JP2010118313A - X-ray source - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an X-ray source in which displacement of the focus of the X-rays is reduced. <P>SOLUTION: The support member 60 of the X-ray source 1 supports a load of an X-ray tube support part 6 by being fixed to the X-ray tube support part 6 in a state that an X-ray emitting window 27h is exposed on one end side of the X-ray tube support part 6, and is separated from the X-ray tube support part 6 on the other end side of the X-ray tube support part 6. With this structure, when the X-ray tube support part 6 is thermally expanded, the X-ray tube support part 6 is extended from the one end side to the other end side of the tube support part 6 with the fixed side of the support member 60 as a reference, and this extension margin can be escaped to a clearance S between the support member 60 and the X-ray tube support part 6. Thereby, the displacement amount of the focus of the X-rays can be made as small as possible. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention particularly relates to an X-ray source used as a microfocus X-ray source.

  Conventionally, there is JP, 2007-323898, A as a technique of such a field. An X-ray tube apparatus (X-ray source) described in this publication includes an X-ray tube having an envelope for making a cathode and an anode vacuum-tight, and emits X-rays to the envelope. An X-ray exit window is provided. Further, the X-ray tube device includes an insulating oil for holding the X-ray tube, a high voltage introduction unit for supplying power to the cathode and the anode, a tube container for housing the insulation oil and the high voltage introduction unit, and a tube container. And a support part for supporting the X-ray tube. And by fixing the rod-shaped anode to the envelope, even when the anode is thermally expanded at the time of X-ray generation and the anode is elongated in the longitudinal direction, the expansion of the envelope due to the thermal expansion causes the electrons on the target to expand. The amount of displacement of the focal point (X-ray focal point) can be suppressed.

JP 2007-323898 A Japanese Patent No. 3930770 JP 59-16254 JP-A-6-5381

  In the conventional X-ray source described above, it is possible to reduce the displacement of the focal point of the X-ray due to thermal expansion caused by the constituent members of the X-ray tube. On the other hand, since the heat generated in the X-ray tube is also transmitted to the tube container for fixing the X-ray tube, the tube container is also thermally expanded. As a result, the position of the X-ray tube itself is displaced, and accordingly, the focal point of the X-ray in the X-ray source is also displaced. As described above, in the displacement of the focal point of the X-ray in the X-ray source, the influence of the thermal expansion of the tube container cannot be ignored. In the conventional X-ray source, no consideration is given to the thermal expansion of the tube container, and it can be said that measures against the displacement of the focal point of the X-ray accompanying the thermal expansion of the tube container are insufficient. Accordingly, there is a problem that it is difficult to reduce the displacement of the focal point of the X-ray in the X-ray source.

  An object of this invention is to provide the X-ray source which reduced the displacement of the focus of X-ray | X_line.

The present invention provides an X-ray source including an X-ray tube having an X-ray emission window for emitting X-rays generated by electrons incident on a target to the outside.
An X-ray tube holding unit for holding the X-ray tube in a state where the X-ray exit window of the X-ray tube is exposed;
The X-ray tube holding part is fixed to the X-ray tube holding part with the X-ray exit window exposed at one end side to support the load of the X-ray tube holding part, and at the other end side of the X-ray tube holding part. And a support member that is spaced apart from the X-ray tube holding part.

  The support member of the X-ray source of the present invention is fixed to the X-ray tube holding portion with the X-ray exit window exposed at one end side of the X-ray tube holding portion, and supports the load of the X-ray tube holding portion. The other end side of the X-ray tube holding part is separated from the X-ray tube holding part. With such a configuration, when the X-ray tube holding portion is thermally expanded, the X-ray tube holding portion extends from one end side of the X-ray tube holding portion to the other end side with respect to the fixed side of the support member. This elongation can be released to the gap between the support member and the X-ray tube holding part. Therefore, the amount of displacement of the focus of X-ray can be made as small as possible.

Further, the support member is spaced apart from the other end surface of the X-ray tube holding portion and extends opposite to the other end surface, and one end side of the X-ray tube holding portion. An X-ray tube holding part, comprising: a second heat radiating part fixed to the surface; and a third heat radiating part having one end fixed to the first heat radiating part and the other end fixed to the second heat radiating part. Is preferably separated from the third heat radiating portion.
When such a configuration is adopted, the X-ray tube holding portion is surrounded by the first to third heat radiating portions in a substantially U-shape, and the X-ray tube holding portion due to thermal expansion toward the third heat radiating portion side. The elongation can also escape to the gap between the third heat radiating part and the X-ray tube holding part. This is effective in reducing the displacement of the focal point of the X-ray, coupled with an appropriate escape of the extension of the X-ray tube holding part due to the separation between the first heat radiation part and the X-ray tube holding part.

