Abstract: There is provided a fluorescent X-ray analysis apparatus in which a detection lower limit is improved, and it is possible to quantify a trace aimed element having been contained not only in a sample whose main component is a heavy element but also in a sample whose main component is a light element. The fluorescent X-ray analysis apparatus possesses a sample base supporting the sample, an X-ray source irradiating a primary X-ray with a predetermined irradiation position being made a center, and a detector disposed toward the irradiation position and detecting a fluorescent X-ray generated from the sample.

Abstract: A vacuumed enclosure has a window formed of an X-ray transmissive material. The vacuumed enclosure encloses an electron beam source for generating an electron beam and a target which, irradiated by the electron beam, generates a primary X-ray. The target is smaller in the outer dimension than the window and located on the center of the window such that it irradiates, through the window, the primary X-ray onto a sample located outside. The vacuumed enclosure further encloses an X-ray detector located such that it can detect a fluorescent X-ray and a scattered X-ray coming from the sample through the window. The X-ray detector generates a signal representative of energy information of the fluorescent X-ray and the scattered X-ray. The vacuumed enclosure further encloses a thermally and electrically conductive metal extending through the target across the widow.

Abstract: Provided are an X-ray analysis apparatus and an X-ray analysis method, in which a measurer can judge an area incapable of being analyzed in a sample with a concave-convex portion.

Abstract: In an X-ray analysis apparatus and an X-ray analysis method, a quantitative analysis is stably performed by stably behaving an X-ray source. There are possessed an X-ray tubular bulb irradiating a primary X-ray to a sample, a primary X-ray adjustment mechanism capable of adjusting an intensity of the primary X-ray, an X-ray detector detecting a characteristic X-ray radiated from the sample, thereby outputting a signal including energy informations of the characteristic X-ray and a scattered X-ray, an analyzer analyzing the above signal, and an incident X-ray adjustment mechanism disposed between the sample and the X-ray detector, and capable of adjusting a total intensity of the characteristic X-ray and the scattered x-ray, which are entered to the X-ray detector.

Abstract: Provided are an X-ray analysis apparatus and an X-ray analysis method, in which a measurer can judge an area incapable of being analyzed in a sample with a concave-convex portion.

Abstract: To provide an energy dispersion type radiation detecting system and a method of measuring a content of an object element capable of carrying out a measurement by determining an intensity of an incidence radiation to constitute an optimum minimum limit of detection by restraining an influence of a pile up, the energy dispersion type radiation detecting system includes an incidence system of irradiating the incidence radiation to a sample by a predetermined intensity, a detection system of detecting a radiation emitted from the sample by irradiating the incidence radiation for specifying a content of an object element of the sample based on a spectrum of the detected radiation, and the energy dispersion type radiation detecting system includes a control portion capable of irradiating the incidence radiation by an optimum intensity by determining the optimum intensity of the incidence radiation minimizing a minimum limit of detection of the object element based on the spectrum of the detected radiation.

Abstract: Provided are an X-ray tube and an X-ray analysis apparatus, which can be further reduced in size as well as in weight and more efficiently detect a fluorescent X-ray and the like to increase sensitivity.

Abstract: There are disclosed an X-ray tube and an X-ray analysis apparatus which are made smaller and lighter in weight than heretofore and which detect fluorescent X-rays more efficiently with enhanced sensitivity. The X-ray tube has a vacuum enclosure, an electron beam source mounted in the enclosure and emitting an electron beam, a target irradiated with the beam and producing primary X-rays, an X-ray detector device, and a metallic thermal and electrical conductor portion mounted over a part of the window and extending from the target to the enclosure. The enclosure has a vacuum inside and a window made of an X-ray transmissive film through which X-rays are transmitted. The target is smaller in outside diameter than the window and mounted over the central portion of the window such that the primary X-rays can be ejected at an external sample through the window.

Abstract: A sample sealing vessel 8 includes a plurality of wall faces comprising a material for transmitting X-ray, an X-ray source 1 is arranged at a wall face 11 to irradiate primary X-ray, a face 12 different from the face irradiated with the primary X-ray is arranged to be opposed to an X-ray detector 10, and the primary X-ray from the X-ray source 1 is arranged to be able to irradiate the wall face 12 of the sample sealing vessel to which the X-ray detector 10 is opposed.

Abstract: There is provided a fluorescent X-ray analysis apparatus in which a detection lower limit has been improved by reducing an X-ray generating subsidiarily and detected. The fluorescent X-ray analysis apparatus is one which possesses an X-ray source irradiating a primary X-ray, and a detector in which a collimator having a through-hole in its center part has been placed in a front face, and in which, by the detector, there is detected a primary fluorescent X-ray which generates from a sample by irradiating the primary X-ray to a sample, and passes through the through-hole of the collimator.

Abstract: To provide a fluorescent X-ray analysis apparatus, whereby a peak-back ratio is improved by effectively exciting a focused element and a detection limit of the focused element is improved by decreasing a scattered X-ray to be a background. A sample housing has one or more wall surfaces made of a material through which an X-ray transmits and an X-ray source is arranged so that a primary X-ray is irradiated on the wall surface. In addition, the sample housing is arranged so that a wall surface different from a wall surface on which the primary X-ray is irradiated is opposed to an X-ray detector incident window. Further, the primary X-ray from the X-ray source is arranged so as to be able to irradiate the wall surface of the sample housing to which the X-ray detector incident window is opposed. The sample housing has a shape extending in response to extension of a viewing filed that a detection element in the X-ray detector is seen from the X-ray detector incident window.

