Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J35/00—X-ray tubes
  • H01J35/02—Details
  • H01J35/14—Arrangements for concentrating, focusing, or directing the cathode ray
  • H01J35/153—Spot position control
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J35/00—X-ray tubes
  • H01J35/02—Details
  • H01J35/14—Arrangements for concentrating, focusing, or directing the cathode ray
  • H01J35/147—Spot size control
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J35/00—X-ray tubes
  • H01J35/02—Details
  • H01J35/14—Arrangements for concentrating, focusing, or directing the cathode ray
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J35/00—X-ray tubes
  • H01J35/02—Details
  • H01J35/16—Vessels; Containers; Shields associated therewith
  • H01J35/18—Windows
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05G—X-RAY TECHNIQUE
  • H05G1/00—X-ray apparatus involving X-ray tubes; Circuits therefor
  • H05G1/08—Electrical details
  • H05G1/26—Measuring, controlling or protecting
  • H05G1/30—Controlling
  • H05G1/32—Supply voltage of the X-ray apparatus or tube
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J2235/00—X-ray tubes
  • H01J2235/16—Vessels
  • H01J2235/165—Shielding arrangements

Definitions

• the present invention relates to an apparatus for generating X-radiation according to claim 1 and to a method for operating an apparatus for generating X-radiation according to claim 13.
• X-ray tubes for generating X-radiation are known from the prior art.
• X-ray tubes have a cathode for emitting electrons. The emitted electrons are accelerated by a high voltage to an anode. In the anode, the electrons are decelerated and thereby generate X-ray Bremsstrahlung and characteristic X-rays.
• the X-ray Bremsstrahlung has a broad spectral distribution, while the characteristic X-radiation has a discrete line spectrum. In the X-ray radiated from the X-ray tube both types of radiation are superimposed.
• characteristic X-radiation with discrete energies is better suited than X-ray bremsstrahlung. It is known to filter X-radiation with metallic filters in order to reduce the brake radiation component. However, such filters also dampen the proportion of characteristic X-rays.
• An inventive device for generating X-ray radiation comprises an anode with a target layer, a cathode for emitting an electron beam, a deflection unit for deflecting the electron beam onto the
• Target layer by means of an electric field, a focusing unit for focusing the electron beam and an X-ray window for coupling out in the target layer of the anode generated X-radiation in a on the
• the cathode is arranged laterally offset relative to the outgoing from the anode rearward direction.
• this device can be made particularly compact.
• the focusing unit can advantageously produce a particularly small focal spot of the electron beam on the anode.
• the deflection unit advantageously allows x-ray radiation generated by the anode to be conducted away in a direction which is rearward with respect to the direction of the electrons striking the anode. As a result, the emitted X-radiation has a low relative proportion of X-ray Bremsstrahlung and
• the focusing unit is arranged in the direction of advance of the electron beam behind the deflection unit.
• the focusing unit can then focus the electron beam directly onto a point of the target layer of the anode.
• the deflection unit comprises a curved screen tube.
• a first electrode and a second electrode are arranged within the shield tube.
• the focusing unit comprises an inner shell.
• the anode is arranged inside the inner shell.
• the focusing unit can then focus the electron beam onto the anode.
• the anode is arranged in a field-free area.
• the inner shell is formed as a spherical shell.
• the focusing unit then has a high degree of symmetry, as a result of which well-defined electric fields can be generated.
• the focusing unit comprises an outer shell, wherein the outer shell at least partially surrounds the inner shell.
• the electron beam can then be focused between the outer shell and the inner shell.
• the electrons of the electron beam between the outer shell and the inner shell can be accelerated in the direction of movement.
• the outer shell is formed as a spherical shell.
• the outer shell is formed as Kugelkalottenschale.
• this also results in a compact, simple and symmetrical design of the focusing unit.
• the inner shell and the outer shell each have at least one opening, which is intended to allow the electron beam to pass.
• the electron beam can then be directed and focused onto an anode arranged in the inner shell.
