JP5931501B2 - X-ray tube device - Google Patents

Description

  Embodiments described herein relate generally to an X-ray tube apparatus.

  X-ray tube apparatuses are used in many applications such as medical diagnostic equipment. The X-ray tube device operates by being supplied with a high voltage from a high voltage generator via a high voltage cable. A plug as a high voltage connector is provided at the tip of the high voltage cable. The plug is electrically connected to a receptacle provided in the housing of the X-ray tube apparatus.

  The high voltage connector is electrically connected to a high voltage supply terminal on the X-ray tube side, and is detachably attached to the high voltage insulating member. A high voltage is supplied to the cathode or anode target of the X-ray tube via the high voltage connector and the high voltage supply terminal.

  As a high voltage connector, there is known a high voltage connector that is attached to a high voltage insulating member of an X-ray tube by applying pressure. By applying pressure, the air layer is removed from between the electrically insulating rubber portion of the high-voltage connector and the high-voltage insulating member of the X-ray tube, and the surfaces of each other are firmly adhered to each other. As a result, it is possible to cut off the discharge along the adhesion interface.

US Patent No. 70000662 US Pat. No. 6,556,654

  When a plug as a high voltage connector is used as described above, the receptacle needs to have a sufficient length along the direction in which the plug of the high voltage cable is inserted to ensure electrical insulation. Since the receptacle extends between the X-ray tube and the housing, there is a problem that the X-ray tube device cannot be reduced in size.

  On the other hand, by using a surface pressure type high voltage connector as described above, the X-ray tube apparatus can be made smaller than when a receptacle is used for high voltage insulation. However, when the high voltage connector is used, if the heat generation of the X-ray tube increases, the function of releasing the heat transmitted from the cathode or anode target is limited. Then, for example, the electrically insulating rubber portion of the high voltage connector is deformed beyond the allowable temperature, and the adhesion between the electrically insulating rubber portion of the high voltage connector and the high voltage insulating member of the X-ray tube is reduced. . As a result, there is a problem that discharge along the adhesion interface between the electrically insulating rubber portion and the high voltage insulating member occurs relatively early.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an X-ray tube apparatus that can be miniaturized and can obtain high reliability over a long period of time.

An X-ray tube apparatus according to one embodiment
A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an electron provided in the vacuum envelope for emitting the irradiation to the anode target An X-ray tube, and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode;
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
Has an electrically insulating material which is in close contact directly or indirectly on the end face of the electrical insulating member, Bei example and a high-voltage connector which gives a high voltage to the second high voltage supply terminal,
The electrical insulation member has another high voltage insulation member having the end face, and an electrical insulation member,
The other high-voltage insulating member has a hole that opens to the inside of the housing and exposes the second high-voltage supply terminal,
The other end of the high voltage cable is electrically connected to the second high voltage supply terminal through the hole,
The electrical insulating member is filled in the hole portion and fills the second electrical connection portion .

FIG. 1 is a cross-sectional view showing an X-ray apparatus according to the first embodiment. FIG. 2 is a cross-sectional view showing an X-ray apparatus according to the second embodiment. FIG. 3 is a cross-sectional view showing a modification of the X-ray apparatus according to the second embodiment. FIG. 4 is a cross-sectional view showing an X-ray apparatus according to the third embodiment. FIG. 5 is a sectional view showing an X-ray apparatus according to the fourth embodiment. FIG. 6 is an exploded cross-sectional view showing a part of the X-ray apparatus shown in FIG. FIG. 7 is a cross-sectional view showing an X-ray apparatus according to the fifth embodiment. FIG. 8 is a cross-sectional view showing an X-ray apparatus according to the seventh embodiment. FIG. 9 is a cross-sectional view showing an X-ray apparatus according to the eighth embodiment. FIG. 10 is a schematic view showing the X-ray apparatus according to the eighth embodiment, and is a view showing the X-ray apparatus viewed from the receptacle side. FIG. 11 is a schematic view showing a modified example of the X-ray apparatus according to the eighth embodiment, and is a view showing the X-ray apparatus viewed from the receptacle side. FIG. 12 is a schematic view showing another modified example of the X-ray apparatus according to the eighth embodiment, and is a view showing the X-ray apparatus viewed from the receptacle side. FIG. 13 is a schematic view showing another modification of the X-ray apparatus according to the eighth embodiment, and is a view showing the X-ray apparatus viewed from the receptacle side. FIG. 14 is a cross-sectional view showing Comparative Example 1 of the X-ray apparatus according to the above-described embodiment. FIG. 15 is a cross-sectional view showing a comparative example 2 of the X-ray apparatus according to the above-described embodiment.

Hereinafter, the X-ray apparatus according to the first embodiment will be described in detail with reference to the drawings. FIG. 1 is a cross-sectional view showing an X-ray apparatus according to the first embodiment.
As shown in FIG. 1, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a cooler 22, a high voltage connector 100, and a high voltage connector 200.

  The X-ray tube apparatus 10 includes a housing 20, an X-ray tube 30 accommodated in the housing 20, and a coolant filled in the housing 20 and filled in a space between the X-ray tube 30 and the housing 20. 7, a stator coil 910 as a rotational drive device, a cable assembly 60, a cable assembly 70, an electrically insulating member 81, and an electrically insulating member 91.

  The housing 20 has two divided parts 20a and 20c which are divided. The division part 20a has a frame part 20b on the outer edge side of the opening end. The division part 20c has a frame part 20d on the outer edge side of the opening end. The frame portion 20d is formed with a frame-like groove portion formed on the side facing the frame portion 20b.

  The division parts 20a and 20c are brought into contact with each other so that the frame parts 20b and 20d face each other, and are fastened by a fastener (not shown). The gap between the frame part 20b and the frame part 20d is liquid-tightly sealed by a frame-shaped O-ring provided in the groove part. The O-ring has a function of preventing the coolant 7 from leaking outside the housing 20.

  The inner surface of the housing 20 is in contact with the coolant 7. The housing 20 is provided with a rubber bellows 21 to adjust the pressure of the coolant 7. The housing 20 has an X-ray emission window 20w that transmits X-rays and emits the X-rays to the outside. The housing 20 has an opening 20o1 and an opening 20o2.

  The X-ray tube 30 includes a vacuum envelope 31. The vacuum envelope 31 has a vacuum container 32. The vacuum container 32 is made of nonmagnetic metal such as glass, copper, stainless steel, or aluminum, for example. The X-ray radiation window 33 is provided in the vacuum container 32 in an airtight manner. Here, the X-ray emission window 33 is made of beryllium. A part of the vacuum envelope 31 is formed of a high voltage insulating member 40 and a high voltage insulating member 50. In this embodiment, the high voltage insulating member 40 and the high voltage insulating member 50 are formed of ceramics.

  The X-ray tube 30 has a high voltage supply terminal 44, a high voltage supply terminal 54, an anode target 35, and a cathode 36. In this embodiment, the high voltage supply terminal 44 and the high voltage supply terminal 54 are metal terminals. The high voltage supply terminal 44 is exposed to the outside of the vacuum envelope 31 from the outer surface of the high voltage insulating member 40 and is electrically connected to the anode target 35. The high voltage supply terminal 54 is exposed from the outer surface of the high voltage insulating member 50 to the outside of the vacuum envelope 31 and is electrically connected to the cathode 36.

  The anode target 35 is provided in the vacuum envelope 31. The anode target 35 is formed in a disc shape. The anode target 35 has a target layer 35a provided on a part of the outer surface of the anode target. The target layer 35a emits X-rays when electrons irradiated from the cathode 36 collide. The anode target 35 is made of a metal such as molybdenum. The target layer 35a is formed of a metal such as molybdenum, a molybdenum alloy, or a tungsten alloy. The anode target 35 can rotate around the tube axis.

  The cathode 36 is provided in the vacuum envelope 31. The cathode 36 emits electrons that irradiate the anode target 35. A relatively negative voltage is applied to the cathode 36. The KOV member 55, which is a low expansion alloy, covers the high voltage supply terminal 54 in the vacuum envelope 31. Here, the high voltage supply terminal 54 and the high voltage insulating member 50, and the KOV member 55 and the high voltage insulating member 50 are brazed. A cathode support member 37 is attached to the KOV member 55. The cathode 36 is attached to a cathode support member 37.

  The high voltage supply terminal 54 is connected to the cathode 36 through the inside of the cathode support member 37. The high voltage supply terminal 54 applies a relatively negative voltage to the cathode 36 and supplies a filament current to a filament (electron emission source) (not shown) of the cathode 36.

  The X-ray tube 30 includes a rotor 920, a bearing 930, a fixed body 1, and a rotating body 2. The fixed body 1 is formed in a columnar shape and is fixed to the high voltage insulating member 40. A high voltage supply terminal 44 is electrically connected to the fixed body 1. Here, the fixed body 1 is formed integrally with the high voltage supply terminal 44. The fixed body 1 supports the rotating body 2 in a rotatable manner. The rotating body 2 is formed in a cylindrical shape and is provided coaxially with the fixed body 1. A rotor 920 is attached to the outer surface of the rotating body 2. An anode target 35 is attached to the rotating body 2. The bearing 930 is formed between the fixed body 1 and the rotating body 2. The rotating body 2 is provided so as to be rotatable together with the anode target 35. The high voltage supply terminal 44 applies a relatively positive voltage to the anode target 35 via the fixed body 1, the bearing 930, and the rotating body 2.

  The cable assembly 60 includes a high voltage cable 61, a high voltage connector 62, and a fixing member 67. The high voltage connector 62 includes an electrically insulating member 64 as an electrically insulating member, a mounting ring 66, and a high voltage supply terminal 69.

  One end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 44, and the other end is electrically connected to the high voltage supply terminal 69 through the space in the housing 20. The high voltage supply terminal 69 is exposed to the outside of the housing 20 through the opening 20o1. For connection between the high voltage supply terminal 44 and the high voltage cable 61 and connection between the high voltage supply terminal 69 and the high voltage cable 61, welding, soldering, or the like can be used.

  The high voltage connector 62 is provided at the other end of the high voltage cable 61. The attachment ring 66 is made of a highly rigid material such as metal. The shape of the attachment ring 66 is a shape corresponding to the opening 20o1. The attachment ring 66 is located in the opening 20o1.

  An annular groove is formed in the opening 20o1. A gap between the mounting ring 66 and the opening 20o1 is sealed by an annular O-ring provided in the groove portion. The O-ring has a function of preventing the coolant 7 from leaking out of the housing 20 from the gap between the mounting ring 66 and the opening 20o1. The O-ring is made of resin or rubber.

  The electrically insulating member 64 has an end face 64s exposed to the outside of the housing 20 through the opening 20o1. Here, the end face 64s is a flat surface. The high voltage supply terminal 69 protrudes from the end face 64 s to the outside of the housing 20. The electrically insulating member 64 covers the electrical connection between the high voltage supply terminal 69 and the high voltage cable 61 and is cooled by the coolant 7. In this embodiment, the electrically insulating member 64 is formed of an electrically insulating resin, fills up the electrical connection between the high voltage supply terminal 69 and the high voltage cable 61, and directly on the inner peripheral surface of the mounting ring 66. It is glued.

  More specifically, the electrically insulating member 64 is formed of a molding material. When the electrically insulating member 64 is formed, the high voltage supply terminal 69 and the high voltage cable 61 are electrically connected in advance. When the formation of the electrical insulating member 64 starts, first, an electrical connection portion between the high voltage supply terminal 69 and the high voltage cable 61, and a high voltage are formed inside a mold material tank (not shown) partially formed by the mounting ring 66. A part of the voltage cable 61 is carried in, and the molding material is injected into the molding material tank. Thereafter, the injected molding material is cured, and the cured molding material is carried out from the molding material tank together with the mounting ring 66. Thereby, the electrically insulating member 64 to which the attachment ring 66 is bonded is formed.

  In addition, when inject | pouring a molding material, injection | pouring in a vacuum is preferable and it is preferable to carry out inside the vacuum chamber which is not shown in figure. By injecting the molding material in a vacuum, air bubbles such as air that may remain in the molding material can be prevented from remaining.

  Further, the attachment ring 66 may not form a part of the mold material tank. In this case, the attachment ring 66 may be indirectly bonded to the electrical insulating member 64 via an adhesive member (not shown). However, the adhesive member provides a liquid-tight seal between the mounting ring 66 and the electrically insulating member 64.

  The fixing member 67 is formed in an annular shape. The screw passes through a through hole formed in the fixing member 67 and is tightened in a screw hole formed in the attachment ring 66. The other screws pass through other through holes formed in the fixing member 67 and are tightened into screw holes formed in the housing 20. Thereby, the position of the high voltage connector 62 with respect to the housing 20 can be fixed.