In addition, it is preferable that the X-ray tube holding portion, the first heat radiating portion, the second heat radiating portion, and the third heat radiating portion are thermally connected.
When such a configuration is adopted, the heat of the X-ray tube holding portion can be efficiently absorbed by the entire support member, and the heat dissipation efficiency of the X-ray tube can be improved by releasing this heat to the outside by the entire support member. . Therefore, it is effective in reducing the displacement of the focal point of X-rays.

In addition, it is preferable that thermally conductive grease is filled between the second heat radiating portion and the third heat radiating portion.
With such a configuration, the thermal conductivity from the second heat radiating portion to the third heat radiating portion can be increased, and the heat radiating ability of the third heat radiating portion can be fully utilized. Efficiency can be improved. Therefore, it is effective in reducing the displacement of the focal point of X-rays.

The X-ray tube includes a flange portion for fixing the X-ray tube to the X-ray tube holding portion, and the second heat radiating portion is fixed to one end side of the X-ray tube holding portion via the flange portion. It is preferable that
Since the flange portion is sandwiched between the second heat radiation portion and the X-ray tube holding portion, the heat generated by the X-ray tube is directly absorbed by the second heat radiation portion via the flange portion. By doing so, the heat dissipation efficiency of the X-ray tube can be improved.

In addition, it is preferable that thermally conductive grease is filled between the second heat radiating portion and the flange portion.
With such a configuration, the thermal conductivity from the flange portion of the X-ray tube to the second heat radiating portion can be enhanced. Therefore, the heat of the X-ray tube can be further easily transferred to the second heat radiating portion, and the heat dissipation efficiency of the X-ray tube can be further increased. Therefore, it is effective in reducing the displacement of the focal point of X-rays.

In addition, it is preferable that thermally conductive grease is filled between the second heat radiating portion and the X-ray tube holding portion.
With such a configuration, the thermal conductivity from the X-ray tube holding part to the second heat radiating part can be enhanced. Therefore, the heat of the X-ray tube holding part can be easily transferred to the second heat radiating part, and the heat radiation efficiency of the X-ray tube holding part itself can be increased.

In addition, the X-ray tube is provided with an X-ray emission window, a target accommodating portion that accommodates a target provided at an end of the rod-shaped anode, and an electron gun that accommodates an electron gun that emits electrons toward the target The housing portion is exposed from the X-ray tube holding portion, and the second heat radiating portion is provided with an opening for housing the target housing portion and the electron gun housing portion, and a wall surface that forms the opening portion, and the target housing portion Further, it is preferable that an X-ray shielding member is disposed between the electron gun housing portion and the electron gun housing portion.
By adopting the X-ray shielding member, even when there is X-rays emitted from other than the X-ray exit window, it can be prevented from leaking outside the X-ray source.

  According to the present invention, the displacement of the focal point of X-rays can be reduced.

  Hereinafter, preferred embodiments of an X-ray source according to the present invention will be described in detail with reference to the drawings.

  As shown in FIGS. 1 and 2, the X-ray source 1 used in an X-ray nondestructive inspection apparatus or the like emits X-rays generated after colliding electrons emitted from an electron gun with a target. An X-ray tube 27 having a structure for emitting light from the window to the outside is attached in a replaceable manner.

  An X-ray generation unit 5 for generating X-rays and a control unit 7 for electrically controlling the X-ray generation unit 5 are accommodated in the housing 3 of the X-ray source 1. . The internal space of the housing 3 is partitioned into an X-ray generation unit accommodation space R1 for accommodating the X-ray generation unit 5 and a control unit accommodation space R2 for accommodating the control unit 7, and the X-ray generation unit accommodation A partition wall 15 extending downward from the upper inner wall surface of the housing 3 is provided between the space R1 and the control unit accommodation space R2.

  As shown in FIG. 3, the X-ray generation unit 5 includes a power supply unit 17 for generating a high voltage, an X-ray tube 27 that receives power supply from the power supply unit 17 and emits X-rays, and a power supply unit 17 and a metal tube 29 that is an X-ray tube surrounding portion that surrounds a part of the X-ray tube 27. An X-ray for holding the X-ray tube 27 in a state in which the X-ray emission window 27h provided on the end surface on one end side of the X-ray tube 27 is exposed by integrating the power supply unit 17 and the metal tube 29. A tube holding unit 6 is configured.