• this has a collector which is intended to catch electrons of the electron beam which have penetrated the anode.
• the electrons collected by the collector can be fed back into a circuit, which improves the energy efficiency of the device.
• the collector and the outer shell of the focusing unit together enclose the inner shell of the focusing unit.
• the collector is then suitable for collecting electrons scattered in a large solid angle range.
• the collector has a cylindrical portion, wherein the cylindrical portion of the collector connects to the outer shell.
• the outer shell and the cylindrical portion are electrically isolated from each other.
• the collector is then suitable for collecting a large part of the electrons of the electron beam directed towards the anode.
• the collector can be advantageously placed on a different electrical potential than the outer shell of the focusing.
• the shield tube and the outer shell are placed on a first electrical voltage against the cathode. This will be the first
• the inner shell is placed on a third electrical voltage against the cathode.
• the first voltage has a more positive voltage value than the second voltage.
• the third voltage has a more positive voltage value than the first voltage.
• the electron beam is then deflected in the deflection unit.
• the electron beam is focused between the outer shell and the inner shell of the focusing purity.
• the electrons of the electron beam between the outer shell and the inner shell are accelerated in the direction of movement.
• the second electrode is also placed on the first electrical voltage against the cathode.
• the electrons of the electron beam then experience no change in their speed amount within the deflection unit.
• the collector is placed on a fourth electrical voltage against the cathode.
• the fourth voltage has a more positive voltage value than the first voltage.
• the third voltage has a more positive voltage value than the fourth voltage.
• electrons of the electron beam which have penetrated the anode are then decelerated by the collector, whereby a part of the energy of the electrons is recovered.
• the method advantageously has a high energy efficiency.
• FIG. 1 is a schematic sectional view of a device for generating X-ray radiation according to a first embodiment
• Figure 2 is a schematic perspective view of the device for generating X-radiation
• Figure 3 is a schematic sectional view of a device for generating X-radiation according to a second embodiment
• FIG. 4 is a schematic perspective view of the device for generating X-radiation of the second embodiment.
• FIG. 1 shows a highly schematic sectional view of an apparatus 100 for generating X-ray radiation.
• the components of the X-ray generating device 100 shown in FIG. 1 may be arranged in a vacuum tube.
• the X-ray generating device 100 may also be called an X-ray tube.
• Figure 2 shows a schematic perspective view of the device 100 for generating the X-radiation. For reasons of clarity, some components of the device 200 are not shown in FIG.
• the device 100 has a cathode 200.
• the cathode 200 is designed to emit electrons to produce an electron beam 210.
• the cathode 200 may emit the electrons, for example by thermal emission or by field emission.
• the device 100 further comprises a deflection unit 300.
• the deflection unit 300 is intended to remove the radiation from the cathode. de 200 outgoing electron beam to deflect 210, so to change the direction of the electron beam 210.
• the deflection unit 300 comprises a curved screen tube 330 made of an electrically conductive material, for example a metal.
• a first longitudinal end 331 of the shield tube 330 faces the cathode 200. Electrons of the electron beam 210 emitted by the cathode 200 may penetrate the shield tube 330 through the first longitudinal end 330.
• a first electrode 310 and a second electrode 320 are arranged within the shield tube 330 of the deflection unit 300.
• the first electrode 310 and the second electrode 320 each have the shape of elongate and curved bands and extend substantially parallel to each other in the longitudinal direction of the screen tube 330.
• the curvature of the electrodes 310, 320 substantially corresponds to the curvature of the screen tube 330.
• the electrodes 310 , 320 are spaced from each other.
• a center axis of the shield tube 330 extends between the first electrode 310 and the second electrode 320.
• the first electrode 310 and the second electrode 320 are each made of an electrically conductive material such as metal.