  The electrically insulating member 81 covers the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61, is surrounded by the coolant 7, and is cooled directly or indirectly by the coolant 7.

  In this embodiment, the high voltage supply terminal 44 is formed outside the vacuum envelope 31 so as to protrude from the outer surface of the high voltage insulating member 40. The electrically insulating member 81 is formed of an electrically insulating resin, fills up the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61, and is directly bonded to the outer surface of the high voltage insulating member 40. The electrically insulating member 81 is surrounded by the coolant 7 and directly cooled by the coolant 7 in the vicinity of the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61.

  More specifically, the electrically insulating member 81 is formed of a molding material. When the electrically insulating member 81 is formed, the high voltage supply terminal 44 and the high voltage cable 61 are electrically connected in advance. When the formation of the electrical insulating member 81 starts, first, the outer surface of the high-voltage insulating member 40, the electrical connection portion between the high-voltage supply terminal 44 and the high-voltage cable 61, and the high-voltage cable are placed inside a mold material tank (not shown) A part of 61 is carried in, and a mold material is injected into the mold material tank. Thereafter, the injected mold material is cured, and the cured mold material is carried out of the mold material tank. Thereby, the electrically insulating member 81 is formed. In addition, when inject | pouring a molding material, injection | pouring in a vacuum is preferable.

  The cable assembly 70 includes a high voltage cable 71, a high voltage connector 72, and a fixing member 77. The high voltage connector 72 includes an electrically insulating member 74 as an electrically insulating member, a mounting ring 76, and a high voltage supply terminal 79.

  One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54, and the other end is electrically connected to the high voltage supply terminal 79 through the space in the housing 20. The high voltage supply terminal 79 is exposed to the outside of the housing 20 through the opening 20o2. For connection between the high voltage supply terminal 54 and the high voltage cable 71 and connection between the high voltage supply terminal 79 and the high voltage cable 71, welding, soldering, or the like can be used.

  The high voltage connector 72 is provided at the other end of the high voltage cable 71. The attachment ring 76 is made of a highly rigid material such as metal. The shape of the attachment ring 76 is a shape corresponding to the opening 20o2. The attachment ring 76 is located in the opening 20o2.

  Note that an annular groove is formed in the opening 20o2. A gap between the mounting ring 76 and the opening 20o2 is sealed by an annular O-ring provided in the groove portion. The O-ring has a function of preventing the coolant 7 from leaking out of the housing 20 from the gap between the mounting ring 76 and the opening 20o2. The O-ring is made of resin or rubber.

  The electrically insulating member 74 has an end face 74s exposed to the outside of the housing 20 through the opening 20o2. Here, the end surface 74s is a flat surface. The high voltage supply terminal 79 protrudes from the end face 74s to the outside of the housing 20. The electrically insulating member 74 covers the electrical connection between the high voltage supply terminal 79 and the high voltage cable 71 and is cooled by the coolant 7. In this embodiment, the electrically insulating member 74 is formed of an electrically insulating resin, fills up the electrical connection between the high voltage supply terminal 79 and the high voltage cable 71, and directly on the inner peripheral surface of the mounting ring 76. It is glued.

  More specifically, the electrical insulating member 74 is formed of a molding material. The electrically insulating member 74 can be formed by using the same technique as that for forming the electrically insulating member 64. Further, the attachment ring 76 may be indirectly bonded to the electrically insulating member 74 via an adhesive member (not shown).

  The fixing member 77 is formed in an annular shape. The screw passes through a through hole formed in the fixing member 77 and is tightened in a screw hole formed in the attachment ring 76. Other screws are tightened in screw holes formed in the housing 20 through other through holes formed in the fixing member 77. Thereby, the position of the high voltage connector 72 with respect to the housing 20 can be fixed.

  The electrically insulating member 91 covers the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71, is surrounded by the coolant 7, and is cooled directly or indirectly by the coolant 7.

  In this embodiment, the high voltage supply terminal 54 is formed outside the vacuum envelope 31 so as to protrude from the outer surface of the high voltage insulating member 50. The electrically insulating member 91 is formed of an electrically insulating resin, fills up the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71, and is directly bonded to the outer surface of the high voltage insulating member 50. The electrically insulating member 91 is surrounded by the coolant 7 and is directly cooled by the coolant 7 in the vicinity of the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71.

  More specifically, the electrically insulating member 91 is formed of a molding material. The electrically insulating member 91 can be formed by using the same technique as that for forming the electrically insulating member 81.

  The high voltage connector 100 includes a bottomed cylindrical housing 101, a cable 102 having a tip inserted into the housing 101, and the housing 101 filled, and the terminal of the cable 102 is fixed toward the high voltage connector 62 side. And a silicone plate 104 made of a silicone resin material inserted between the fixing portion 103 and the end face of the electrical insulating member 64. In this embodiment, the cable 102 is a high voltage cable. The fixing part 103 is made of an electrically insulating resin. The end surface of the fixing portion 103 facing the high voltage connector 62 is a flat surface. In addition, when the fixing | fixed part 103 is formed with the electrically insulating rubber, the fixing | fixed part 103 may be closely_contact | adhered to the end surface of the electrically insulating member 64 directly. The high voltage connector 100 provides a high voltage to the high voltage supply terminal 69.

  When the high voltage connector 100 is attached to the housing 20, the silicone plate 104 is respectively connected to the end surface of the fixing portion 103 and the end surface of the electrical insulating member 64 with the terminal of the cable 102 connected to the high voltage supply terminal 69. Press so that it is in close contact. When pressing, for example, a screw is tightened into a screw hole formed in the fixing member 67 through a through hole formed in the housing 101.

  The high-voltage connector 200 includes a bottomed cylindrical housing 201, a cable 202 having a tip inserted into the housing 201, and the housing 201 filled, and the terminal of the cable 202 is fixed toward the high-voltage connector 72 side. And a silicone plate 204 made of a silicone resin material inserted between the fixing portion 203 and the end face of the electrical insulating member 74. In this embodiment, cable 202 is a high voltage cable. The fixing portion 203 is made of an electrically insulating resin. The end surface of the fixing portion 203 facing the high voltage connector 72 is a flat surface. Note that when the fixing portion 203 is formed of an electrically insulating rubber, the fixing portion 203 may be in direct contact with the end face of the electrically insulating member 74. The high voltage connector 200 applies a high voltage to the high voltage supply terminal 79.

  When the high voltage connector 200 is attached to the housing 20, the silicone plate 204 is respectively connected to the end surface of the fixing portion 203 and the end surface of the electrical insulating member 74 with the terminal of the cable 202 connected to the high voltage supply terminal 79. Press so that it is in close contact. When pressing, for example, a screw is tightened into a screw hole formed in the fixing member 77 through a through hole formed in the housing 201.

  In the housing 20, an inlet 26 and an outlet 27 for the coolant 7 are formed. A cooler 22 is provided outside the housing 20 and is connected to an inlet 26 and an outlet 27 of the housing 20 via a conduit such as a hose. The cooler 22 radiates and circulates the coolant 7 in the housing 20. The cooler 22 has a coolant circulation pump 23 and a heat exchanger 24. The coolant circulation pump 23 discharges the coolant 7 taken from the housing 20 side to the heat exchanger 24 and creates a flow of the coolant 7 in the housing 20. The heat exchanger 24 is connected between the housing 20 and the coolant circulation pump 23 and releases the heat of the coolant 7 to the outside.

  From the above, a cooling path through which the coolant 7 flows can be formed in the housing 20. As the coolant 7, insulating oil or an aqueous coolant can be used. In this embodiment, an aqueous coolant is used as the coolant 7. The electrically insulating members 81 and 91, the high voltage cables 61 and 71, etc. can be cooled by the coolant 7.

  In the X-ray tube apparatus 10 configured as described above, by applying a predetermined current to the stator coil 910, the rotor 920 rotates and the anode target 35 rotates. Next, a predetermined high voltage is applied to the high voltage connectors 100 and 200.

  The high voltage applied to the high voltage connector 100 is supplied to the anode target 35 via the high voltage supply terminal 69, the high voltage cable 61, the high voltage supply terminal 44, the fixed body 1, the bearing 930 and the rotating body 2. The high voltage applied to the high voltage connector 200 is supplied to the cathode 36 via the high voltage supply terminal 79, the high voltage cable 71, and the high voltage supply terminal 54.

  As a result, an electron beam is emitted from the cathode 36 to the target layer 35a of the anode target 35, X-rays are emitted from the anode target 35, and the X-rays pass through the X-ray emission window 33 and the X-ray emission window 20w to the outside. To be emitted.

  According to the X-ray apparatus according to the first embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have. The high voltage connectors 62 and 72 are provided on the housing 20 independent of the X-ray tube 30 and less influenced by the heat generated by the X-ray tube 30.

  The high voltage supply terminal 44 electrically connected to the anode target 35 is exposed from the high voltage insulating member 40 to the outside of the vacuum envelope 31. The high voltage supply terminal 54 electrically connected to the cathode 36 is exposed from the high voltage insulating member 50 to the outside of the vacuum envelope 31.

  One end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 44, and the other end is electrically connected to the high voltage supply terminal 69 through the space in the housing 20. One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54, and the other end is electrically connected to the high voltage supply terminal 79 through the space in the housing 20. Since the receptacle is not provided with a receptacle between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be reduced in size as compared with the structure provided with the receptacle. Can be planned.

  The X-ray tube apparatus 10 includes electrically insulating members 81 and 91. The electrically insulating member 81 is directly bonded to the outer surface of the high voltage insulating member 40, and the electrically insulating member 91 is directly bonded to the outer surface of the high voltage insulating member 50. Since it is not a structure in which pressure is applied to the electric insulating member 81 toward the high voltage insulating member 40 or a structure in which pressure is applied to the electric insulating member 91 toward the high voltage insulating member 50, the electric insulating member 81 or the electric insulation Even if the conductive member 91 is affected by heat, good insulating properties can be maintained. The X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  In the housing 20, the high voltage cable 61 is immersed in the cooling liquid 7 from the vicinity of the outer wall of the X-ray tube 30 to the vicinity of the inner wall of the housing 20, so that the heat transmitted from the anode target 35 to the high voltage cable 61 is cooled with the cooling liquid. 7 can be released.

  The electrically insulating member 81 that covers the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61 is surrounded by the coolant 7 and is directly cooled by the coolant 7. For this reason, heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7.

  The amount of heat transferred from the anode target 35 to the other end of the high voltage cable 61 and the high voltage supply terminal 69 can be reduced. Since it is possible to suppress a decrease in adhesion between the end surface 64s of the electrical insulating member 64 of the high voltage connector 62 and the silicone plate 104 and a decrease in adhesion between the silicone plate 104 and the end surface of the fixing portion 103, electrical insulation is achieved. The discharge along the adhesion interface between the end face 64 s of the adhesive member 64 and the silicone plate 104 and the discharge along the adhesion interface between the silicone plate 104 and the end face of the fixing portion 103 can be suppressed. Since the adhesion between the high voltage connector 62 and the high voltage connector 100 can be maintained, good insulation can be maintained.

  In the housing 20, the high voltage cable 71 is immersed in the coolant 7 from the vicinity of the outer wall of the X-ray tube 30 to the vicinity of the inner wall of the housing 20, so that the heat transmitted from the cathode 36 to the high voltage cable 71 is transferred to the coolant 7. Can be released.

  The electrically insulating member 91 that covers the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71 is surrounded by the coolant 7 and is directly cooled by the coolant 7. Therefore, heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7.

  The amount of heat transferred from the cathode 36 to the other end of the high voltage cable 71 and the high voltage supply terminal 79 can be reduced. Since it is possible to suppress a decrease in adhesion between the end surface 74s of the electrical insulating member 74 of the high voltage connector 72 and the silicone plate 204 and a decrease in adhesion between the silicone plate 204 and the end surface of the fixing portion 203, electrical insulation is achieved. The discharge along the contact interface between the end surface 74 s of the adhesive member 74 and the silicone plate 204 and the discharge along the contact interface between the silicone plate 204 and the end surface of the fixing portion 203 can be suppressed. Since the adhesion between the high voltage connector 72 and the high voltage connector 200 can be maintained, good insulation can be maintained.