  The power supply unit 17 connects the high voltage transformer 19 that can generate a high voltage, the high voltage supply circuit 23 that supplies the high voltage generated by the high voltage transformer 19 to the X-ray tube 27, and the high voltage transformer 19 and the high voltage supply circuit 23. A connection line 25a and a connection line 25b for connecting the high voltage supply circuit 23 and the X-ray tube 27 are provided.

  The high voltage supply circuit 23 and the connection lines 25a and 25b are molded in an insulating block 21 made of an electrically insulating material (for example, epoxy resin). The high-voltage transformer 19 protrudes from the side surface of the insulating block 21 toward the control unit 7 side. With such a structure of the power supply unit 17, it is possible to suppress discharge generated from the high voltage supply circuit 23 and the connection lines 25a and 25b to which a high voltage is continuously applied.

  The X-ray tube 27 is a reflection type target type, and closes a rod-shaped anode 27b provided with a target 27c at an end, a valve portion 27a to which the anode 27b is fixed, and an opening portion of the valve portion 27a. A target housing portion 27d that surrounds the target 27c, and an electron gun housing portion 27e that houses an electron gun 27k for emitting an electron beam toward the target 27c. For power feeding, the base end portion of the rod-shaped anode 27b protrudes from the valve portion 27a as a high voltage application portion 27g.

  The valve portion 27a and the target accommodating portion 27d are arranged coaxially with the tube axis L of the X-ray tube 27, and the electron gun accommodating portion axis P of the electron gun 27k is substantially orthogonal to the tube axis L. An X-ray emission axis R exists on L. That is, in the X-ray tube 27, the tube axis L and the X-ray emission axis R are coaxial. The X-ray emission axis R extends substantially orthogonal to the X-ray emission window 27h provided in the opening of the target accommodating portion 27d. That is, the X-ray tube 27 has an X-ray exit window 27h on one end side and a high voltage application portion 27g on the other end side along the tube axis L (or X-ray exit axis R).

  The lower part of the high voltage applying part 27g protruding from the valve part 27a is brought into contact with the socket 33 for supplying power to the anode 27b. The socket 33 is connected to the high voltage supply circuit 23 through the connection line 25 b of the power supply unit 17. With such a configuration, a high voltage is supplied to the X-ray tube 27 from the high voltage supply circuit 23 through the connection line 25b. When the electron gun 27k emits electrons toward the target 27c while the X-ray tube 27 is supplied with a high voltage, X-rays are generated from the target 27c, and the X-rays are provided in the target accommodating portion 27d. It is emitted from the X-ray emission window 27h.

  The X-ray tube 27 is a hermetically sealed type whose inside is sealed in a vacuum. For example, the X-ray tube 27 is provided with an exhaust pipe (not shown), and after the inside of the valve portion 27a, the target storage portion 27d, and the electron gun storage portion 27e is evacuated, the exhaust pipe is connected to the X-ray tube 27. By sealing, the X-ray tube 27 is sealed.

  A metal tube 29 surrounding the valve portion 27 a of the X-ray tube 27 protrudes upward from the upper surface of the power supply unit 17 and is formed in a cylindrical shape surrounding the X-ray tube 27. The metal tube 29 is made of a metal (for example, aluminum) having excellent heat dissipation properties and has a plurality of cooling fins 29a protruding from the outer peripheral surface in order to efficiently dissipate heat generated from the X-ray tube 27. Yes. The cooling fin 29a expands the surface area of the metal tube 29, and can efficiently dissipate heat generated from the X-ray tube 27.

  An opening 29j is formed in the upper end surface of the metal tube 29, and a valve portion 27a of the X-ray tube 27 is inserted through the opening 29j. Insulating oil that is a liquid electrical insulating material is inserted into the internal space of the metal tube 29. 31 is satisfied. The target accommodating portion 27d of the X-ray tube 27 is provided with a flange portion 27f. The flange portion 27f is located on the opening 29j side of the metal tube 29 and extends perpendicularly to the X-ray emission axis R. It is being fixed to the attachment surface 29b (refer FIG. 7) which is the surface of the existing one end side (X-ray emission window 27 side) of the X-ray tube holding | maintenance part 6. FIG.