• Electrons of the electron beam 210 entering the shield tube 330 at the first longitudinal end 331 of the shield tube 330 can pass through the shield tube 330 between the first electrode 310 and the second electrode 320.
• electrical voltages of suitable magnitude applied to the first electrode 310, the second electrode 320 and the shield tube 330 electrical fields prevail inside the shield tube 330 of the deflection unit 300, which deflects the electrons of the electron beam 310 during their passage through the shield tube 330 in such a way that the Electron beam 210 follows the curvature of the screen tube 330. This changes the direction of the electron beam 210.
• the electrons of the electron beam 210 leave the shield tube 330 at its second longitudinal end 332.
• the device 100 for generating X-ray radiation further comprises a focusing unit 400.
• the focusing unit 400 serves to focus the electron beam 210 onto a focal spot of a target layer 510 of an anode 500. This is done with the aim of producing a focal spot with the smallest possible diameter, which is advantageous for medical purposes such as angiography, for example.
• the focusing unit 400 in the illustrated embodiment comprises an outer shell 410 and an inner shell 420.
• the outer shell 410 and the inner shell 420 are each made of electrically conductive material, for example of metal.
• the outer shell 410 and the inner shell 420 are each formed as spherical shells.
• the outer shell 410 and the inner shell 420 are arranged concentrically with each other.
• the outer shell 410 has a first opening 411.
• the inner shell 420 has a first opening 421. From the center of the coaxially arranged shells 410, 420, the first opening 421 of the inner shell 420 and the first opening 411 of the outer shell 410 are in a common radial direction, that of the second
• Longitudinal end 332 of the shield tube 330 of the deflection 300 faces. Electron of the electron beam 210 exiting the shield tube 330 of the deflector 300 through the second longitudinal end 332 may penetrate into the focusing unit 400 through the first opening 411 of the outer shell 410 and the first opening 421 of the inner shell 420.
• outer shell 410 and inner shell 420 may be other than spherical (eg, ellisoidal), and may not necessarily be coaxially disposed.
• electrical voltages of suitable magnitude are applied to the outer shell 410 and the inner shell 420 of the focusing unit 400, a focus is formed between the outer shell 410 and the inner shell 420 of the focusing unit 400.
• focusing causes the electron beam 210 to pass between the first opening 411 of the outer shell 410 and the first opening 421 of the inner shell 420.
• the electron beam 210 is thereby focused by the radial course of the electric field approximately onto the common center of the outer shell 410 and the inner shell 420 of the focusing unit 400.
• the electrons of the electron beam 210 between the outer shell 210 and the inner shell 420 are accelerated such that a speed amount of the electrons of the electron beam 210 increases.
• the increase in the kinetic energy of the electrons of the electron beam 210 results from the potential difference between the outer shell 410 and the inner shell 420.
• the anode 500 of the X-ray generating device 100 is arranged.
• the anode 500 has a holder 520 that holds the target layer 510.
• the holder 520 of the anode 500 may comprise or consist of diamond, for example.
• the target layer 510 may comprise or consist of tungsten, for example.
• the anode 500 has a front 501 and a back 502. The front side 501 of the anode 500 is replaced by the
• Target layer 510 formed.
• the anode 500 is arranged such that the electron beam 210 entering the focusing unit 400 through the first opening 411 of the outer shell 410 and the first opening 421 of the inner shell 420 strikes the target layer 510 on the front side 501 of the anode 500.
• the electron beam 210 preferably strikes the target layer 510 approximately perpendicularly.
• the anode 500 is preferably arranged in the interior of the inner shell 420 of the focusing unit 400 in such a way that the target layer 510 is at the focal point of the focusing of the electron beam 210 caused by the focusing unit 400. Then points the focal spot in which the electrons of the Electron beam 210 on the target layer 510 of the anode 500 meet a minimum diameter.
• the electrons of the electron beam 210 which strike the target layer 510 of the anode 500 are decelerated in the target layer 510, with X-ray radiation being produced.
• This X-ray radiation is emitted in several or all spatial directions.
• the X-radiation comprises X-ray braking radiation and characteristic X-radiation.