  The electrical insulating member 81 fills up the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61, and the electrical insulating member 91 fills up the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71. I'm doing it. Thereby, the water-system coolant which has a high heat transfer rate and has water as a main component can be used as the coolant 7. For this reason, the cooling liquid 7 is the heat most transmitted from the anode target 35 to the high voltage supply terminal 44 and the high voltage cable 61, the heat transmitted from the cathode 36 to the high voltage supply terminal 54 and the high voltage cable 71, and the like. It can be taken away effectively. Further, since the water-based coolant has a larger specific heat than the insulating oil (about twice that of the insulating oil), the temperature rise of the coolant 7 can be suppressed low.

The electrically insulating members 81 and 91 can be formed using a resin cheaper than ceramics.
The electrically insulating members 81 and 91 made of resin tend to release gas when the temperature becomes high, but the electrically insulating members 81 and 91 are located outside the vacuum envelope 31. Since the high-voltage insulating members 40 and 50 formed of ceramic hardly release gas even at a high temperature, a decrease in the vacuum degree of the vacuum envelope 31 can be reduced.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to the second embodiment will be described. In this embodiment, the same reference numerals are given to the same functional parts as those in the above-described embodiment, and detailed description thereof will be omitted. FIG. 2 is a cross-sectional view showing an X-ray apparatus according to the second embodiment.

  As shown in FIG. 2, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a high voltage connector 100, and a high voltage connector 200. Although not shown, the X-ray apparatus also includes the cooler 22.

  The high voltage insulating member 40 has a hole 41 that opens to the outside of the vacuum envelope 31. In this embodiment, the hole 41 extends in a direction orthogonal to the tube axis. The high voltage supply terminal 44 is located at the bottom of the hole 41. The high voltage insulating member 40 exposes the high voltage supply terminal 44 to the outside of the vacuum envelope 31 through the hole 41.

  One end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 44 through the hole 41. In this embodiment, the high voltage supply terminal 44 is located deep inside, and it is difficult to use welding or soldering to connect the high voltage supply terminal 44 and the high voltage cable 61. You can connect using it.

The electrically insulating member 81 is formed of an electrically insulating resin, is filled in the hole 41, and fills up the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61.
More specifically, the electrically insulating member 81 is formed of a molding material. When the formation of the electrical insulating member 81 starts, first, the molding material is injected into the hole 41 while maintaining the state where one end of the high voltage cable 61 is pressed against the high voltage supply terminal 44 through the hole 41. Thereafter, the injected molding material is cured to form an electrically insulating member 81 in the hole 41.

  In addition, when inject | pouring a molding material, injection | pouring in a vacuum is preferable. In addition, it is preferable that air is not left in the hole portion 41, so that the insulation can be satisfactorily ensured. Therefore, when the molding material is injected, it is preferable that the hole portion 41 is completely filled with the molding material. In this embodiment, the mold material is poured into the hole 41 to the extent that it overflows.

  The high voltage insulating member 50 has a hole 51 that opens to the outside of the vacuum envelope 31. In this embodiment, the hole 51 extends in a direction orthogonal to the tube axis. The high voltage supply terminal 54 is located at the bottom of the hole 51. The high voltage insulating member 50 exposes the high voltage supply terminal 54 to the outside of the vacuum envelope 31 through the hole 51.

  One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54 through the hole 51. In this embodiment, the high voltage supply terminal 54 is located deep inside, and it is difficult to use welding or soldering to connect the high voltage supply terminal 54 and the high voltage cable 71. You can connect using it.

The electrically insulating member 91 is formed of an electrically insulating resin, is filled in the hole 51, and fills up the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71.
More specifically, the electrically insulating member 91 is formed of a molding material. The electrically insulating member 91 can be formed by using the same technique as that for forming the electrically insulating member 81.

According to the X-ray apparatus according to the second embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have.
Since the receptacle is not provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be downsized.

  The X-ray tube apparatus 10 includes electrically insulating members 81 and 91. The electrically insulating member 81 is formed by filling the hole 41 with a molding material, and the electrically insulating member 91 is formed by filling the hole 51 with a molding material. Since it is not a structure in which pressure is applied to the electric insulating member 81 toward the high voltage insulating member 40 or a structure in which pressure is applied to the electric insulating member 91 toward the high voltage insulating member 50, the electric insulating member 81 or the electric insulation is not provided. Even if the conductive member 91 is affected by heat, good insulating properties can be maintained. The X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  The electrically insulating member 81 that covers the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 is surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7, and indirectly through the high voltage insulating member 40. Cooled. For this reason, heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7.

  The electrically insulating member 91 covering the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71 is surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7, and indirectly through the high voltage insulating member 50. Cooled. Therefore, heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7.

  The electrical insulating member 81 fills up the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61, and the electrical insulating member 91 fills up the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71. I'm doing it.

The electrically insulating members 81 and 91 can be formed using a resin cheaper than ceramics. The high voltage connectors 100 and 200 are surface pressure type connectors.
For this reason, the effect similar to the X-ray apparatus concerning the said 1st Embodiment can be acquired.

In addition, the adverse effect of heat applied to the high voltage cables 61 and 71 when forming the electrical insulating members 81 and 91 can be reduced as compared with the first embodiment.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

Here, a modification of the X-ray apparatus according to the second embodiment will be described. FIG. 3 is a cross-sectional view showing a modification of the X-ray apparatus according to the second embodiment.
As shown in FIG. 3, the high voltage insulating member 40 has a hole portion 41 and another hole portion 42 opened to the outside of the vacuum envelope 31. Here, the hole 42 extends in a direction along the tube axis. The high voltage supply terminal 44 is located at the bottom of the hole 41 and the hole 42. The high voltage insulating member 40 exposes the high voltage supply terminal 44 to the outside of the vacuum envelope 31 through the holes 41 and 42.

  One end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 44 through the hole 41. Although the high voltage supply terminal 44 is located behind, the high voltage insulating member 40 has not only the hole 41 but also the hole 42. For this reason, it is possible to use welding, soldering, or the like to connect the high voltage supply terminal 44 and the high voltage cable 61 by using the hole 42.

The electrically insulating member 81 is formed of an electrically insulating resin, is filled in the holes 41 and 42, and fills the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61.
More specifically, the electrically insulating member 81 is formed of a molding material. When the formation of the electrical insulating member 81 starts, first, one end of the high voltage cable 61 is passed through the hole 41, and the high voltage supply terminal 44 and the high voltage cable 61 are welded or soldered using the hole 42. Connect using it. Subsequently, after injecting the molding material into the holes 41 and 42, the injected molding material is cured, whereby the electrical insulating member 81 is formed in the holes 41 and 42.

  As described above, by forming the hole 42 in the high voltage insulating member 40, the high voltage supply terminal 44 and the high voltage cable 61 can be connected using welding or soldering without using a spring action. Can be connected.

  The high voltage insulating member 50 has, in addition to the hole 51, another hole 52 that opens to the outside of the vacuum envelope 31. Here, the hole 52 extends in a direction along the tube axis. The high voltage supply terminal 54 is located at the bottom of the hole 51 and the hole 52. The high voltage insulating member 50 exposes the high voltage supply terminal 54 to the outside of the vacuum envelope 31 through the holes 51 and 52.

  One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54 through the hole 51. Although the high voltage supply terminal 54 is located behind, the high voltage insulating member 50 has not only the hole 51 but also the hole 52. For this reason, by using the hole portion 52, welding, soldering, or the like can be used to connect the high voltage supply terminal 54 and the high voltage cable 71.

The electrically insulating member 91 is formed of an electrically insulating resin, is filled in the holes 51 and 52, and fills the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71.
More specifically, the electrically insulating member 91 is formed of a molding material. When the formation of the electrical insulating member 91 starts, first, one end of the high voltage cable 71 is passed through the hole 51, and the high voltage supply terminal 54 and the high voltage cable 71 are welded or soldered using the hole 52. Connect using it. Subsequently, after injecting the mold material into the holes 51 and 52, the injected mold material is cured, whereby the electrical insulating member 91 is formed in the holes 51 and 52.

  As described above, by forming the hole 52 in the high voltage insulating member 50, the high voltage supply terminal 54 and the high voltage cable 71 can be connected using welding or soldering without using a spring action. Can be connected.

  Next, an X-ray apparatus according to a third embodiment will be described. In this embodiment, the same functional parts as those of the second embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted. FIG. 4 is a cross-sectional view showing an X-ray apparatus according to the third embodiment.

  As shown in FIG. 4, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a high voltage connector 100, and a high voltage connector 200. Although not shown, the X-ray apparatus also includes the cooler 22.

  The high voltage connector 62 includes a mounting ring 66 and a high voltage supply terminal 69, and also includes a high voltage insulating member 65 and an electric insulating member 64 as electric insulating members.

  The high voltage insulating member 65 has an end face 65s exposed to the outside of the housing 20 through the opening 20o1. Here, the end face 65s is a flat surface. The high voltage supply terminal 69 protrudes from the end face 65s to the outside of the housing 20.

  The high voltage insulating member 65 has a hole 68 that is opened inside the housing 20. The high voltage supply terminal 69 is located at the bottom of the hole 68. The high voltage insulating member 65 exposes the high voltage supply terminal 69 to the inside of the housing 20 through the hole 68. The high voltage insulating member 65 is bonded to the inner peripheral surface of the mounting ring 66. Here, the high voltage insulating member 65 is indirectly bonded to the inner peripheral surface of the mounting ring 66 through an adhesive member.

  The other end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 69 through the hole 68. In this embodiment, welding or soldering can be used to connect the high voltage supply terminal 69 and the high voltage cable 61, and the high voltage supply terminal 69 is attached to the high voltage insulating member 65.

The electrically insulating member 64 is formed of an electrically insulating resin, is filled in the hole 68, and fills up the electrical connection between the high voltage supply terminal 69 and the high voltage cable 61.
More specifically, the electrically insulating member 64 is formed of a molding material. When the formation of the electrical insulating member 64 starts, first, a molding material is injected into the hole 68 where the electrical connection portion between the high voltage supply terminal 69 and the high voltage cable 61 is located. Then, the electrically insulating member 64 is formed in the hole 68 by curing the injected molding material.

  The high voltage connector 100 is attached to the housing 20 by being pressed so that the silicone plate 104 is in close contact with the end surface of the fixed portion 103 and the end surface 65 s of the high voltage insulating member 65.

  The high voltage connector 72 includes a mounting ring 76 and a high voltage supply terminal 79, and also includes a high voltage insulating member 75 and an electric insulating member 74 as electric insulating members.

  The high voltage insulating member 75 has an end surface 75s exposed to the outside of the housing 20 through the opening 20o2. Here, the end surface 75s is a flat surface. The high voltage supply terminal 79 protrudes from the end surface 75s to the outside of the housing 20.

  The high-voltage insulating member 75 has a hole 78 that is open inside the housing 20. The high voltage supply terminal 79 is located at the bottom of the hole 78. The high voltage insulating member 75 exposes the high voltage supply terminal 79 to the inside of the housing 20 through the hole 78. The high voltage insulating member 75 is bonded to the inner peripheral surface of the mounting ring 76. Here, the high voltage insulating member 75 is indirectly bonded to the inner peripheral surface of the mounting ring 76 via an adhesive member.

  The other end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 79 through the hole 78. In this embodiment, welding or soldering can be used to connect the high voltage supply terminal 79 and the high voltage cable 71, and the high voltage supply terminal 79 is attached to the high voltage insulating member 75.

The electrically insulating member 74 is formed of an electrically insulating resin, is filled in the hole 78, and fills the electrical connection portion between the high voltage supply terminal 79 and the high voltage cable 71.
More specifically, the electrical insulating member 74 is formed of a molding material. When the formation of the electrically insulating member 74 starts, first, a molding material is injected into the hole 78 where the electrical connection portion between the high voltage supply terminal 79 and the high voltage cable 71 is located. Thereafter, the injected molding material is cured to form the electrically insulating member 74 in the hole 78.

  The high voltage connector 200 is attached to the housing 20 by pressing the silicone plate 204 so as to be in close contact with the end face of the fixing portion 203 and the end face 75 s of the high voltage insulating member 75.

According to the X-ray apparatus according to the third embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have. The X-ray tube apparatus 10 is formed in the same manner as in the second embodiment except for the high voltage connectors 62 and 72.
Since the receptacle is not provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be downsized.

  The X-ray tube apparatus 10 includes electrically insulating members 81 and 91. Since it is not a structure in which pressure is applied to the electric insulating member 81 toward the high voltage insulating member 40 or a structure in which pressure is applied to the electric insulating member 91 toward the high voltage insulating member 50, the electric insulating member 81 or the electric insulation is not provided. Even if the conductive member 91 is affected by heat, good insulating properties can be maintained. The X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  The electrically insulating member 64 that covers the electrical connection between the high voltage supply terminal 69 and the high voltage cable 61 is surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7, and indirectly through the high voltage insulating member 65. Cooled. For this reason, even if there is heat transfer from the anode target 35 to the high voltage connector 62, the heat can be radiated to the coolant 7.