  Since the flange portion 27f is fixed to the mounting surface 29b by the screw 32 (see FIG. 6) in a state where the valve portion 27a of the X-ray tube 27 is immersed in the insulating oil 31 filled in the internal space of the metal tube 29, the insulating portion 31 is insulated. Oil 31 does not leak out and discharge from the X-ray tube 27 to the outside is prevented.

  Next, the control unit 7 will be described.

  As shown in FIGS. 1 and 4, the control unit 7 is provided in the control unit accommodating space R <b> 2 and includes a first circuit board 35, a second circuit board 37, and a drive power supply unit 39. The first circuit board 35 controls the voltage that can be generated by the power supply unit 17 from a high voltage (for example, 160 kV) to a low voltage (for example, 0 V). Further, the first circuit board 35 controls the emission timing, tube voltage, tube current, etc. of the electron gun housing portion 27e. The second circuit board 37 controls the operation of the first circuit board 35 based on a control signal from the outside.

  The drive power supply unit 39 is a converter that performs AC / DC conversion (or DC / DC conversion) on electric power supplied from the outside, and supplies drive power to the first circuit board 35 and the second circuit board 37 and X-rays. Electric power for generating a high voltage is supplied to the high voltage transformer 19 of the generator 5. Note that the first circuit board 35, the second circuit board 37, the drive power supply unit 39, and the X-ray generation unit 5 are electrically connected to each other by wiring (not shown).

  In the control unit 7, in order to accommodate the first circuit board 35, the second circuit board 37, and the drive power supply unit 39 in the control unit accommodation space R2, the control unit 7 includes a heat conductive metal. A circuit board holder 49 made of (for example, aluminum) is provided, and the circuit board holder 49 has a mountain shape to hold the first circuit board 35, the second circuit board 37, and the drive power supply unit 39 at appropriate positions. It has become.

  The circuit board holder 49 includes a first plate 45 made of a heat conductive metal and a second plate 47 screwed to the first plate 45. The first plate 45 has a first flat plate portion 46 that is inclined and raised with respect to the bottom plate (second heat radiating portion) 61 of the housing 3, and the second plate 47 is formed with respect to the bottom plate 61. And a second flat plate portion 48 that is erected substantially vertically. The lower ends of the first plate 45 and the second plate 47 are fixed to the bottom plate 61 by screws 49a, and are connected by screws 49b with the upper ends overlapped.

  The lower portion of the second plate 47 is bent in an L shape so as to approach the side wall 3 f of the housing 3, and the high voltage transformer 19 of the power supply unit 17 is interposed between the second plate 47 and the first plate 45. It is supposed to be located.

  If the X-ray tube 27 generates heat during the operation of the X-ray source 1, the X-ray tube 27 and the metal tube 29 become high temperature. The heat generated by the X-ray tube 27 increases as the output of the X-ray irradiation increases. If the temperature of the X-ray tube 27 becomes high, other parts are adversely affected and the output of the X-ray tube 27 is reduced. In order to cool the X-ray tube 27 efficiently, it is necessary to cool the metal tube 29 efficiently.

  Therefore, in the X-ray source 1, as shown in FIG. 1, a cooling fan unit 55 is fixed to the side wall 3 b that stands in a direction orthogonal to the bottom plate 61 of the housing 3, and cooling air is blown in the housing 3. The metal tube 29 is rapidly cooled by forcibly flowing.

  As shown in FIGS. 2 and 4, the upper wall 3c of the housing 3 extends in parallel with the bottom plate 61, and is provided with an opening (irradiation unit) 3j for exposing the X-ray exit window 27h. Moreover, in the housing | casing 3, the wall which connects the upper wall 3c and the side wall 3b is formed as the inclined wall 3d. Similarly, the wall connecting the side wall 3f facing the side wall 3b and the upper wall 3c is also an inclined wall 3e.

  As shown in FIG. 1, the cooling fan unit 55 is provided on the side wall 3b of the housing 3 as described above, and has the cooling fan 55a that rotates about an axis perpendicular to the side wall 3b. By driving the cooling fan 55a, air flows into the X-ray generation unit accommodating space R1 from the outside to the inside of the housing 3. The cooling fan 55 a is disposed in the vicinity of the X-ray generator 5 so that the cooling air directly hits the X-ray generator 5.