• the proportion of the X-ray bremsstrahlung is higher in the forward direction defined by the direction of the electron beam 210 striking the target layer 510 than in the opposite reverse direction. Since the smallest possible amount of X-ray bremsstrahlung is desirable for various medical and technical purposes, X-ray window 110 for discharging X-ray radiation generated in target layer 510 of anode 500 in the rearward direction, that is in FIG of the
• the X-ray window 110 can cover, for example, a solid angle range of +/- 20 °.
• An advantage of the device 100 for generating X-ray radiation is that the cathode 200 is at least partially disposed outside the spatial region through which the X-ray emitted by the X-ray window 110 extends on its way from the target layer 510 of the anode 500.
• the X-ray radiation is not or only slightly shielded or attenuated by the cathode 200.
• the arrangement of the cathode 200 outside the space area covered by the X-ray window 110 is made possible by the deflection unit 300. This allows the cathode 200 to be arranged laterally offset from the rearward direction and still allow the electron beam 210 to be located in the rear area. in the opposite direction to the target layer 510 of the anode 500.
• the X-ray generating device 100 further comprises a collector 600.
• the collector 600 is disposed behind the focussing unit 400 and outside the outer shell 410 of the focussing unit 400 in the forward direction defined by the direction of the electron beam 200 striking the target layer 510.
• the collector 600 serves to collect electrons of the electron beam 210, which have completely penetrated the anode 500, in order to improve the energy efficiency of the device 100.
• the inner shell 420 has a second opening 422.
• the outer shell 410 also has a second opening 412.
• the second opening 412 of the outer shell 410 and the second opening 422 of the inner shell 420 are disposed on the sides of the outer shell 410 and the inner shell 420 opposite to the first openings 411, 421.
• the cathode 200 may form a ground or reference potential.
• the shield tube 330 of the deflection unit 300 and the outer shell 410 of the focusing unit 400 are set to a common positive electrical potential.
• the electrical voltage can be, for example, 10 kV with respect to the cathode 200.
• the second electrode 320 of the deflection unit 300 is preferably also at this potential. sets.
• the first electrode 310 of the deflection unit 300 is set to a positive potential that is smaller than the potential of the shield tube 330 of the deflection unit 300.
• the first electrode 310 can be placed opposite to the cathode 200 to a potential of 1 kV.
• the inner shell 420 of the focusing unit 400 is set at a positive potential higher than the potential of the outer shell 410 of the focusing unit 400.
• the inner shell 420 may be placed opposite the cathode 200 to a potential of 150 kV.
• the collector 600 may be set to a positive potential that lies between the potentials of the outer shell 410 and the inner shell 420 of the focusing unit 400.
• the collector 600 may be placed opposite the cathode 200 to a potential of 40 kV.
• FIG. 3 shows a highly schematic representation of a section through an apparatus 700 for generating X-radiation according to a second embodiment.
• FIG. 4 shows a schematic perspective view of the device 700 for generating the X-ray radiation. For reasons of clarity, some components of the device 700 are not shown in FIG.
• the device 700 for generating X-radiation has correspondences with the device 100 shown in FIGS. 1 and 2 for generating X-ray radiation. Components corresponding to one another are therefore provided with the same reference symbols and will not be described again in detail below.
• the device 700 for generating X-radiation comprises a focusing unit 800.
• the focusing unit 800 comprises an inner shell 820, which is formed as an electrically conductive spherical shell.
• the inner shell 820 includes a first opening 821 through which electrons of the electron beam 210 can penetrate into the space enclosed by the inner shell 820.
• the anode 500 is arranged in the interior of the inner shell 820 of the focusing unit 800. Electron of the electron beam 210, which has completely penetrated the anode 500, the inner
• the inner shell 820 of the focusing unit 800 corresponds to the inner shell 420 of the focusing unit 400 of the X-ray generating device 100 of FIGS. 1 and 2.
• the focusing unit 800 of the X-ray generating device 700 further includes an outer shell 810.
• the outer shell 810 is made of an electrically conductive material such as a metal.