  The electrically insulating member 74 covering the electrical connection portion between the high voltage supply terminal 79 and the high voltage cable 71 is surrounded by the coolant 7 and directly cooled by the coolant 7, and indirectly through the high voltage insulator 75. Cooled. For this reason, even if there is heat transfer from the cathode 36 to the high voltage connector 72, heat can be radiated to the coolant 7.

The high voltage connectors 100 and 200 are surface pressure type connectors.
For this reason, the effect similar to the X-ray apparatus concerning the said 2nd Embodiment can be acquired.

The electrically insulating member 64 is formed by filling the hole 68 with a molding material, and the electrically insulating member 74 is formed by filling the hole 78 with a molding material. Compared with the first and second embodiments, the adverse effect of heat applied to the high voltage cables 61 and 71 when forming the electrically insulating members 64 and 74 can be reduced.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to a fourth embodiment will be described. In this embodiment, the same reference numerals are given to the same functional parts as those in the above-described embodiment, and detailed description thereof will be omitted. FIG. 5 is a sectional view showing an X-ray apparatus according to the fourth embodiment. FIG. 6 is an exploded cross-sectional view showing a part of the X-ray apparatus shown in FIG.

  As shown in FIGS. 5 and 6, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a high voltage connector 100, and a high voltage connector 200. Although not shown, the X-ray apparatus also includes the cooler 22.

  The X-ray tube apparatus 10 further includes a high voltage insulating member 82 having an adhesive surface 82 s and an adhesive member 84 that adheres the adhesive surface 82 s of the high voltage insulating member 82 to the outer surface of the high voltage insulating member 40. . The high voltage insulating member 82 is formed of ceramics. The adhesive member 84 is formed of, for example, an epoxy resin as a material having electrical insulation and heat resistance.

  The high voltage supply terminal 44 includes a first dividing unit 44a and a second dividing unit 44b. The first divided portion 44 a is exposed from the high voltage insulating member 40 to the outside of the vacuum envelope 31. The second divided portion 44b is provided in the high voltage insulating member 82, is located inside the high voltage insulating member 82, is exposed to the outside of the high voltage insulating member 82 from the bonding surface 82s, and is electrically connected to the first divided portion 44a. Connected to. In this embodiment, the side surface of the second divided portion 44b is in contact with the first divided portion 44a using a spring action.

  The high voltage insulating member 82 has a hole 83 opened at a position away from the bonding surface 82s. In this embodiment, the hole 83 extends in a direction orthogonal to the tube axis. The second divided portion 44 b of the high voltage supply terminal 44 is located at the bottom of the hole portion 83. The high voltage insulating member 82 exposes the second divided portion 44 b to the outside of the vacuum envelope 31 through the hole 83.

  One end of the high voltage cable 61 is electrically connected to the second divided portion 44 b through the hole 83. In this embodiment, the second divided portion 44b is located behind and it is difficult to use welding or soldering to connect the second divided portion 44b and the high voltage cable 61. You can connect using it.

The electrically insulating member 81 is formed of an electrically insulating resin, is filled in the hole 83, and fills the electrical connection portion between the second divided portion 44b and the high voltage cable 61.
More specifically, the electrically insulating member 81 is formed of a molding material. When the formation of the electrical insulating member 81 starts, first, the molding material is injected into the hole 83 while maintaining the state where one end of the high voltage cable 61 is pressed through the hole 83 to the second divided part 44b. Thereafter, the injected molding material is cured to form an electrically insulating member 81 in the hole 83.

  The electrically insulating member 81, the high voltage insulating member 82, and the second divided portion 44b form a part of the cable assembly 60. Thereby, after forming the cable assembly 60, the bonding surface 82 s of the high voltage insulating member 82 can be bonded to the outer surface of the high voltage insulating member 40 using the bonding member 84.

  Alternatively, the bonding surface 84s of the high voltage insulating member 82 may be first bonded to the outer surface of the high voltage insulating member 40 using the bonding member 84, and the first divided portion 44a and the second divided portion 44b may be electrically connected. . In this case, the second divided portion 44b may be formed integrally with the first divided portion 44a in advance and provided on the high voltage insulating member 40 side. Next, the mold material is injected into the hole 83 while maintaining the state where one end of the high voltage cable 61 is pressed against the second divided portion 44 b through the hole 83. Thereafter, the injected molding material is cured to form an electrically insulating member 81 in the hole 83.

  The X-ray tube apparatus 10 further includes a high voltage insulating member 92 having an adhesive surface 92 s and an adhesive member 94 that adheres the adhesive surface 92 s of the high voltage insulating member 92 to the outer surface of the high voltage insulating member 50. . The high voltage insulating member 92 is formed of ceramics. The adhesive member 94 is made of, for example, an epoxy resin as a material having electrical insulation and heat resistance.

  The high voltage supply terminal 54 includes a first dividing unit 54a and a second dividing unit 54b. The first divided portion 54 a is exposed from the high voltage insulating member 50 to the outside of the vacuum envelope 31. The second divided portion 54b is provided in the high voltage insulating member 92, is located inside the high voltage insulating member 92, is exposed to the outside of the high voltage insulating member 92 from the bonding surface 92s, and is electrically connected to the first divided portion 54a. Connected to. In this embodiment, the side surface of the second divided portion 54b is in contact with the first divided portion 54a using a spring action.

  The high voltage insulating member 92 has a hole 93 that is open at a position away from the bonding surface 92s. In this embodiment, the hole 93 extends in a direction orthogonal to the tube axis. The second divided portion 54 b of the high voltage supply terminal 54 is located at the bottom of the hole 93. The high voltage insulating member 92 exposes the second divided portion 54 b to the outside of the vacuum envelope 31 through the hole 93.

  One end of the high voltage cable 71 is electrically connected to the second divided portion 54 b through the hole 93. In this embodiment, the second divided portion 54b is located behind and it is difficult to use welding or soldering to connect the second divided portion 54b and the high voltage cable 71. You can connect using it.

The electrically insulating member 91 is formed of an electrically insulating resin, is filled in the hole 93, and fills the electrical connection portion between the second divided portion 54 b and the high voltage cable 71.
More specifically, the electrically insulating member 91 is formed of a molding material. The electrically insulating member 91 can be formed by using the same technique as that for forming the electrically insulating member 81.

  The electrically insulating member 91, the high voltage insulating member 92, and the second divided portion 54b form a part of the cable assembly 70. Thereby, after forming the cable assembly 70, the bonding surface 92 s of the high voltage insulating member 92 can be bonded to the outer surface of the high voltage insulating member 50 using the bonding member 94.

  Alternatively, the bonding surface 94s of the high voltage insulating member 92 may be first bonded to the outer surface of the high voltage insulating member 50 using the bonding member 94, and the first divided portion 54a and the second divided portion 54b may be electrically connected. . In this case, the second divided portion 54b may be formed integrally with the first divided portion 54a in advance and provided on the high voltage insulating member 50 side. Next, the mold material is injected into the hole 93 while maintaining the state where one end of the high voltage cable 71 is pressed against the second divided portion 54 b through the hole 93. Then, the electrically insulating member 91 is formed in the hole 93 by curing the injected molding material.

  According to the X-ray apparatus according to the fourth embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have.

  Since the receptacle is not provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be downsized.

  The X-ray tube apparatus 10 includes electrically insulating members 81 and 91 and high voltage insulating members 82 and 92. The electrically insulating member 81 is formed by filling the hole 83 with a molding material, and the electrically insulating member 91 is formed by filling the hole 93 with a molding material. Since it is not a structure in which pressure is applied to the electric insulating member 81 toward the high voltage insulating member 82 or a structure in which pressure is applied to the electric insulating member 91 toward the high voltage insulating member 92, the electric insulating member 81 and the electric insulation are not provided. Even if the conductive member 91 is affected by heat, good insulating properties can be maintained. The X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  The electrically insulating member 81 that covers the electrical connection between the high voltage supply terminal 44 and the high voltage cable 61 is surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7, and the high voltage insulating member 82 and the high voltage insulation Cooled indirectly via member 40. For this reason, heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7.

  The electrically insulating member 91 covering the electrical connection between the high voltage supply terminal 54 and the high voltage cable 71 is surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7, and the high voltage insulating member 92 and the high voltage insulation It is cooled indirectly via the member 50. Therefore, heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7.

  The electrically insulating member 81 fills up the electrical connection portion between the second divided portion 44b (high voltage supply terminal 44) and the high voltage cable 61, and the electrically insulating member 91 includes the second divided portion 54b (high voltage supply terminal 54). ) And the high voltage cable 71 are filled up.

The electrically insulating members 81 and 91 can be formed using a resin cheaper than ceramics. The high voltage connectors 100 and 200 are surface pressure type connectors.
For this reason, the effect similar to the X-ray apparatus concerning the said 1st Embodiment can be acquired.

  In addition, the adverse effect of heat applied to the high voltage cables 61 and 71 when forming the electrical insulating members 81 and 91 can be reduced as compared with the first embodiment.

  From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to a fifth embodiment will be described. In this embodiment, the same reference numerals are given to the same functional parts as those in the above-described embodiment, and detailed description thereof will be omitted. FIG. 7 is a cross-sectional view showing an X-ray apparatus according to the fifth embodiment.

  As shown in FIG. 7, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a high voltage connector 100, and a high voltage connector 200. Although not shown, the X-ray apparatus also includes the cooler 22.

  The high voltage supply terminal 44 includes a first dividing unit 44a and a second dividing unit 44b. The first divided portion 44 a is exposed from the high voltage insulating member 40 to the outside of the vacuum envelope 31. The second dividing unit 44b is electrically connected to the first dividing unit 44a. In this embodiment, the side surface of the second divided portion 44b is in contact with the first divided portion 44a using a spring action.

  The electrically insulating member 81 is formed of an electrically insulating resin, has an adhesive surface 81s, fills the electrical connection portion between the second divided portion 44b and the high voltage cable 61, and extends from the adhesive surface 81s to the second divided portion. 44b is exposed to the outside.

  More specifically, the electrically insulating member 81 is formed of a molding material. When forming the electrically insulating member 81, the second divided portion 44b and the high voltage cable 61 are electrically connected in advance using welding, soldering, or the like. When the formation of the electrical insulating member 81 starts, first, an electrical connection portion between the second divided portion 44b and the high voltage cable 61 and a part of the high voltage cable 61 are carried into a mold material tank (not shown), Mold material is injected into the mold material tank. Thereafter, the injected molding material is cured and carried out of the molding material tank. Thereby, the electrically insulating member 81 in which the second divided portion 44b is exposed from the bonding surface 81s is formed.

  The X-ray tube apparatus 10 further includes an adhesive member 84. The adhesive member 84 is formed of, for example, an epoxy-based resin, and the adhesive surface 81 s of the electrical insulating member 81 is adhered to the outer surface of the high voltage insulating member 40.

  The electrically insulating member 81 and the second divided portion 44 b form a part of the cable assembly 60. Thereby, after forming the cable assembly 60, the bonding surface 81 s of the electrical insulating member 81 can be bonded to the outer surface of the high-voltage insulating member 40 using the bonding member 84.

  The high voltage supply terminal 54 includes a first dividing unit 54a and a second dividing unit 54b. The first divided portion 54 a is exposed from the high voltage insulating member 50 to the outside of the vacuum envelope 31. The second division unit 54b is electrically connected to the first division unit 54a. In this embodiment, the side surface of the second divided portion 54b is in contact with the first divided portion 54a using a spring action.

  The electrically insulating member 91 is formed of an electrically insulating resin, has an adhesive surface 91s, fills the electrical connection portion between the second divided portion 54b and the high voltage cable 71, and extends from the adhesive surface 91s to the second divided portion. 54b is exposed to the outside.

  More specifically, the electrically insulating member 91 is formed of a molding material. The electrically insulating member 91 can be formed by using the same technique as that for forming the electrically insulating member 81.

  The X-ray tube apparatus 10 further includes an adhesive member 94. The adhesive member 94 is formed of, for example, an epoxy resin, and the adhesive surface 91s of the electrical insulating member 91 is adhered to the outer surface of the high voltage insulating member 50.

