japanese Patent Laid-Open No. 2009-90035 discloses a movable diaphragm unit capable of adjusting an opening diameter by moving a plate-shaped leaf (i.e., a restricting blade) on a curved surface. In such a movable diaphragm unit, the restricting blade has a predetermined thickness necessary to attenuate the X-ray in order to prevent X-ray from leaking in an unnecessary direction.
In the X-ray generating apparatus disclosed in Japanese Patent Laid-Open No. 2009-90035, the restricting blade rotates on a curved surface of which radius of curvature is a distance significantly shorter than a distance between the restricting blade and the focal spot of X-ray. Therefore, there has been a problem that, when the restricting blade opens widely, an effective thickness of the restricting blade at a corner on an opening side thereof is reduced and X-ray partially passes through the restricting blade, whereby unnecessary exposure of a subject increases.
Therefore, it has been necessary to provide an X-ray generating apparatus capable of optimizing an angle of the restricting blade with respect to a direction in which the X-ray is emitted and reducing unnecessary exposure of a subject. The present invention provides an X-ray imaging system capable of reducing unnecessary exposure and an X-ray imaging system using the X-ray imaging system.
An X-ray imaging system, including: a radiation generating apparatus which includes an X-ray generating unit configured to emit X-ray from a target upon irradiation of the target with an electron beam, and a movable diaphragm unit which includes a restricting blade configured to restrict a passage range of the X-ray and a moving mechanism of the restricting blade; and
an X-ray detecting device configured to detect, on a detector plane, X-ray emitted from the radiation generating apparatus and has passed through an object,
wherein the restricting blade has a predetermined thickness defined by a front surface on a target side and back surface of the opposite side of the front surface, and includes an end surface which communicates with the front surface and the back surface on a side on which the X-ray passes,
the moving mechanism moves the restricting blade in a direction in which the restricting blade crosses the end surface,
wherein, when a width of an eclipsed penumbra formed by X-ray emitted from a focal spot defined by an electron beam flux applied to the target, is in contact with the end surface, and arrives at a first virtual plane which includes the detector plane is denoted by h1 and a width of an attenuated penumbra formed by X-ray emitted from the focal spot, enters from the end surface, passes through the restricting blade, and arrives at the first virtual plane is denoted by h2, a relationship h2<h1 is satisfied,
a second virtual plane which is in contact with the end surface crosses a third virtual plane which includes the focal spot,
when the restricting blade is moved away from a normal line extending from a center of the focal spot to the first virtual plane, a moving distance of a crossing line of the second virtual plane and a third virtual plane with respect to a center of the focal spot is shorter than a moving distance of the end surface with respect to the normal line.
An X-ray imaging system including: the X-ray imaging system according to claim 1; and a control device configured to control the radiation generating apparatus and the X-ray detecting device in the X-ray imaging system in a cooperated manner.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
In an X-ray imaging system, a main factor that defines a resolution of an X-ray imaging image is a focal diameter in a target which is an X-ray source. The focal spot of X-ray emitted by the X-ray imaging system according to the present invention is substantially defined by a focal spot of an electron beam flux applied to a target from an electron emission source. Hereafter, in this specification, the focal spot of the electron beam defined by the electron beam flux on the target will be referred to as a focal spot.
From a viewpoint of improving the resolution of the X-ray imaging image described above, it is desirable for the focal diameter to be small as much as possible. From a viewpoint of heat resistance of a material which constitutes the target and output intensity of X-ray, lower and upper limits of an anode current density and a focal diameter which flow in the target are defined, respectively. Typically, the lower limit of the focal diameter is set to be several tens of micrometers from a viewpoint of heat-resistant of the target, and the upper limit of the focal diameter is set to be several mm from a viewpoint of resolution.
In a movable diaphragm unit as described in Japanese Patent Laid-Open No. 2009-90035 provided with a restricting blade, a typical range of thickness of the restricting blade is from equal to or greater than 0.1 mm to equal to or less than several tens of mm in a direction of the object or the X-ray detecting device from the focal spot. In the X-ray imaging system which includes the movable diaphragm unit described above, a penumbra is unavoidably produced resulting from the “focal diameter” and the “thickness” of the restricting blade of the movable diaphragm unit in an outer periphery of the exposure range.
An object of the present invention is to provide an X-ray imaging system capable of reducing penumbra leaking out of a detector.
Hereinafter, in the invention in the present application, a point which corresponds to an electron beam flux beam spot and has a limited focal diameter on an electron beam incident surface of a target will be referred to as a “focal spot.”
