Brazing apparatus and method for anode target plate

What is claimed is: 1. A brazing apparatus for brazing an anode target plate of an X-ray generator, comprising: a vacuum part configured to provide, during brazing, a vacuum environment for (i) a target plate main body that is formed of an alloy, (ii) a brazing material, and (iii) a substrate to be brazed to a surface of the target plate main body; an induction brazing part configured to apply an induction current to the target plate main body, the brazing material, and the substrate within the vacuum part to heat the brazing material to a temperature that is higher than a melting point of the brazing material to cause the substrate to be brazed to the surface of the target plate main body via a melting of the brazing material and a resulting reaction; a directional energy welding part configured to perform heating by applying a directional energy beam to a location on the target plate main body having a temperature that is less than a predetermined temperature threshold; a sensor configured to measure a temperature of the target plate main body during brazing; and a controller configured to determine, based upon the measured temperature, the location on the target plate main body having the temperature less than the predetermined temperature threshold, and to control the directional energy welding part to cause the directional energy welding part to apply the generated directional energy beam to the location. 2. The brazing apparatus as claimed in claim 1 , wherein the induction brazing part comprises an induction heater configured to generate an induction current within a predetermined frequency range to heat the target plate main body, the brazing material, and the substrate within the vacuum part. 3. The brazing apparatus as claimed in claim 1 , wherein the directional energy welding part comprises an electron beam welder. 4. The brazing apparatus as claimed in claim 1 , wherein the directional energy welding part comprises a laser welder. 5. The brazing apparatus as claimed in claim 1 , wherein the target plate main body is from among a plurality of target plate main bodies, and further comprising: a stacking part disposed in the vacuum part and configured to stack the plurality of target plate main bodies, the target plate main body being located at an uppermost level of the stacking part including the plurality of target plate main bodies. 6. The brazing apparatus as claimed in claim 1 , wherein the vacuum part comprises: a first vacuum chamber configured to provide the vacuum environment for the brazing; a second vacuum chamber configured to provide a vacuum cooling environment for the target plate main body that has undergone the brazing; and a valve configured to be selectively opened or closed, the valve being arranged between the first vacuum chamber and the second vacuum chamber, wherein, when the valve is opened, the first vacuum chamber and the second vacuum chamber are coupled to one another such that the target plate main body is transferred from the first vacuum chamber to the second vacuum chamber. 7. The brazing apparatus as claimed in claim 6 , wherein the first vacuum chamber comprises: a sealed quartz bell jar configured to enable observation of the brazing material on the target plate main body during the brazing. 8. The brazing apparatus as claimed in claim 6 , further comprising: a first cooling apparatus configured to cool an exterior of the first vacuum chamber to prevent an outside surface temperature of the first vacuum chamber from exceeding a further predetermined threshold temperature; and a second cooling apparatus configured to cool the second vacuum chamber to increase a rate of cooling of the target plate main body that has undergone the brazing. 9. The brazing apparatus as claimed in claim 1 , wherein the target plate main body comprises a molybdenum alloy, and wherein the substrate is comprised of graphite. 10. The brazing apparatus as claimed in claim 1 , wherein the degree of vacuum of the vacuum environment is at most 5×10 −5 mbar. 11. The brazing apparatus as claimed in claim 1 , wherein the brazing material comprises an alloy brazing material. 12. A brazing method, comprising: placing, in a vacuum environment, (i) a target plate main body formed of an alloy, (ii) a brazing material, and (iii) a substrate to be brazed to a surface of the target plate main body; arranging the brazing material and the substrate at a predetermined position on the target plate main body; applying an induction current to the target plate main body, the brazing material, and the substrate to heat the brazing material to a temperature that is higher than a melting point of the brazing material to cause the substrate to be brazed to the surface of the target plate main body via melting of the brazing material and a resulting reaction; and applying a directional energy beam to a location on the target plate main body having a temperature, which is less than a predetermined temperature threshold, to perform heating, by: measuring a temperature of the target plate main body during brazing; and adjusting the direction of the directional energy beam to apply the directional energy beam to the position on the target plate main body that is less than the predetermined temperature threshold. 13. The brazing method as claimed in claim 12 , wherein the target plate main body comprises a molybdenum alloy, and wherein the substrate is comprised of graphite. 14. The brazing method as claimed in claim 12 , wherein the degree of vacuum of the vacuum environment for brazing is at most 5×10 −5 mbar. 15. The brazing method as claimed in claim 12 , wherein the brazing material comprises an alloy brazing material. 16. The brazing method as claimed in claim 12 , wherein the act of applying the induction current to the target plate main body comprises: applying, via an induction heater, the induction current within a predetermined frequency range to heat the target plate main body, the brazing material, and the substrate within the vacuum environment. 17. The brazing method as claimed in claim 12 , wherein the act of applying the directional energy beam comprises: applying the directional energy beam using an electron beam welder or a laser welder. 18. The brazing method as claimed in claim 12 , further comprising: stacking a plurality of target plate main bodies via a stacking part, the target plate main body being located at an uppermost level of the stacking part including the plurality of target plate main bodies. 19. The brazing method as claimed in claim 12 , further comprising: providing the vacuum environment by providing a first vacuum chamber comprising a sealed quartz bell jar configured to enable observation of the brazing material on the target plate main body during the brazing; providing a second vacuum chamber configured to provide a vacuum cooling environment for the target plate main body that has undergone the brazing; and providing a valve configured to be selectively opened or closed, the valve being arranged between the first vacuum chamber and the second vacuum chamber, wherein, when the valve is opened, the first vacuum chamber and the second vacuum chamber are coupled to one another such that the target plate main body is transferred from the first vacuum chamber to the second vacuum chamber. 20. The brazing method as claimed in claim 19 , further comprising: providing a first cooling apparatus configured to cool an exterior of the first vacuum chamber