  The electrically insulating member 91 and the second divided portion 54 b form a part of the cable assembly 70. Thereby, after forming the cable assembly 70, the bonding surface 91 s of the electrical insulating member 91 can be bonded to the outer surface of the high voltage insulating member 50 using the bonding member 94.

According to the X-ray apparatus according to the fifth embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have.
Since the receptacle is not provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be downsized.

  The X-ray tube apparatus 10 includes electrically insulating members 81 and 91. The electrical insulating member 81 is bonded to the high voltage insulating member 40 using an adhesive member 84, and the electrical insulating member 91 is bonded to the high voltage insulating member 50 using an adhesive member 94. Since it is not a structure in which pressure is applied to the electric insulating member 81 toward the high voltage insulating member 40 or a structure in which pressure is applied to the electric insulating member 91 toward the high voltage insulating member 50, the electric insulating member 81 or the electric insulation is not provided. Even if the conductive member 91 is affected by heat, good insulating properties can be maintained. The X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  The electrically insulating member 81 that covers the electrical connection portion between the second divided portion 44 b and the high voltage cable 61 is surrounded by the coolant 7 and is directly cooled by the coolant 7. For this reason, heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7.

  The electrically insulating member 91 that covers the electrical connection portion between the second divided portion 54 b and the high voltage cable 71 is surrounded by the coolant 7 and is directly cooled by the coolant 7. Therefore, heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7.

  The electrically insulating member 81 fills up the electrical connection portion between the second divided portion 44b (high voltage supply terminal 44) and the high voltage cable 61, and the electrically insulating member 91 includes the second divided portion 54b (high voltage supply terminal 54). ) And the high voltage cable 71 are filled up.

The electrically insulating members 81 and 91 can be formed using a resin cheaper than ceramics. The high voltage connectors 100 and 200 are surface pressure type connectors.
For this reason, the effect similar to the X-ray apparatus concerning the said 1st Embodiment can be acquired.

After the second divided portion 44b and the high voltage cable 61 are firmly connected using welding or soldering, the electrically insulating member 81 is molded. Similarly, after the second divided portion 54b and the high voltage cable 71 are firmly connected using welding or soldering, the electrically insulating member 91 is molded. For this reason, the cable assemblies 60 and 70 with high reliability can be obtained.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to a sixth embodiment will be described. The X-ray apparatus according to this embodiment is formed in the same manner as the X-ray apparatus according to the fourth embodiment except that the high voltage insulating members 82 and 92 are formed using an electrically insulating resin (FIG. 5). reference). More specifically, the high voltage insulating members 82 and 92 are formed of a molding material.

According to the X-ray apparatus according to the sixth embodiment configured as described above, the same effects as those of the X-ray apparatus according to the fourth embodiment can be obtained.
The high voltage insulating members 82 and 92 can be formed using a resin that is less expensive than ceramics.

The high voltage insulating members 82 and 92 can be molded in a state independent of the X-ray tube 30 and the high voltage cables 61 and 71. For this reason, the apparatus for performing mold forming in the sixth embodiment is generally smaller than the apparatus (special apparatus) for performing mold forming in the fifth embodiment. Can do.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to a seventh embodiment will be described. In this embodiment, the same reference numerals are given to the same functional parts as those in the above-described embodiment, and detailed description thereof will be omitted. FIG. 8 is a cross-sectional view showing an X-ray apparatus according to the seventh embodiment.

  As shown in FIG. 8, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10, a high voltage connector 100, and a high voltage connector 200. Although not shown, the X-ray apparatus also includes the cooler 22.

  The electrically insulating member 81 is formed in the shape of a bowl and is located at a distance from the high voltage insulating member 40. A through hole is formed in the electrically insulating member 81, and the high voltage cable 61 passes through the through hole.

  The electrically insulating member 91 is formed in a bowl shape and is located at a distance from the high voltage insulating member 50. A through hole is formed in the electrically insulating member 91, and a high voltage cable 71 passes through the through hole.

  The coolant 7 is also interposed between the electric insulating member 81 and the high voltage insulating member 40 and between the electric insulating member 91 and the high voltage insulating member 50, respectively. Since the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 and the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 are in contact with the coolant 7, the coolant 7 is insulated. Oil.

  According to the X-ray apparatus according to the seventh embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have. The high voltage supply terminal 44 electrically connected to the anode target 35 is exposed from the high voltage insulating member 40 to the outside of the vacuum envelope 31. The high voltage supply terminal 54 electrically connected to the cathode 36 is exposed from the high voltage insulating member 50 to the outside of the vacuum envelope 31.

  The high voltage cable 61 has one end electrically connected to the high voltage supply terminal 44 and the other end electrically connected to the high voltage supply terminal 69 through the through hole of the electrical insulating member 81 and the space in the housing 20. It is connected to the. One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54, and the other end is electrically connected to the high voltage supply terminal 79 through the through hole of the electrical insulating member 91 and the space in the housing 20. It is connected to the. Since the receptacle is not provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube device 10, the X-ray tube device 10 can be downsized.

  The coolant 7 is an insulating oil. The high voltage cable 61 is connected to the high voltage supply terminal 44 and the high voltage cable 71 is connected to the high voltage supply terminal 54 without using a surface pressure type connector. For this reason, the X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  In the housing 20, the high voltage cable 61 is immersed in the coolant 7, so that heat transmitted from the anode target 35 to the high voltage cable 61 can be released to the coolant 7. The electrical connection between the high voltage supply terminal 44 and the high voltage cable 61 and the electrically insulating member 81 are surrounded by the coolant 7 and are directly cooled by the coolant 7. For this reason, heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7.

  The amount of heat transferred from the anode target 35 to the other end of the high voltage cable 61 and the high voltage supply terminal 69 can be reduced. Deformation of the end face 64s of the electrically insulating member 64 of the high voltage connector 62 and deformation of the silicone plate 104 can be suppressed. For this reason, the adhesiveness of the high voltage connector 62 and the high voltage connector 100 can be maintained, and favorable insulation can be maintained.

  In the housing 20, the high voltage cable 71 is immersed in the coolant 7, so that heat transmitted from the cathode 36 to the high voltage cable 71 can be released to the coolant 7. The electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 and the electrical insulating member 91 are surrounded by the cooling liquid 7 and directly cooled by the cooling liquid 7. Therefore, heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7.

  The amount of heat transferred from the cathode 36 to the other end of the high voltage cable 71 and the high voltage supply terminal 79 can be reduced. Deformation of the end surface 74s of the electrically insulating member 74 of the high voltage connector 72 and deformation of the silicone plate 204 can be suppressed. For this reason, the adhesiveness of the high voltage connector 72 and the high voltage connector 200 can be maintained, and favorable insulation can be maintained.

The electrically insulating members 81 and 91 can be formed using a resin cheaper than ceramics. In addition, when the electrical insulation between the high voltage supply terminal 44 and the housing 20 and the electrical insulation between the high voltage supply terminal 54 and the housing 20 are maintained by insulating oil, the electrical insulating members 81 and 91 are not necessarily provided. There is no need to provide it. The high voltage connectors 100 and 200 are surface pressure type connectors.
The high voltage supply terminal 44 and the high voltage cable 61 are firmly connected using welding or soldering, and similarly, the high voltage supply terminal 54 and the high voltage cable 71 are firmly connected using welding or soldering. Has been. The electrical insulating member 81 is formed without filling up the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61, and similarly, the electrical insulating member 91 includes the high voltage supply terminal 54, the high voltage cable 71, and the like. It is formed without filling up the electrical connection part. For this reason, the reliability of an electrical connection part can be improved.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

  Next, an X-ray apparatus according to an eighth embodiment will be described. In this embodiment, the same reference numerals are given to the same functional parts as those in the above-described embodiment, and detailed description thereof will be omitted. FIG. 9 is a cross-sectional view showing an X-ray apparatus according to the eighth embodiment.

  As shown in FIG. 9, the X-ray apparatus includes a rotary anode type X-ray tube apparatus 10. Although not shown, the X-ray apparatus also includes the cooler 22.

The housing 20 includes a housing main body 20e formed in a cylindrical shape and lid portions 20f, 20g, and 20h.
A frame-shaped step portion is formed in the opening of the housing body 20a on the side where the high voltage supply terminal 44 is located. A frame-shaped groove is formed on the inner peripheral surface of the stepped portion. In the direction along the tube axis, the peripheral edge portion of the lid portion 20f is in contact with the step portion of the housing body 20a. A C retaining ring 20i is fitted in the groove of the housing body 20a.

The C retaining ring 20i restricts the position of the lid portion 20f with respect to the housing body 20a in the direction along the tube axis. In this embodiment, the position of the lid 20f is fixed in order to prevent the lid 20f from rattling. In the direction perpendicular to the tube axis, the gap between the housing body 20e and the lid portion 20f is liquid-tightly sealed by a frame-shaped O-ring. The O-ring has a function of preventing the coolant 7 from leaking outside the housing 20. The O-ring is made of resin or rubber.
From the above, the opening of the housing body 20a on the side where the high voltage supply terminal 44 is located is liquid-tightly closed by the lid 20f, the C retaining ring 20i, and the O-ring.

  A frame-shaped step portion is formed in the opening of the housing body 20a on the side where the high voltage supply terminal 54 is located. A frame-shaped groove is formed on the inner peripheral surface of the stepped portion. The lid 20g is located inside the housing body 20a. In the direction along the tube axis, the peripheral portion of the lid portion 20g sandwiches an X-ray shielding portion 510 described later together with the step portion of the housing body 20a. If there is no leakage of X-rays from between the X-ray shield 510 and the X-ray shield 520, which will be described later, to the outside of the housing 20, the peripheral portion of the lid portion 20g is in contact with the step portion of the housing body 20e. Also good. The lid part 20h faces the lid part 20g. In this embodiment, the lid portion 20h has an annular portion, and the annular portion is formed to protrude toward the lid portion 20g.

  The inner peripheral surface of the housing main body 20a and the gap between the lid portion 20g and the lid portion 20h are liquid-tightly sealed by a frame-shaped O-ring. The O-ring is formed at the peripheral edge of the rubber bellows 21 and has a function of preventing leakage of the coolant 7 to the outside of the housing 20.

  A C retaining ring 20j is fitted in the groove of the housing body 20a. The C retaining ring 20j maintains a state in which the lid portion 20h applies stress to the O-ring. From the above, the opening of the housing body 20a on the side where the high voltage supply terminal 54 is located is liquid-tightly closed by the lid 20g, the lid 20h, the C retaining ring 20j, and the rubber bellows 21.

  Although not shown, the housing 20 has an X-ray radiation window 20w, an opening 20o1, and an opening 20o2. In this embodiment, no lead plate is attached to the inner surface of the housing 20.

  The lid 20g has an opening 20k through which the coolant 7 enters and exits. The lid 20h is formed with a vent 20m through which air as an atmosphere enters and exits. In the housing main body 20a, the rubber bellows 21 divides a region surrounded by the lid 20g and the lid 20h into a first space connected to the opening 20k and a second space connected to the vent hole 20m.

  The X-ray tube 30 includes an anode target 35, a cathode 36, a vacuum envelope 31, a high voltage supply terminal 44, a high voltage supply terminal 54, and the like. The vacuum envelope 31 includes a vacuum vessel 32, a high voltage insulating member 50, and the like. In this embodiment, the vacuum vessel 32 is made of glass and has an X-ray emission window 33.

  The fixed body 1 of the X-ray tube 30 is fixed to the vacuum vessel 32 and the high voltage insulating member 6. In this embodiment, the tip of the fixed body 1 functions as a high voltage supply terminal 44. The high voltage insulating member 6 is formed in a tubular shape with one end having a conical shape and the other end closed. The high voltage insulating member 6 electrically insulates the fixed body 1 from the housing 20 and the stator coil 910.

  Further, an X-ray shielding part 510 is provided on one end side of the housing 20 facing the target layer 35a in the direction along the tube axis. The X-ray shielding unit 510 shields X-rays emitted from the target layer 35a. The X-ray shielding part 510 is made of a material containing an X-ray opaque material. The X-ray shielding part 510 has a first shielding part 511 and a second shielding part 512.

  The 1st shielding part 511 is affixed on the cover part 20g on the side facing the target layer 35a in the direction along the tube axis. The first shielding part 511 covers the entire lid part 20g. The first shielding portion 511 is formed by opening a portion facing the opening 20k, and keeps the coolant 7 in and out of the opening 20k. The second shielding part 512 is provided on the first shielding part 511. The second shielding part 512 shields X-rays that may be emitted to the outside of the housing 20 from the vicinity of the opening 20k.