  The air taken into the housing 3 by the cooling fan 55a flows in the X-ray generation unit accommodating space R1 as cooling air, and hits the metal tube 29 having the cooling fins 29a evenly, while the metal tube 29 It will flow along the side wall 3f while passing around. Then, the cooling air passing around the metal tube 29 is guided by the cooling fins 29a and smoothly flows in the horizontal direction, and contacts the metal tube 29 with a sufficient contact area, and efficiently heats from the metal tube 29. Remove it. As a result, the metal tube 29 is efficiently cooled, and the X-ray tube 27 surrounded by the metal tube 29 can be efficiently cooled. And since the metal cylinder 29 contacts the cooling air without any unevenness and is cooled, it is possible to suppress output fluctuation and output decrease due to temperature unevenness of the X-ray tube 27. The cooling air that has received heat from the metal tube 29 and has increased in temperature is discharged to the outside through the exhaust port 3k provided in the inclined wall 3e.

  Further, the drive power supply unit 39 generates a large amount of heat when performing AC / DC conversion (or DC / DC conversion), and thus needs to be efficiently cooled. Therefore, the partition wall 15 in the housing 3 does not completely partition the X-ray generation unit accommodation space R1 and the control unit accommodation space R2, but below the partition wall 15, the X-ray generation unit accommodation space R1 and the control unit. A ventilation port 59 is provided for communicating with the accommodation space R2.

  Thus, since the partition between the metal cylinder 29 and the control unit 7 is partitioned by the partition wall 15, the cooling air that has become high temperature after the cooling of the metal cylinder 29 flows directly into the control unit accommodating space R2. Can be suppressed. Further, it is possible to suppress the radiant heat generated from the metal cylinder 29 from being blocked by the partition wall 15 and directly transmitted to the control unit 7. As a result, the temperature rise of the control unit 7 can be suppressed, and the operations of the circuit boards 35 and 37 of the control unit 7 can be stabilized. At the same time, since the X-ray generation unit accommodation space R1 and the control unit accommodation space R2 are communicated with each other by the ventilation port 59 located on the lower side, a part of the cooling air generated by the cooling fan 55a located on the lower side. Can easily flow into the control unit accommodating space R2 through the ventilation port 59, and the control unit 7 can be cooled by the cooling air.

  As shown in FIGS. 2 and 5, the X-ray tube holder 6 of the X-ray source 1 is housed in the X-ray generator housing space R1 in a suspended state. In order to achieve this, a support member 60 is employed in the X-ray source 1.

  As shown in FIG. 8, when thermal expansion occurs in the X-ray tube holding unit 6, if the power supply unit 17 is fixed to the bottom plate 61 with screws or the like, the X-ray emission axis R direction (direction perpendicular to the bottom plate 61). The thermal expansion of the X-ray tube holding part 6 to) acts in a direction in which the X-ray tube 27 is separated from the bottom plate 61. That is, on the X-ray emission axis R, the X-ray tube 27 is greatly displaced upward, that is, toward the X-ray irradiation object, and as a result, the X-ray focal point is similarly displaced. As a result, the positional relationship between the X-ray focal point and the X-ray irradiation target changes, and it becomes difficult to obtain a stable X-ray transmission image. This is a particular problem when irradiating for a long time, when used for position determination, or when used for CT.

  Therefore, as shown in FIGS. 3 and 5, in the extending direction of the X-ray emission axis R of the X-rays emitted from the X-ray emission window 27 h, the support member 60 is located at one end side of the X-ray tube holding unit 6. The X-ray tube holding portion 6 is fixed to the X-ray tube holding portion 6 with the X-ray exit window 27h exposed to support the load of the X-ray tube holding portion 6, and the X-ray tube holding portion on the other end side of the X-ray tube holding portion 6 6 apart.

  With such a configuration, when the X-ray tube holding portion 6 is thermally expanded, the X-ray tube holding portion 6 extends in the extending direction of the X-ray emission axis R with reference to the fixed surface side of the support member 60. The elongation is released to the gap S between the support member 60 and the X-ray tube holding unit 6. Therefore, the displacement of the X-ray focal point on the X-ray emission axis R can be made as small as possible. This is more effective as the X-ray output becomes higher.

  On the other hand, thermal expansion of the X-ray tube holding unit 6 also occurs in a direction perpendicular to the X-ray emission axis R of the X-ray tube holding unit 6. Also in this case, the side plate 63 and the casing 3 surrounding the side surface of the X-ray tube holding unit 6 are spaced apart from the side surface of the X-ray tube holding unit 6 so as to have a gap S ′. To escape. Therefore, similarly, the displacement of the focal point of the X-ray in the direction perpendicular to the X-ray emission axis R can be made as small as possible.