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The size, material, shape, relative arrangement and the like of the components described in the embodiments are not limiting the scope of the present invention.
The radiation generating apparatus 100 according to the present invention includes the X-ray generating unit 101 and the movable diaphragm unit 140. In the X-ray generating unit 101, the transmission X-ray generating tube 110 and the high voltage circuit 130 are housed in a container 102 that is filled with an insulating liquid 150. The insulating liquid 150 functions as an insulating medium and a cooling medium of the X-ray generating tube 110. It is desirable to use an electric insulating oil for the insulating liquid 150: specifically, mineral oil, silicone oil and the like are used suitably. Other examples of the insulating liquid 150 include a fluorine-based insulating liquid.
The high voltage circuit 130 generates a voltage which is applied to a cathode 111, a grid electrode 112, a lens electrode 113 and a target 115 of the X-ray generating tube 110. The target 115 consists of a target layer 115a fixed on a supporting substrate 115b which is made of a radiotransparent material. The cathode 111 is made of a tungsten filament, a hot cathode, such as an impregnated cathode, and a cold cathode. In a vacuum chamber 114, electrons are emitted toward the target 115 by an electric field formed by a grid electrode 112. The emitted electrons become an electron beam which is converged at the lens electrode 113, collides with the target layer 115a, and X-ray is emitted. At this time, unnecessary X-ray is shielded by an X-ray shielding member 117. The target layer 115a is made of, for example, tungsten, tantalum and molybdenum. After passing through the X-ray emission window 121, the X-ray is released outside under the limitation of an irradiation field by the movable diaphragm unit 140.
The X-ray imaging system of the present invention includes the radiation generating apparatus 100 and the X-ray detecting device 201 illustrated in
The movable diaphragm unit 140 according to the present invention includes the restricting blade 3 which restricts a passage range of X-ray, and a moving mechanism (not illustrated) of the restricting blade 3. As illustrated in
The X-ray emitted from the focal spot 1 which has a limited size as described above passes through an opening formed by the restricting blade 3 (i.e., a right side area of the restricting blade 3 of
There is an area formed by X-ray partially passing therethrough because of a reduced effective thickness of the restricting blade 3 when seen from the irradiation side. This area is referred to as an attenuated penumbra 10. That is, the attenuated penumbra 10 is an area formed by the X-ray emitted from the focal spot 1, enters from the end surface 4 of the restricting blade 3, passes through the restricting blade 3, and arrives at the first virtual plane 14. In
The foregoing is defined by the positional relationships illustrated in
Since both the eclipsed penumbra 9 and the attenuated penumbra 10 are unnecessary components to the X-ray imaging image and may provide unnecessary exposure to the subject, it is desirable to reduce a width h1 of the eclipsed penumbra 9 and a width h2 of the attenuated penumbra 10. However, since the width of the eclipsed penumbra 9 is determined by the size of the focal spot 1 and an arrangement of the components, there is a limit to the reduction of the size of the eclipsed penumbra 9 from a viewpoint of the maintenance of predetermined X-ray intensity. In contrast, since the width of the attenuated penumbra 10 is determined by an angle of the end surface of the restricting blade 3, it is possible to reduce the attenuated penumbra 10 by the posture of the restricting blade 3.
In the present invention, in a case in which the width h1 of the eclipsed penumbra 9 and the width h2 of the attenuated penumbra 10 are not uniform at an arbitrary position of the restricting blade 3, h1 and h2 are defined by values obtained at a position nearest to a normal line 2 of the end surface 4.
Regarding the reduction of h2, according to the knowledge of the present inventors, if h1>h2, the X-ray of the attenuated penumbra 10 is attenuated when the X-ray partially passes through the restricting blade 3. Therefore, an effect of the exposure by the attenuated penumbra 10 is considered to be small enough.
Further, as a more quantitive threshold, a harmful effect caused by the unnecessary exposure is not increased significantly as long as the exposure dose is equal to or smaller than the exposure dose caused by, for example, natural X-ray. The exposure dose caused by natural X-ray is considered to be 2.4 mGy/year/person, that is, 6.6 μGy/day/person. An exposure dose of a chest X-ray is 0.15 mGy. If an unnecessary exposure dose by the chest X-ray does not exceed the exposure dose caused by natural X-ray, it is considered that attenuated penumbra by X-ray radiography has no effects.