  The X-ray shield 520 is formed in a cylindrical shape. One end of the X-ray shield 520 is close to the first shield 511. For this reason, X-rays that may be emitted from the gap between the X-ray shield 510 and the X-ray shield 520 can be shielded.

  The X-ray shield 520 extends along the tube axis from the first shield 511 to a position exceeding the anode target 35 (on the extended line of the surface of the target layer 35a). In this embodiment, the X-ray shield 520 extends from the first shield 511 to the front of the stator coil 910. The X-ray shield 520 is provided with a gap between the vacuum vessel 32 and the housing body 20a in the direction perpendicular to the tube axis.

  The X-ray shield 520 is fixed to at least one of the vacuum envelope 31 and the housing 20. Here, the X-ray shield 520 is fixed to a protrusion formed on the inner wall of the housing body 20a. The X-ray shield 520 is fixed to the vacuum envelope 31 by the insulating member 8.

  The X-ray shield 520 and the X-ray shield 510 form a passage through which the high voltage cable 71 passes. In order to prevent X-ray leakage from the passage to the outside of the housing 20, the passage is preferably a bottleneck. A part of the housing body 20e is formed to protrude in the radial direction. The protruding portion of the housing body 20e and the X-ray shield 520 form a passage (bottle way) through which the high voltage cable 71 passes.

  Although not shown, the X-ray shield 520 has an X-ray transmission window that transmits X-rays. The X-ray transmission window faces the X-ray emission window 20w. Here, the X-ray transmission window is an opening in which a part of the X-ray shield 520 is opened. Needless to say, the passage (high voltage cable 71) is out of the position facing the X-ray radiation window 20 w of the housing 20 and the X-ray transmission window of the X-ray shield 520.

  The X-ray shield 520 is made of a material containing an X-ray opaque material. The thickness of the X-ray shield 520 is 1 to 5 mm. Here, the thickness of the X-ray shield 520 is the shortest distance between the inner peripheral surface and the outer peripheral surface, and in this embodiment, is the distance between the inner peripheral surface and the outer peripheral surface in the direction perpendicular to the tube axis. In the direction perpendicular to the tube axis, the gap between the vacuum vessel 32 and the housing 20 is 3 to 12 mm. In this embodiment, the gap between the vacuum vessel 32 and the housing 20 is 8 mm.

  The X-ray shield 520 can be made of hard lead obtained by adding antimony or the like to lead, for example. Preferably, the X-ray shield 520 is formed by winding an X-ray opaque material around a cylindrical part made of SUS or the like.

  As the X-ray opaque material used for the X-ray shields 510 and 520, at least a metal composed of any one of tungsten, tantalum, molybdenum, barium, bismuth, rare earth metal and lead, or tungsten, tantalum, molybdenum, At least one of a compound of barium, bismuth, rare earth metal and lead can be used as a main material. The surfaces of the X-ray shields 510 and 520 may be formed with metal plating such as tin, silver, copper, or nickel, or a resin coating for corrosion protection.

  When the X-ray shield 520 has a certain degree of strength and ductility, the X-ray shield 520 can function as a protective body. When the anode target 35 is broken during high-speed rotation, fragments of the anode target 35 having high kinetic energy break the vacuum vessel 32 made of glass and further scatter in a direction toward the inner surface of the housing 20. The X-ray shield 520 protects the debris of the anode target 35 that scatters with high kinetic energy from colliding with the housing 20.

  Even if a fragment of the anode target 35 collides with the X-ray shield 520, the X-ray shield 520 can absorb kinetic energy by causing sufficient deformation. Since the X-ray shield 520 and the housing 20 are located with a gap, even if the X-ray shield 520 is deformed, the housing 20 itself can be prevented from being deformed. Thereby, the crack which may arise in the housing 20 can be prevented.

As shown in FIGS. 9 and 10, the housing 20 has a lid portion 20 n. The lid portion 20n closes the end portion of the housing body 20e together with the lid portion 20f. The opening 20o1 and the opening 20o2 are formed in the lid portion 20n. The opening 20 o 1 and the opening 20 o 2 are formed in the housing 20, deviating from positions facing (close to) the X-ray shield 510 and the X-ray shield 520.
The X-ray tube apparatus 10 includes an anode receptacle 300 and a cathode receptacle 400. The receptacles 300 and 400 are attached to the lid 20f. The receptacles 300 and 400 extend along the tube axis direction. The longitudinal direction of the housing 20 is parallel to the tube axis direction.

  The receptacle 300 has a housing 301 as an electrical insulating member and a terminal 302 as a high voltage supply terminal.

  The housing 301 extends from the opening 20o1 to a space between the X-ray tube 30 and the housing 20 in a direction orthogonal to the tube axis direction. The housing 301 is formed in a bowl shape that opens to the outside of the housing 20. It can be said that the housing 301 has a substantially axisymmetric cup shape. In addition, it can be said that the plug insertion port of the housing 301 is open to the outside of the housing 20.

  An annular protrusion is formed on the outer surface of the housing 301 at the end of the housing 301 on the opening side. The housing 301 is made of, for example, resin as an insulating material. The housing 301 is cooled by the coolant 7.

  The terminal 302 is liquid-tightly attached to the bottom of the housing 301 and penetrates the bottom. The terminal 302 is electrically connected to the other end of the high voltage cable 61 outside the housing 301.

  The electrically insulating member 64 is formed of an electrically insulating resin, fills the electrical connection portion between the terminal 302 and the high voltage cable 61, and is directly bonded to the housing 301. More specifically, the electrically insulating member 64 is formed of a molding material. By using the electrically insulating member 64, it is possible to improve the electrical insulation between the housing 20 and the electrical connection between the terminal 302 and the high voltage cable 61.

  In the tube axis direction, an O-ring is interposed between the step portion of the lid portion 20 n facing the opening 20 o 1 and the protruding portion of the housing 301. The stepped portion of the lid portion 20n is processed with a female screw. The ring nut 310 has a male thread on the side. The ring nut 310 is fastened to the step portion of the lid portion 20n and presses the housing 301. Thereby, in the tube axis direction, the O-ring is pressurized by the stepped portion of the lid portion 20n and the protruding portion of the housing 301. Thereby, since the receptacle 300 is liquid-tightly attached to the lid portion 20n, the leakage of the coolant 7 to the outside of the housing 20 can be prevented.

  The receptacle 300 and the plug (not shown) inserted into the receptacle 300 are non-surface pressure type and are detachable. With the plug connected to the receptacle 300, a high voltage (for example, +70 to +80 kV) is supplied from the plug to the terminal 302.

  The receptacle 400 is formed in the same manner as the receptacle 300. The receptacle 400 is provided on the lid portion 20n by using a ring nut 310, an O-ring, or the like, like the receptacle 300. The receptacle 400 is attached to the lid portion 20n so as to liquid-tightly close the opening 20o2. The electrical connection between the terminal (high voltage supply terminal) of the receptacle 400 and the high voltage cable 71 is filled with an electrically insulating member (74).

  According to the X-ray apparatus according to the eighth embodiment configured as described above, the X-ray tube apparatus 10 includes the X-ray tube 30, the housing 20, the coolant 7, and the cable assemblies 60 and 70. I have. The receptacles 300 and 400 are independent of the X-ray tube 30 and are provided in the housing 20 that is less affected by the heat generated by the X-ray tube 30.

  The high voltage supply terminal 44 electrically connected to the anode target 35 is exposed outside the vacuum envelope 31. The high voltage supply terminal 54 electrically connected to the cathode 36 is exposed from the high voltage insulating member 50 to the outside of the vacuum envelope 31.

  One end of the high voltage cable 61 is electrically connected to the high voltage supply terminal 44, and the other end is electrically connected to the terminal 302 through the space in the housing 20. One end of the high voltage cable 71 is electrically connected to the high voltage supply terminal 54, and the other end is electrically connected to the terminal of the receptacle 400 through the space in the housing 20. The receptacles 300 and 400 are located between the X-ray tube 30 and the housing 20 in a direction perpendicular to the tube axis of the X-ray tube device 10. Since the X-ray tube apparatus 10 is not a conventional structure in which a receptacle is provided between the X-ray tube 30 and the housing 20 in the direction along the tube axis of the X-ray tube apparatus 10, the X-ray tube apparatus 10 can be made smaller than the conventional structure. be able to.

  The coolant 7 is an insulating oil. The high voltage cable 61 is connected to the high voltage supply terminal 44 and the high voltage cable 71 is connected to the high voltage supply terminal 54 without using a surface pressure type connector. For this reason, the X-ray tube apparatus 10 can obtain high reliability over a long period of time.

  In the housing 20, the high voltage supply terminal 44 and the high voltage cable 61 are immersed in the coolant 7 from the vicinity of the outer wall of the X-ray tube 30 to the vicinity of the inner wall of the housing 20. The generated heat can be released to the coolant 7. Since heat transmitted from the anode target 35 to the electrical connection portion between the high voltage supply terminal 44 and the high voltage cable 61 can be released to the coolant 7, good insulation of the receptacle 300 can be maintained. .

  In the housing 20, the high voltage supply terminal 54 and the high voltage cable 71 are immersed in the coolant 7 from the vicinity of the outer wall of the X-ray tube 30 to the vicinity of the inner wall of the housing 20, so that they are transmitted from the cathode 36 to the high voltage cable 71. Heat can be released to the coolant 7. Since heat transmitted from the cathode 36 to the electrical connection portion between the high voltage supply terminal 54 and the high voltage cable 71 can be released to the coolant 7, good insulation of the receptacle 400 can be maintained.

  The X-ray shield 520 is made of a material containing an X-ray opaque material. Since the X-ray shield 520 can shield X-rays in directions other than the X-ray transmission window, for example, when the X-ray tube device is mounted on a medical diagnostic device, unnecessary radiation (exposure) to the human body. Can be prevented.

  The X-ray shield 520 is formed outside the housing 20 and then incorporated inside the housing 20. There is no need to affix a lead plate to the inner surface of the housing 20, and the cylindrical X-ray shield 520 can be easily manufactured as compared with the case where the lead plate is affixed, so that the manufacturing cost can be reduced. .

  When the X-ray shield 520 has a certain degree of strength and ductility, the X-ray shield 520 can function as a protective body. The X-ray shield 520 protects the debris of the anode target 35 that is scattered with high kinetic energy from colliding with the housing 20 when the anode target 35 is broken during high-speed rotation. Even if a fragment of the anode target 35 collides with the X-ray shield 520, the X-ray shield 520 can absorb kinetic energy by causing sufficient deformation.

  Further, in this embodiment, the inner surface of the housing 20 can be straight as compared with the conventional structure. For this reason, the X-ray shield 520 can be easily incorporated into the housing 20, and the X-ray shield 520 can be easily taken out of the housing 20.

Thereby, the crack which may arise in the housing 20 can be prevented. For example, when a rotating anode type X-ray tube device is mounted on a medical diagnostic instrument, the risk that the high-temperature coolant 7 may be applied to an object to be inspected (for example, a human body) can be eliminated.
From the above, it is possible to obtain the X-ray tube apparatus 10 and the X-ray apparatus including the X-ray tube apparatus that can be downsized and can obtain high reliability over a long period of time.

Next, a modification of the X-ray apparatus according to the eighth embodiment will be described.
For example, the X-ray tube apparatus 10 may include the electrical insulating members 81 and 91 (FIG. 8) according to the seventh embodiment. Thereby, the insulation between the high voltage supply terminal 44 and the housing 20 and the insulation between the high voltage supply terminal 54 and the housing 20 can be further secured.

  The coolant 7 can use an aqueous coolant instead of the insulating oil. However, in this case, the X-ray tube apparatus 10 includes the electrically insulating members 81 and 91 (FIGS. 1 to 7) according to the first to sixth embodiments, and the electrically insulating members 81 and 91 are supplied with a high voltage. The electrical connection between the terminal 44 (54) and one end of the high voltage cable 61 (71) is filled.

  When the electrically insulating member 81 is molded, the high voltage supply terminal 44 and the high voltage cable 61 are electrically connected and the X-ray tube 30 is accommodated in the housing 20. When the electrically insulating member 91 is molded, the high voltage supply terminal 54 and the high voltage cable 71 are electrically connected and the X-ray tube 30 is accommodated in the housing 20.