  The support member 60 made of a material having high thermal conductivity (for example, aluminum) is spaced apart from the flat surface portion 17a that forms the bottom surface of the power supply portion 17 extending perpendicularly to the X-ray emission axis R, and faces the flat surface portion 17a. A first heat dissipating part (bottom plate) 61, a second heat dissipating part 62 fixed to a mounting surface 29b (see FIG. 7) of the metal tube (X-ray tube surrounding part) 29, and an X-ray emission A third heat radiating portion (side plate) 63 that extends in parallel to the axis R, has one end fixed to the first heat radiating portion 61 with a screw and the other end fixed to the second heat radiating portion 62 with a screw. And consist of Each of the heat radiating portions is thicker than the plate material constituting the housing 3 and uses a member having excellent strength and heat capacity. The metal tube 29, the first heat radiating portion 61, the second heat radiating portion 62, and the third heat radiating portion 63 are thermally connected.

  As described above, the X-ray tube holding portion 6 is surrounded by the first to third heat radiating portions 61 to 63 in a substantially U-shape, thereby increasing the heat capacity of the support member 60 and increasing the heat dissipation efficiency of the support member 60. Can be raised. This is combined with an appropriate escape of the extension of the X-ray tube holding part 6 due to the gap S between the first heat radiating part 61 and the flat part 17a of the power supply part 17, and thus the displacement of the X-ray focal point is reduced. It is effective. Furthermore, since the support member 60 also has a large surface area, it can be cooled very efficiently by the cooling fan 55a, so that the cooling efficiency of the X-ray tube 27 can be improved. Furthermore, since the first and third heat radiating portions 61 and 63 are exposed to the atmosphere outside the X-ray source 1, the heat radiating effect is high.

  The first heat radiating portion 61 extends in a flat plate shape, and is separated from the flat portion 17 a of the power source portion 17 by a gap S. The gap S is about 0.5 considering the material of the X-ray tube holding portion 6. About millimeters are suitable and are sufficient to absorb the amount of thermal expansion of the X-ray tube holder 6.

  As shown in FIG. 5 to FIG. 7, the second heat radiating portion 62 constitutes a heat sink that is thicker than the first heat radiating portion 61 and the third heat radiating portion 63, and the screw 32 a of the metal tube 29. It is fixed to the mounting surface 29b. Specifically, in a state where the flange portion 27f is sandwiched between the second heat radiating portion 62 and the metal tube 29, a first through hole provided in the second heat radiating portion 62 and through which the screw 32a is inserted, and the flange portion The second through hole provided in 27f and through which the screw 32a is inserted is aligned, and then both are fixed to the mounting surface 29b of the metal tube 29 by the screw 32a.

  In this manner, the flange portion 27f is sandwiched between the second heat radiating portion 62 and the mounting surface 29b of the metal tube 29, and the flange portion 27f and the second heat radiating portion 62 are firmly pressed by the screws 32a. Therefore, the heat generated in the X-ray tube 27 is directly absorbed by the second heat radiating portion 62 via the flange portion 27f. Therefore, the heat dissipation efficiency of the X-ray tube 27 can be increased. That is, the flange portion 27 f not only serves as a fixing member for fixing the X-ray tube 27 to the mounting surface 29 b of the metal tube 29, but also transmits heat generated by the X-ray tube 27 to the second heat radiating portion 62. It is also used as a heat transfer member. In order to ensure heat transfer, after the heat conductive grease 67 is filled between the flange portion 27f and the second heat radiating portion 62, the flange portion 27f and the second heat radiating portion 62 are (See FIG. 7).

  Further, the flange portion 27 f is fixed to the attachment surface 29 b by the screw 32, whereby the X-ray tube 27 is fixed to the metal tube 29. Furthermore, the slit part 62a is formed in the 2nd thermal radiation part 62 so that the head of the screw | thread 32 for fixing the flange part 27f to the attachment surface 29b may be avoided. The slit portion 62 a can prevent the head of the screw 32 from being crushed while enhancing the heat dissipation effect due to the surface area expansion of the second heat dissipation portion 62.