In
Generation of the eclipsed penumbra 9 is unavoidable but should be reduced. Here, an intensity ratio of the exposure dose caused by natural X-ray to the eclipsed penumbra 9 will be considered as an index of an intensity ratio of the attenuated penumbra 10 to the eclipsed penumbra 9. The intensity ratio of the exposure dose caused by natural X-ray with respect to the eclipsed penumbra 9 is 6.6/37=0.18. Therefore, when it is supposed that there is no reduction in dose after the X-ray passes through the restricting blade 3, if h2≦0.18×h1, the effect of the exposure of the attenuated penumbra 10 is considered to be equal to or smaller than that of the natural X-ray and can be tolerated.
As illustrated in
As a method for reducing the width h2 of the attenuated penumbra 10, a crossing line 17 at which a second virtual plane 15 in contact with the end surface 4 of the restricting blade 3 and a third virtual plane 16 which includes the focal spot 1 cross each other is first defined as illustrated in
For example, as illustrated in
Exemplary moving mechanisms to implement the present embodiment will be described. As illustrated in
According to this moving mechanism, since X-ray may be applied to the detector plane 206a while keeping the attenuated penumbra 10 small, it is desirable that the unnecessary exposure is made to the minimum. Further, since the restricting blade 3 is moved in a circular arc, a movement region of the restricting blade 3 may be made smaller than in a case in which the restricting blade 3 is moved in parallel, and the size of the restricting blade 3 may be reduced, it is desirable that the weight of the apparatus may be reduced.
A specific moving form of a restricting blade 3 in the present embodiment is illustrated in
In the present embodiment, the restricting blade 3 consists of a plurality of auxiliary blades 3a, 3b and 3c which are stacked in a thickness direction from a front surface 5 toward a back surface 6 so as to be relatively movable. As illustrated in
In the present embodiment, the end surface 4 of the restricting blade 3 is divided into end surfaces 4a, 4b and 4c of the auxiliary blades 3a, 3b and 3c. Therefore, as illustrated in
Desirable examples of the moving mechanism of the auxiliary blades 3a, 3b and 3c include, as illustrated in
According to the present embodiment, when the restricting blade 3 is to be moved, along a surface which crosses the normal line 2, the restricting blade 3 is moved while changing an angle made by a front surface 5 and the second virtual plane 15, and an amount of change in distance between a back surface 6 and the normal line 2 becomes longer than an amount of change in distance between a front surface 5 and the normal line 2.
The distance between the front surface 5 and the normal line 2 is defined by a distance between a side of the front surface 5 located nearer to the normal line and the normal line 2, and the distance between the back surface 6 and the normal line 2 is defined by a distance between a side of the back surface 6 located nearer to the normal line and the normal line 2.
Applications of the first and the second embodiments will be described.
In the present invention, as illustrated in
Further, in the present invention, as illustrated in
As illustrated in
In the form in which the first restricting blade 3 to the fourth restricting blade 34 and the back blade 32 are combined as illustrated in
In the present invention, as illustrated in
In the present invention, as illustrated in
In the present invention, in a form in which the third restricting blade 33 and the fourth restricting blade 34 illustrated in
Although applications of the first embodiment are described in the foregoing, the same applications may be made to the second embodiment.
In the present invention, as illustrated in
A transmission radiation generating apparatus equipped with the movable diaphragm unit described in the first embodiment is configured and the X-ray imaging system of the present invention is configured. In the X-ray imaging system described above, a diameter D of the focal spot 1 is set to D=1.5 mm, a distance L from the focal spot 1 to the detector plane 206a is set to L1=1000 mm, a thickness t of the restricting blade 3 is set to t=2 mm, and a distance L between the focal spot 1 and the restricting blade 3 is set to L2=75 m. An angle θ made by the end surface 4 of the restricting blade 3 and the normal line 2 in a movable range of the restricting blade 3 when the opening becomes the largest is set to θ=15° and a distance W from the connection side 8 of the end surface 4 of the restricting blade 3 to the normal line 2 is set to W=20 mm.
A width h1 of the eclipsed penumbra 9 and a width h2 of the attenuated penumbra 10 are obtained as follows by the Expression above: h1=8.5 mm and h2=0.23 mm, which satisfy the relationship h2≦0.18×h1. Therefore, unnecessary exposure has been reduced sufficiently.
According to the present invention, unnecessary exposure caused by X-ray which has passed through a portion at which thickness of the restricting blade is insufficient when the opening of the restricting blade is adjusted can be reduced by devising arrangement of the restricting blade.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2013-232708, filed Nov. 11, 2013 which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2013-232708 | Nov 2013 | JP | national |