  Moreover, when utilizing a water-system coolant, it is preferable that the X-ray apparatus further includes a heat shrinkable tube (not shown). The heat-shrinkable tube covers at least the surface of the high voltage cable 61 (71) in contact with the aqueous coolant and is formed of a resin that does not contain chloride. When covering the surface of the high-voltage cable 61 (71), the high-voltage cable 61 (71) is covered with a heat-shrinkable tube having a diameter larger than that of the high-voltage cable 61 (71), and heat is applied to the heat-shrinkable tube. As a result, the heat-shrinkable tube contracts, and the surface of the high voltage cable 61 (71) is covered with the heat-shrinkable tube. The heat-shrinkable tube can be formed of any material of, for example, ethylene propylene rubber, silicone rubber, polyolefin, and polyethylene.

  The surface of the high voltage cable 61 (71) in contact with the aqueous coolant is covered with a heat shrinkable tube formed of a resin not containing chloride. Since elution of chloride ions into the aqueous coolant can be prevented, metal corrosion can be reduced. The above is effective when the covering material (outermost periphery covering material) of the high voltage cable 61 (71) contains chlorine.

Further, when a resin mold material is used for forming the electrical insulating members 81 and 91, the heat shrinkable tube as described above has excellent adhesion to the resin mold material, and thus contributes to prevention of electric leakage. it can. Preferably, the adhesion to the resin mold material can be further improved by applying a treatment for applying various primers including SiO ₂ and TiO ₂ .

On the other hand, according to the experience of the inventors of the present application, when the outermost periphery covering material of the high voltage cable 61 (71) contains chloride, even if it is attempted to mold the outermost periphery covering material with an epoxy resin or a silicone resin, the adhesiveness is low. There is a problem that it is bad, and even if the surface of the coating material is subjected to a treatment for applying various primers including SiO ₂ or TiO ₂ , the adhesion is not improved, and there is a possibility of leakage through the adhesion interface.

  The position of the X-ray radiation window 20w is not limited to the example shown in FIG. 10 and may be variously modified and may be a position that does not face the high voltage cables 61 and 71. As shown in FIG. 11, the X-ray radiation window 20w may be located.

  In the example shown in FIGS. 10 and 11, since the lid portion 20n is used, the size of the housing 20 is expanded downward in the drawing. The receptacle 300 and the receptacle 400 are provided without sandwiching the X-ray tube 30. However, the positions of the receptacle 300 and the receptacle 400 are not limited to the examples shown in FIGS. 10 and 11 and can be variously modified.

  For example, as shown in FIG. 12, the receptacle 300 and the receptacle 400 may be provided with the X-ray tube 30 interposed therebetween. The housing 20 has lid portions 20p and 20q instead of the lid portion 20n. In this example, since the lid portions 20p and 20q are used, the size of the housing 20 is enlarged in the left-right direction in the figure. The receptacle 300 is liquid-tightly attached to the lid 20p, and the receptacle 400 is liquid-tightly attached to the lid 20q.

  Further, the receptacle 300 and the plug, and the receptacle 400 and the plug may be a surface pressure type. In this case, the plug is brought into close contact with the inner surfaces of the housings 301 and 401 (electrical insulating members). When the connection method of the receptacles 300 and 400 is a surface pressure type, the receptacles 300 and 400 can be downsized.

  In the above case, as shown in FIG. 13, the housing 20 is not partially arcuate, but the receptacles 300 and 400 and the lid 20p are not enlarged so that the size of the housing 20 does not increase in the vertical direction or the horizontal direction. , 20q can be provided.

Next, Comparative Example 1 and Comparative Example 2 of the X-ray apparatus according to the above-described embodiment will be described.
FIG. 14 is a cross-sectional view showing Comparative Example 1 of the X-ray apparatus according to the above-described embodiment.
As shown in FIG. 14, the X-ray tube apparatus 10 of Comparative Example 1 is different from the X-ray tube apparatus 10 according to the first embodiment in that the high-voltage cables 61 and 71, the high-voltage connectors 62 and 72, and the electrical insulation property It is formed without the members 81 and 91. Since the high voltage supply terminals 44 and 54 are in contact with the coolant 7, the coolant 7 is an insulating oil. The X-ray tube apparatus 10 includes an anode receptacle 300 and a cathode receptacle 400.

  In the direction along the tube axis, the receptacle 300 is provided between the X-ray tube 30 (high voltage insulating member 40) and the housing 20. The receptacle 300 has a bottomed cylindrical housing 301 and a terminal 302. The housing 301 is airtightly attached to the housing 20. The housing 301 is made of, for example, resin as an insulating material. The terminal 302 is provided in the housing 301. The terminal 302 is electrically connected to the high voltage supply terminal 44 by a cable.

  The receptacle 300 and a plug (not shown) are non-surface pressure type and are detachable. With the plug connected to the receptacle 300, the receptacle 300 supplies a high voltage (for example, +70 to +80 kV) to the high voltage supply terminal 44.

  In the direction along the tube axis, the receptacle 400 is provided between the X-ray tube 30 (high voltage insulating member 50) and the housing 20. The receptacle 400 includes a bottomed cylindrical housing 401 and terminals 402. The housing 401 is airtightly attached to the housing 20. The housing 401 is made of, for example, a resin as an insulating material. The terminal 402 is provided in the housing 401. The terminal 402 is electrically connected to the high voltage supply terminal 54 by a cable.

  The receptacle 400 and other plugs (not shown) are non-surface pressure type and are detachable. With the plug connected to the receptacle 400, the receptacle 400 supplies a high voltage (for example, −70 to −80 kV) and a filament current to the high voltage supply terminal 54.

  In the X-ray apparatus of Comparative Example 1 configured as described above, since the X-ray tube apparatus 10 has a structure in which a receptacle is provided, the X-ray tube apparatus 10 cannot be downsized. An aqueous coolant cannot be used for the coolant 7. The high voltage supply terminals 44 and 54 are in contact with the coolant, but the cables connected to the high voltage supply terminals 44 and 54 are not formed to extend to the vicinity of the inner wall of the housing 20, and are supplied with a higher voltage than the housing 20. It is connected to terminals 302 and 402 located near the terminals 44 and 54.

FIG. 15 is a cross-sectional view showing a comparative example 2 of the X-ray apparatus according to the above-described embodiment.
As shown in FIG. 15, the X-ray tube device 10 of Comparative Example 2 is formed without the cable assemblies 60 and 70 and the electrically insulating members 81 and 91, unlike the X-ray tube device 10 according to the first embodiment. ing. As the coolant 7, an aqueous coolant or insulating oil can be used.

  The housing 20 is formed in a cylindrical shape. The outer surface of the high voltage insulating member 40 is exposed to the outside of the housing 20 together with the high voltage supply terminal 44. The outer surface of the high voltage insulating member 50 is exposed to the outside of the housing 20 together with the high voltage supply terminal 54.

The high-voltage connector 100 includes a bottomed cylindrical housing 101, a cable 102 having a tip inserted into the housing 101, and the housing 101 filled with the terminal of the cable 102 facing the opening side of the housing 101. A fixing portion 103 to be fixed and a silicone plate 104 made of a silicone resin material inserted between the fixing portion 103 and the outer surface of the high voltage insulating member 40 are provided. In this embodiment, the cable 102 is a high voltage cable. The fixing part 103 is an electrically insulating rubber part. Note that the fixing portion 103 may be in direct contact with the outer surface of the high voltage insulating member 40. The high voltage connector 100 provides a high voltage to the high voltage supply terminal 44.
When the high voltage connector 100 is attached to the housing 20, the silicone plate 104 is pressed so as to be in close contact with the fixing portion 103 and the outer surface of the high voltage insulating member 40.

The high-voltage connector 200 includes a bottomed cylindrical housing 201, a cable 202 having a tip inserted into the housing 201, and the housing 201 filled with the terminal of the cable 202 facing the opening of the housing 201. A fixing portion 203 to be fixed, and a silicone plate 204 made of a silicone resin material inserted between the fixing portion 203 and the outer surface of the high voltage insulating member 50 are provided. In this embodiment, cable 202 is a high voltage cable. The fixing part 203 is an electrically insulating rubber part. Note that the fixing portion 203 may be in direct contact with the outer surface of the high voltage insulating member 50. The high voltage connector 200 applies a high voltage to the high voltage supply terminal 54.
When the high voltage connector 200 is attached to the housing 20, the silicone plates 204 are pressed so as to be in close contact with the fixing portion 203 and the outer surface of the high voltage insulating member 50.

  In the X-ray apparatus of Comparative Example 2 configured as described above, the high voltage supply terminals 44 and 54 are not in contact with the coolant but are directly connected to the high voltage connectors 100 and 200. Since the heat transmitted from the anode target 35 to the high voltage supply terminal 44 and the heat transmitted from the cathode 36 to the high voltage supply terminal 54 cannot be sufficiently transmitted to the coolant 7, the heat generated in the X-ray tube There is a problem that radioactivity cannot be improved.

Heat generated in the X-ray tube is transferred to the high voltage connectors 100 and 200.
Then, the fixing portion (electrically insulating rubber portion) 103 of the high voltage connector 100 and the silicone plate 104 are overheated exceeding the allowable temperature, and the adhesion between the high voltage connector 100 and the high voltage insulating member 40 may be reduced. There is. Then, the discharge along the adhesion interface between the high voltage connector 100 and the high voltage insulating member 40 occurs relatively early.

In addition, the fixing portion (electrically insulating rubber portion) 203 and the silicone plate 204 of the high voltage connector 200 are overheated beyond the allowable temperature, and the adhesion between the high voltage connector 200 and the high voltage insulating member 50 may be reduced. There is. Then, discharge along the adhesion interface between the high voltage connector 200 and the high voltage insulating member 50 occurs relatively early.
For this reason, there is also a problem that high reliability (insulation) cannot be obtained over a long period of time.

As described above, the case where the flat surface pressure connector as shown in FIG. 15 is used as a comparative example has been described. However, the same problem occurs when the pressing surface is a tapered concave surface or a convex surface as well as the flat surface type. is there.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  For example, the shape of the housing 20 is not limited to the above-described example and can be variously modified, and may be formed by combining a plurality of members.

  The X-ray tube apparatus 10 is not limited to the neutral point grounding type in which a high voltage is applied to the anode target 35 and the cathode 36, and various modifications can be made. For example, in the case of the grounded anode X-ray tube apparatus 10, the above-described high voltage insulation structure may be employed only on the cathode 36 side. In the case of the cathode-grounded X-ray tube apparatus 10, the above-described high voltage insulation structure and cooling structure may be employed only on the anode target 35 side.

  Contact surface of the high voltage connector 62 (end surface 64s of the electrical insulating member 64, end surface 65s of the high voltage insulating member 65), contact surface of the high voltage connector 72 (end surface 74s of the electrical insulating member 74, high voltage insulating member 75) The end surface 75s) is not limited to a flat surface and can be variously modified, and may be a tapered convex surface or a tapered concave surface. In this case, the shape of the pressing surface of the high voltage connectors 100 and 200 only needs to correspond to the shape of the contact surfaces of the high voltage connectors 62 and 72 so that good adhesion can be obtained. The high voltage connectors 62 and 72 can also use conventional receptacles that are not surface pressure type.

  Peripheral technologies necessary for using the coolant 7 in the housing 20 as an aqueous coolant are disclosed in the following patent documents, and these are necessary for applying the above-described embodiment of the present invention to an actual X-ray tube. It is effective to use peripheral technologies together.

US Pat. No. 7,203,280 (mold related)
US Pat. No. 7,206,380 (Coolant related)
US Patent Application Publication No. 11/401300 (Coating)
As the high-voltage insulating member, alumina can be used. However, if ceramics having a higher thermal conductivity than alumina such as aluminum nitride or beryllia is used, the effect becomes higher.

  Epoxy resin, polyurethane resin, silicone resin, etc. can be used as the molding material and electrical insulating member, but in order to increase the thermal conductivity, insulating materials with high thermal conductivity such as alumina and aluminum nitride are used. It is preferable to mix fine powder.