  As shown in FIG. 5, between the second heat radiating portion 62 and the third heat radiating portion 63 screwed to each other, the heat conductive grease 66 is filled, and the heat conductive grease 66 causes the second heat radiating portion 66 to be filled with the second heat radiating portion 66. The heat radiating part 62 and the third heat radiating part 63 are efficiently and thermally connected. With such a configuration, the thermal conductivity from the second heat radiating portion 62 to the third heat radiating portion 63 can be enhanced, and the heat radiating ability of the third heat radiating portion 63 can be fully utilized. In particular, since the second heat dissipating part 62 is a block heat sink, the area of the joint part with the third heat dissipating part 63 is increased, which can be said to be an extremely effective means.

  As shown in FIG. 7, between the 2nd thermal radiation part 62 and the flange part 27f, the heat conductive grease 67 is filled. Thereby, the 2nd thermal radiation part 62 and the flange part 27f can be thermally connected efficiently, and the thermal conductivity from the flange part 27f of the X-ray tube 27 to the 2nd thermal radiation part 62 can be improved. Therefore, the heat of the X-ray tube 27 can be easily transferred to the second heat radiating portion 62, and the heat dissipation efficiency of the X-ray tube 27 can be increased.

  Further, the heat conductive grease 68 is also filled between the second heat radiating portion 62 and the mounting surface of the X-ray tube surrounding portion. Thereby, the metal cylinder 29 and the 2nd heat radiating part 62 can also be thermally connected efficiently, and the thermal conductivity from the metal cylinder 29 to the 2nd heat radiating part 62 can be improved. Therefore, the heat of the metal cylinder 29 can be easily transmitted to the second heat radiating portion 62, and the heat dissipation efficiency of the metal cylinder 29 itself can be increased. As a result, the heat radiation efficiency of the X-ray tube 27 can be increased.

  As shown in FIGS. 6 and 7, the second heat dissipating part 62 is provided with an opening 69 for accommodating the target accommodating part 27d and the electron gun accommodating part 27e, a wall surface forming the opening 69, and the target accommodating An X-ray shielding member 70 made of lead is disposed between the portion 27d and the electron gun housing portion 27e. The X-ray shielding member 70 is fixed to the target accommodating portion 27d with a screw 71. By adopting the X-ray shielding member 70, even if there is an unintended X-ray emitted from a portion other than the X-ray exit window 27h, for example, the target accommodating portion 27d and the electron gun accommodating portion 27e, this is the X-ray shielding member. By being shielded by 70, unintended leakage of X-rays to the outside of the X-ray source 1 can be suppressed.

  Further, the X-ray exit window 27 h is slightly protruded from the second heat radiating portion 62. This protruding amount corresponds to the thickness of the upper wall 3c of the housing 3. If the X-ray exit window 27h is in a position retracted from the upper wall 3c, the X-ray irradiation object cannot be brought close to the X-ray exit window 27h. Further, if the X-ray exit window 27h is protruded too much from the upper wall 3c, the risk of damage to the X-ray exit window 27h increases. Therefore, the X-ray exit window 27h is preferably flush with the surface of the upper wall 3c of the housing 3.

  It goes without saying that the present invention is not limited to the embodiment described above.

  For example, as shown in FIG. 9, in the X-ray source 80, the flange portion 81a of the X-ray tube 81 is fixed to the mounting surface 82a of the metal tube (X-ray tube surrounding portion) 82A of the X-ray tube holding portion 82 with screws. The second heat radiating portion 83 is fixed to the mounting surface 82a with screws via the flange portion 81a.

  A gap is provided between the power supply unit 82B of the X-ray tube holding unit 82 and the first heat radiating unit 84, and the first heat radiating unit 84 has a box shape and accommodates a circuit board therein. . One end of the third heat radiating portion 85 is fixed to the end portion of the second heat radiating portion 83 with a screw, and the other end of the third heat radiating portion 85 is fixed to the end portion of the first heat radiating portion 84 with a screw. Yes. And the 3rd thermal radiation part 85 supports the load of the 2nd thermal radiation part 83 and the X-ray generation part 86 by making two parallel sheets into one set. The second and third heat radiation portions 83 and 85 are exposed to the outside, and the heat radiation effect is enhanced. In addition, you may expose the 1st-3rd thermal radiation parts 83-85 outside.

  The second heat radiation part 83 is provided with a circular opening 83a for exposing the X-ray emission window 81b, and there is almost no gap between the wall surface of the opening 83a and the target accommodating part 81c. Reference numeral 90 denotes a cooling fan unit.