Abstract: In an X-ray analysis apparatus and an X-ray analysis method, a quantitative analysis is stably performed by stably behaving an X-ray source. There are possessed an X-ray tubular bulb irradiating a primary X-ray to a sample, a primary X-ray adjustment mechanism capable of adjusting an intensity of the primary X-ray, an X-ray detector detecting a characteristic X-ray radiated from the sample, thereby outputting a signal including energy informations of the characteristic X-ray and a scattered X-ray, an analyzer analyzing the above signal, and an incident X-ray adjustment mechanism disposed between the sample and the X-ray detector, and capable of adjusting a total intensity of the characteristic X-ray and the scattered x-ray, which are entered to the X-ray detector.

Abstract: To be able to achieve further small-sized formation and light-weighted formation and to promote a sensitivity by further efficiently detecting a fluorescent X-ray or the like in an X-ray tube and an X-ray analyzing apparatus, there are provided a vacuum cabinet 2 inside of which is brought into a vacuum state and which includes a window portion 1 formed by an X-ray transmitting film through which an X-ray can be transmitted, an electron beam source 3 installed at inside of the vacuum cabinet 2 for emitting an electron beam e, a target T generating a primary X-ray X1 by being irradiated with the electron beam e and installed at inside of the vacuum cabinet 2 to be able to emit the primary X-ray X1 to an outside sample S by way of the window portion 1, and an X-ray detecting element 4 arranged at inside of the vacuum cabinet 2 to be able to detect a fluorescent X-ray and a scattered X-ray X2 emitted from the sample S and incident from the window portion 1 for outputting a signal including energy information of

Abstract: There is provided a fluorescent X-ray analysis apparatus in which a detection lower limit has been improved by reducing an X-ray generating subsidiarily and detected. The fluorescent X-ray analysis apparatus is one which possesses an X-ray source irradiating a primary X-ray, and a detector in which a collimator having a through-hole in its center part has been placed in a front face, and in which, by the detector, there is detected a primary fluorescent X-ray which generates from a sample by irradiating the primary X-ray to a sample, and passes through the through-hole of the collimator.

Abstract: To provide an energy dispersion type radiation detecting system and a method of measuring a content of an object element capable of carrying out a measurement by determining an intensity of an incidence radiation to constitute an optimum minimum limit of detection by restraining an influence of a pile up, the energy dispersion type radiation detecting system includes an incidence system of irradiating the incidence radiation to a sample by a predetermined intensity, a detection system of detecting a radiation emitted from the sample by irradiating the incidence radiation for specifying a content of an object element of the sample based on a spectrum of the detected radiation, and the energy dispersion type radiation detecting system includes a control portion capable of irradiating the incidence radiation by an optimum intensity by determining the optimum intensity of the incidence radiation minimizing a minimum limit of detection of the object element based on the spectrum of the detected radiation.

Abstract: To provide a fluorescent X-ray analysis apparatus, whereby a peak-back ratio is improved by effectively exciting a focused element and a detection limit of the focused element is improved by decreasing a scattered X-ray to be a background. A sample housing has one or more wall surfaces made of a material through which an X-ray transmits and an X-ray source is arranged so that a primary X-ray is irradiated on the wall surface. In addition, the sample housing is arranged so that a wall surface different from a wall surface on which the primary X-ray is irradiated is opposed to an X-ray detector incident window. Further, the primary X-ray from the X-ray source is arranged so as to be able to irradiate the wall surface of the sample housing to which the X-ray detector incident window is opposed. The sample housing has a shape extending in response to extension of a viewing filed that a detection element in the X-ray detector is seen from the X-ray detector incident window.

Abstract: A sample sealing vessel 8 includes a plurality of wall faces comprising a material for transmitting X-ray, an X-ray source 1 is arranged at a wall face 11 to irradiate primary X-ray, a face 12 different from the face irradiated with the primary X-ray is arranged to be opposed to an X-ray detector 10, and the primary X-ray from the X-ray source 1 is arranged to be able to irradiate the wall face 12 of the sample sealing vessel to which the X-ray detector 10 is opposed.

Abstract: The change in the sample size and a change in background intensity due to the coexisting element are measured in real time to thereby automatically change a measurement time, the detection lower limit is kept constant, so that a fluorescent X-ray apparatus is provided that is capable of measuring every time in the same detection lower limit even in a case where there have existed a change in size of a sample, a change in sensitivity due to a difference in main ingredient, and a change of a magnitude in background due to an influence of a coexisting element.

Abstract: There is provided a fluorescent X-ray analysis apparatus in which a detection lower limit is improved, and it is possible to quantify a trace aimed element having been contained not only in a sample whose main component is a heavy element but also in a sample whose main component is a light element. The fluorescent X-ray analysis apparatus possesses a sample base supporting the sample, an X-ray source irradiating a primary X-ray with a predetermined irradiation position being made a center, and a detector disposed toward the irradiation position and detecting a fluorescent X-ray generated from the sample.

Abstract: The change in the sample size and a change in background intensity due to the coexisting element are measured in real time to thereby automatically change a measurement time, the detection lower limit is kept constant, so that a fluorescent X-ray apparatus is provided that is capable of measuring every time in the same detection lower limit even in a case where there have existed a change in size of a sample, a change in sensitivity due to a difference in main ingredient, and a change of a magnitude in background due to an influence of a coexisting element.