The present invention is not limited to the above X-ray apparatus and can be applied to various X-ray apparatuses. The X-ray tube apparatus is not limited to a rotary anode type X-ray tube apparatus, but may be a fixed anode type X-ray tube apparatus .
Hereinafter, the invention described in the scope of claims of the present application will be appended.
[1] A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an anode target provided in the vacuum envelope to irradiate the anode target An X-ray tube comprising: a cathode that emits electrons; and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode. When,
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
An X-ray comprising: a high-voltage connector having an electrical insulating material that is directly or indirectly adhered to an end face of the electrical insulating member, and applying a high voltage to the second high-voltage supply terminal. Tube equipment.
[2] The X-ray tube apparatus according to [1], wherein an end surface of the electrical insulating member is a flat surface.
[3] The electrical insulation member has another high voltage insulation member having the end face, and an electrical insulation member,
The other high-voltage insulating member has a hole that opens to the inside of the housing and exposes the second high-voltage supply terminal,
The other end of the high voltage cable is electrically connected to the second high voltage supply terminal through the hole,
The X-ray tube device according to [1] or [2], wherein the electrical insulating member is filled in the hole portion and fills up the second electrical connection portion.
[4] A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an anode target provided in the vacuum envelope to irradiate the anode target An X-ray tube comprising: a cathode that emits electrons; and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode. When,
A housing having an opening opened in a tube axis direction and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
An electrical insulating member that extends from the opening to the space in a direction orthogonal to the tube axis direction, is formed in a bowl shape that opens to the outside of the housing, and is cooled by the coolant, and a bottom portion of the electrical insulating member A receptacle having a second high voltage supply terminal penetrating through
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space. X-ray tube device characterized by the above.
[5] The longitudinal direction of the housing is parallel to the tube axis direction,
The X-ray tube apparatus according to [4], wherein the receptacle extends along the tube axis direction.
[6] The X-ray tube device according to [4], further comprising a plug that is in close contact with an inner surface of the electrical insulating member and applies a high voltage to the second high voltage supply terminal.
[7] The method further comprises an electrically insulating member that covers a first electrical connection portion between the first high-voltage supply terminal and the high-voltage cable and is cooled directly or indirectly by the coolant. The X-ray tube device according to [1] or [4].
[8] In the above [7], the electrical insulating member is formed of a molding material, fills the first electrical connection portion, and is directly bonded to the outer surface of the high voltage insulating member. The X-ray tube apparatus described.
[9] The high voltage insulating member has a hole that opens to the outside of the vacuum envelope and exposes the first high voltage supply terminal.
One end of the high voltage cable is electrically connected to the first high voltage supply terminal through the hole,
The X-ray tube device according to [7], wherein the electrical insulating member is filled in the hole and fills the first electrical connection portion.
[10] Other high voltage insulating members having an adhesive surface;
An adhesive member for adhering the adhesive surface of the other high-voltage insulating member to the outer surface of the high-voltage insulating member;
The first high voltage supply terminal includes a first divided portion exposed to the outside from the high voltage insulating member and a second divided portion provided on the other high voltage insulating member and electrically connected to the first divided portion. And
The other high-voltage insulating member has a hole that is open at a position deviated from the bonding surface and from which the second divided portion is exposed,
One end of the high-voltage cable is electrically connected to the second divided part through the hole,
The X-ray tube device according to [7], wherein the electrical insulating member is filled in the hole and fills the first electrical connection portion.
[11] The X-ray tube device according to [10], wherein the other high-voltage insulating member is formed of an electrically insulating resin.
[12] The X-ray tube device according to [10], wherein the other high-voltage insulating member is formed of a molding material.
[13] An adhesive member is further provided,
The first high voltage supply terminal has a first divided part exposed to the outside from the high voltage insulating member, and a second divided part electrically connected to the first divided part,
The electrically insulating member is formed of a molding material, has an adhesive surface, fills an electrical connection portion between the second divided portion and the high voltage cable, and exposes the second divided portion to the outside.
The X-ray tube apparatus according to [7], wherein the adhesive member has an adhesive surface of the electrically insulating member adhered to an outer surface of the high-voltage insulating member.
[14] The electrically insulating member is located at a distance from the high voltage insulating member,
The X-ray tube apparatus according to [7], wherein the coolant is insulating oil and is interposed between the electrical insulating member and the high voltage insulating member.
[15] The X-ray tube device according to any one of [8] to [13], wherein the coolant is an aqueous coolant.
[16] The cooling liquid circulation pump according to any one of [1] to [15], further comprising a cooling liquid circulation pump connected to the housing and configured to generate a flow of the cooling liquid in the housing. X-ray tube device.
[17] The X-ray tube device according to [16], further comprising a heat exchanger connected between the housing and the coolant circulation pump and releasing the heat of the coolant to the outside.
[18] A vacuum envelope partially formed of a first high-voltage insulating member and a second high-voltage insulating member, an anode target provided in the vacuum envelope, and a vacuum envelope in the vacuum envelope A cathode which is provided and emits electrons for irradiating the anode target; and a first high voltage supply terminal which is exposed to the outside of the vacuum envelope from the first high voltage insulating member and is electrically connected to the anode target. An X-ray tube having a second high voltage supply terminal exposed from the second high voltage insulating member to the outside of the vacuum envelope and electrically connected to the cathode;
A housing having a first opening and a second opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A third high voltage supply terminal exposed to the outside of the housing through the first opening;
A first high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the third high voltage supply terminal through the space;
An end surface exposed to the outside of the housing through the first opening, covers a second electrical connection between the third high voltage supply terminal and the first high voltage cable, and is cooled by the coolant. A first electrically insulating member;
A first high voltage connector having a first electrical insulating material that is directly or indirectly adhered to an end face of the first electrical insulating member, and applying a high voltage to the third high voltage supply terminal;
A fourth high voltage supply terminal exposed to the outside of the housing through the second opening;
A second high voltage cable having one end electrically connected to the second high voltage supply terminal and the other end electrically connected to the fourth high voltage supply terminal through the space;
It has an end surface exposed to the outside of the housing through the second opening, covers a fourth electrical connection between the fourth high voltage supply terminal and the second high voltage cable, and is cooled by the coolant. A second electrical insulating member,
A second high voltage connector having a second electrical insulation material that is directly or indirectly adhered to the end face of the second electrical insulation member, and applying a high voltage to the fourth high voltage supply terminal. X-ray tube device characterized by the above.
[19] A vacuum envelope partially formed of a first high-voltage insulating member and a second high-voltage insulating member, an anode target provided in the vacuum envelope, and a vacuum envelope in the vacuum envelope A cathode which is provided and emits electrons for irradiating the anode target; and a first high voltage supply terminal which is exposed to the outside of the vacuum envelope from the first high voltage insulating member and is electrically connected to the anode target. An X-ray tube having a second high voltage supply terminal exposed from the second high voltage insulating member to the outside of the vacuum envelope and electrically connected to the cathode;
A housing having a first opening and a second opening opened in a tube axis direction and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A first electric insulating member extending from the first opening to the space in a direction perpendicular to the tube axis direction, formed in a bowl shape opened to the outside of the housing, and cooled by the coolant; A first receptacle having a third high voltage supply terminal penetrating the bottom of the one electrical insulating member;
A first high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the third high voltage supply terminal through the space;
A second electrical insulating member extending from the second opening to the space in a direction perpendicular to the tube axis direction, formed in a bowl shape opened to the outside of the housing, and cooled by the coolant; A second receptacle having a fourth high voltage supply terminal penetrating the bottom of the two electrical insulating members;
A second high voltage cable having one end electrically connected to the second high voltage supply terminal and the other end electrically connected to the fourth high voltage supply terminal through the space. An X-ray tube device characterized by comprising:

  DESCRIPTION OF SYMBOLS 1 ... Fixed body, 2 ... Rotating body, 7 ... Coolant, 10 ... X-ray tube apparatus, 20 ... Housing, 20o1, 20o2 ... Opening, 22 ... Cooler, 23 ... Coolant circulation pump, 24 ... Heat exchanger, DESCRIPTION OF SYMBOLS 30 ... X-ray tube, 31 ... Vacuum envelope, 35 ... Anode target, 36 ... Cathode, 6, 40, 50 ... High voltage insulation member, 41, 42, 51, 52 ... Hole, 44, 54 ... High voltage Supply terminal, 44a, 54a ... 1st division part, 44b, 54b ... 2nd division part, 60, 70 ... Cable assembly, 61, 71 ... High voltage cable, 62, 72 ... High voltage connector, 64, 74 ... Electrical insulation 64s, 74s ... end face, 65, 75 ... high voltage insulation member, 65s, 75s ... end face, 68, 78 ... hole, 69, 79 ... high voltage supply terminal, 81, 91 ... electrical insulation member, 81s , 91s ... Adhesive surface, 82, 92 ... High electricity Insulating member, 82s, 92s ... Adhesive surface, 83, 93 ... Hole, 84, 94 ... Adhesive member, 100, 200 ... High voltage connector, 101, 201 ... Housing, 102, 202 ... Cable, 103, 203 ... Fixed part 104, 204 ... silicone plate, 300, 400 ... receptacle, 301 ... housing, 302 ... terminal, 510, 520 ... X-ray shield.

Claims (6)

A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an electron provided in the vacuum envelope for emitting the irradiation to the anode target An X-ray tube, and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode;
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
A high voltage connector that has an electrical insulating material that is directly or indirectly adhered to an end face of the electrical insulating member, and that applies a high voltage to the second high voltage supply terminal;
The electrical insulation member has another high voltage insulation member having the end face, and an electrical insulation member,
The other high-voltage insulating member has a hole that opens to the inside of the housing and exposes the second high-voltage supply terminal,
The other end of the high voltage cable is electrically connected to the second high voltage supply terminal through the hole,
Said electrically insulating member is filled in the hole, it X-ray tube device it said that fills the second electrical connection portion. A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an electron provided in the vacuum envelope for emitting the irradiation to the anode target An X-ray tube, and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode;
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
A high-voltage connector having an electrical insulating material that is directly or indirectly adhered to the end face of the electrical insulating member, and applying a high voltage to the second high-voltage supply terminal;
An electrical insulating member that covers a first electrical connection between the first high-voltage supply terminal and the high-voltage cable and is cooled directly or indirectly by the coolant;
The high voltage insulating member has a hole that opens to the outside of the vacuum envelope and exposes the first high voltage supply terminal,
One end of the high voltage cable is electrically connected to the first high voltage supply terminal through the hole,
Said electrically insulating member is filled in the hole, it X-ray tube device it said that fills the first electrical connection unit. A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an electron provided in the vacuum envelope for emitting the irradiation to the anode target An X-ray tube, and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode;
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
A high-voltage connector having an electrical insulating material that is directly or indirectly adhered to the end face of the electrical insulating member, and applying a high voltage to the second high-voltage supply terminal;
An electrically insulating member that covers a first electrical connection between the first high-voltage supply terminal and the high-voltage cable and is cooled directly or indirectly by the coolant;
Another high voltage insulating member having an adhesive surface;
E Bei and a bonding member for bonding the adhesive surface of the other high-voltage insulating member to the outer surface of the high voltage insulation member,
The first high voltage supply terminal includes a first divided portion exposed to the outside from the high voltage insulating member and a second divided portion provided on the other high voltage insulating member and electrically connected to the first divided portion. And
The other high-voltage insulating member has a hole that is open at a position deviated from the bonding surface and from which the second divided portion is exposed,
One end of the high-voltage cable is electrically connected to the second divided part through the hole,
Said electrically insulating member is filled in the hole, it X-ray tube device it said that fills the first electrical connection unit. The X-ray tube apparatus according to claim 3, wherein the other high voltage insulating member is formed of an electrically insulating resin. The X-ray tube apparatus according to claim 3, wherein the other high-voltage insulating member is formed of a molding material. A vacuum envelope partially formed of a high voltage insulating member, an anode target provided in the vacuum envelope, and an electron provided in the vacuum envelope for emitting the irradiation to the anode target An X-ray tube, and a first high-voltage supply terminal that is exposed from the high-voltage insulating member to the outside of the vacuum envelope and is electrically connected to one of the anode target and the cathode;
A housing having an opening and containing the X-ray tube;
A coolant filled in a space between the X-ray tube and the housing;
A second high voltage supply terminal exposed outside the housing through the opening;
A high voltage cable having one end electrically connected to the first high voltage supply terminal and the other end electrically connected to the second high voltage supply terminal through the space;
An electrically insulating member having an end surface exposed to the outside of the housing through the opening, covering a second electrical connection portion between the second high voltage supply terminal and the high voltage cable, and being cooled by the coolant When,
A high-voltage connector having an electrical insulating material that is directly or indirectly adhered to the end face of the electrical insulating member, and applying a high voltage to the second high-voltage supply terminal;
An electrically insulating member that covers a first electrical connection between the first high-voltage supply terminal and the high-voltage cable and is cooled directly or indirectly by the coolant;
An adhesive member, the Bei example,
The first high voltage supply terminal has a first divided part exposed to the outside from the high voltage insulating member, and a second divided part electrically connected to the first divided part,
The electrically insulating member is formed of a molding material, has an adhesive surface, fills an electrical connection portion between the second divided portion and the high voltage cable, and exposes the second divided portion to the outside.
The adhesive member, X-ray tube device you said that to adhere the adhesive surface of the electrically insulating member to the outer surface of the high voltage insulation member.

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