  The X-ray tube 27 is a reflective target type, but may be a transmissive target type. In this case, since the target is provided on the back surface of the X-ray exit window, there is almost no movement of the X-ray focal point due to thermal expansion of the target itself, and the X-ray focal point is reduced by reducing the thermal expansion of the X-ray tube holder. The effect of reducing displacement is high.

  The X-ray tube 27 is provided with the X-ray emission window 27h so that the tube axis and the X-ray emission axis R substantially coincide with each other. However, the X-ray emission window 27h so that the tube axis and the X-ray emission axis R intersect with each other. May be provided. In this case as well, the displacement of the focal point of the X-ray can be reduced by reducing the thermal expansion of the X-ray tube holding part.

1 is a perspective view showing an embodiment of an X-ray source according to the present invention. It is a front view of the X-ray source shown by FIG. It is sectional drawing of the X-ray tube generation | occurrence | production part shown by FIG. It is sectional drawing of the control part shown by FIG. It is a front view which shows an X-ray tube holding | maintenance part and a supporting member. It is a top view which shows the 2nd thermal radiation part of a supporting member. It is a principal part expanded sectional view of FIG. It is sectional drawing which shows the expansion | swelling state of a X-ray generation part. It is a perspective view which shows other embodiment of the X-ray source which concerns on this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1,80 ... X-ray source, 5 ... X-ray generation part, 6,82 ... X-ray tube holding part, 17, 82B ... Power supply part, 17a ... Plane part, 27 ... X-ray tube, 27b ... Anode, 27c ... Target , 27d: target housing portion, 27e: electron gun housing portion, 27f, 81a ... flange portion, 27h, 81b ... X-ray emission window, 29, 82A ... X-ray tube surrounding portion, 29b, 82a ... mounting surface, 60 ... support Member, 61, 84 ... 1st heat radiating part, 62, 83 ... 2nd heat radiating part, 63, 85 ... 3rd heat radiating part, 66, 67, 68 ... thermally conductive grease, 69 ... opening part, 70 ... X-ray shielding member, R ... X-ray emission axis, S ... gap.

Claims (8)

In an X-ray source including an X-ray tube having an X-ray exit window for emitting X-rays generated by electrons incident on a target to the outside,
An X-ray tube holding unit for holding the X-ray tube in a state where the X-ray emission window of the X-ray tube is exposed;
The X-ray tube holding part is fixed to the X-ray tube holding part with the X-ray exit window exposed at one end side of the X-ray tube holding part to support the load of the X-ray tube holding part, and the X-ray tube holding part And a support member that is spaced apart from the X-ray tube holding portion on the other end side of the X-ray source. The support member is
A first heat dissipating part extending away from the other end side surface of the X-ray tube holding unit and facing the other end side surface;
A second heat dissipating part fixed to the one end side surface of the X-ray tube holding part;
One end is fixed to the first heat radiating portion, and the other end is fixed to the second heat radiating portion, and a third heat radiating portion,
The X-ray source according to claim 1, wherein the X-ray tube holding unit is separated from the third heat radiating unit.   3. The X-ray source according to claim 2, wherein the X-ray tube holding part, the first heat radiating part, the second heat radiating part, and the third heat radiating part are thermally connected. .   The X-ray source according to claim 3, wherein thermally conductive grease is filled between the second heat radiating portion and the third heat radiating portion. The X-ray tube includes a flange portion for fixing the X-ray tube to the X-ray tube holding portion,
The X-ray source according to any one of claims 2 to 4, wherein the second heat radiating part is fixed to one end side of the X-ray tube holding part via the flange part.   The X-ray source according to claim 5, wherein thermally conductive grease is filled between the second heat radiation portion and the flange portion.   The X-ray source according to any one of claims 3 to 5, wherein thermally conductive grease is filled between the second heat radiating portion and the X-ray tube holding portion. The X-ray tube is
The X-ray emission window is provided, and a target storage unit that stores the target provided at an end of a rod-shaped anode,
An electron gun housing portion that houses an electron gun that emits electrons toward the target, and is exposed from the X-ray tube holding portion;
The second heat radiating part is provided with an opening for accommodating the target accommodating part and the electron gun accommodating part,
The X-ray shielding member is arrange | positioned between the wall surface which forms the said opening part, the said target accommodating part, and the said electron gun accommodating part, The Claim 1 characterized by the above-mentioned. X-ray source.

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