• the outer shell 810 has the shape of a part of a spherical shell.
• the outer shell 810 is formed as a half spherical shell.
• the outer shell 810 may therefore also be referred to as Kugelkalottenschale.
• the outer shell 810 partially encloses the inner shell 820 of the focusing unit 800. In this case, the center of the spherical shell, of which the outer shell 810 forms part, coincides with the center of the inner shell 820.
• the outer shell 810 is arranged on the side of the inner shell 820 facing the second longitudinal end 332 of the screen tube 330 of the deflection unit 300.
• the outer shell 810 has an opening 811, through which electrons of the electron beam 210, which leave the shield tube 330 of the deflection unit 300 through the second longitudinal end 332, can penetrate into the focusing unit 800.
• an electric field to cause focusing of the electron beam 210 passing between the outer shell 810 and the inner shell 820.
• the electron beam 210 is again focused approximately at the center of the inner shell 820 of the focusing unit 800.
• the electric field in turn causes an increase in the speed amount of the electrons of the electron beam 210.
• the device 700 for generating X-radiation comprises a collector 900.
• Collector 900 is made of an electrically conductive material, such as a metal, and serves to collect electrons of the electron beam 210, which have completely penetrated the anode 500, thereby increasing an energy efficiency of the device 700 for generating X-radiation.
• the collector 900 has a cylindrical portion 910 which is closed on one side by a bottom portion.
• the collector 900 is thus cup-shaped.
• the cylindrical portion 910 of the collector 900 has the same diameter as the outer shell 810 of the focusing unit 800.
• the open end of the cylindrical portion 910 of the collector 900 adjoins the open end of the outer shell 810.
• the inner shell 820 of the focusing unit 800 is enclosed by the outer shell 810 and the collector 900.
• an insulation 920 is arranged, which electrically insulates the outer shell 810 against the collector 900. This makes it possible to place the outer shell 810 and the collector 900 at different electrical potentials.
• Electrons of the electron beam 210 that have passed through the anode 500 may leave the wide angle distribution anode 500.
• the change of direction of the electrons to the direction of the electron beam 510 directed to the front side 501 of the anode 500 is determined by collisions of the electrons of the electron beam 210 with the atoms of the
• Target layer 510 and the holder 520 of the anode 500 caused.
• the angular distribution of the electrons that passed through the anode 500 may be in a range of about +/- 60 °.
• the collector 900 offers the advantage over the collector 600 of FIGS. 1 and 2 that the collector 900 can absorb electrons from this entire large solid angle range.
• the device 700 has a particularly high energy efficiency.
• the second opening 822 of the inner shell 820 is designed to be large enough to allow electrons to pass from the entire possible scattering angle range.
• the components of the X-ray generating device 700 may be set at the same potential as the corresponding components of the X-ray generating device 100 during operation of the device 700.
• the outer shell 810 can be placed opposite the cathode 200 to a potential of 10 kV.
• the inner shell 820 of the focusing unit 800 can be placed opposite the cathode 200 to a potential of 150 kV.
• the collector 900 may be placed opposite the cathode 200 to a potential of 40 kV.

Landscapes

• Health & Medical Sciences (AREA)
• General Health & Medical Sciences (AREA)
• Toxicology (AREA)
• X-Ray Techniques (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=49209333

Family Applications (1)

Country Status (8)

Families Citing this family (1)

Family Cites Families (20)

• 2012
  • 2012-09-21 DE DE102012216977.6A patent/DE102012216977B4/de not_active Expired - Fee Related
• 2013
  • 2013-09-09 CN CN201380060275.8A patent/CN104823262A/zh active Pending
  • 2013-09-09 JP JP2015532367A patent/JP2015529386A/ja active Pending
  • 2013-09-09 WO PCT/EP2013/068624 patent/WO2014044567A1/de active Application Filing
  • 2013-09-09 US US14/428,371 patent/US20150228442A1/en not_active Abandoned
  • 2013-09-09 KR KR1020157006913A patent/KR20150075081A/ko not_active Application Discontinuation
  • 2013-09-09 EP EP13763017.4A patent/EP2883236A1/de not_active Withdrawn
  • 2013-09-09 RU RU2015114702A patent/RU2015114702A/ru not_active Application Discontinuation

Non-Patent Citations (1)

Also Published As

Similar Documents

Legal Events