DE10327038B4 - X-ray device - Google Patents

Abstract

X-ray device with an X-ray source (1), one in the radiation region of the X-ray source (1) arranged on a substrate (12) applied X-ray storage phosphor layer (4) and a detector for detecting an X-ray storage phosphor layer (4) radiated X-ray intensity, wherein the detector is a photosensitive sensor (8), which with respect to X-ray storage phosphor layer (4) is mounted so that when absorbing X-rays emitted scintillation light is detectable, wherein the with a Device (6) for regulating the X-ray storage phosphor layer (4) radiated X-ray intensity photosensitive sensor (8) with a distance to the X-ray storage phosphor layer (4) on an inner wall of an X-ray storage phosphor layer (4) receiving cassette-like housing (16) is mounted so that one from the X-ray storage phosphor layer (4) and the unit (12) formed unit from the housing (16) is removable.

Description

The The invention relates to an X-ray device.

The This invention relates generally to the field of radiography. In particular from Schulz R. F .; Fortschr Röntgenstr 2001; 173: 1137-1146 is known, come here as X-ray detectors so-called X-ray storage phosphor layers for use. Such X-ray storage phosphor layers contain special phosphors whose electrons absorb during absorption of X-rays get into an excited metastable state. The by the information stored in the metastable state can at a later date Time to be read out. For this purpose, the X-ray storage phosphor layer irradiated with light of a predetermined wavelength. The metastable State electrons sweep as a result of further excitation back to their ground state through the light. Scintillation light is emitted. The radiated scintillation light is a measure of the absorbed X-ray intensity.

Especially at the radiography for medical purposes are being attempted which irradiated on humans Dose of X-rays as low as possible to keep. This is a device for regulating the dose rate intended. The device has a detector for measuring the Dose rate on. The detector is via a device for regulation with a generator of an x-ray source connected. Once a given dose has been achieved, it will switched off by the means for regulating the generator.

The DE 100 15 264 A1 discloses an X-ray device comprising an X-ray source, an X-ray storage phosphor layer disposed in the X-ray source region and a detector for detecting X-ray intensity irradiated to the X-ray storage phosphor layer, the detector being a photosensitive sensor mounted with respect to the X-ray storage phosphor layer so as to emit X-ray radiation emitted therefrom Scintillation light is detectable, and wherein the photosensitive sensor is connected to a device for controlling the incident on the X-ray storage phosphor layer X-ray intensity.

at the known X-ray device the detector is part of a layered X-ray image converter.

task The invention is the specification of a possible universal X-ray device.

These The object is achieved by a device having the features of the claim 1 solved. Advantageous embodiments the X-ray device arise from the features of claims 2 to 5.

The Device makes use of the circumstance that at absorption of x-rays by means of an X-ray storage phosphor layer as well Spontaneous scintillation light is emitted. The intensity of the spontaneous emitted scintillation light is a measure of the intensity of the incident X-rays. It is suitable for determining the irradiated dose rate. To record the intensity of the spontaneously emitted scintillation light can be a simpler photosensitive Sensor can be used. Such a sensor is not with another Provided scintillator material. He is available at low cost. As a result of the omission the other scintillator material is adulterated in the X-ray storage phosphor layer stored X-ray intensity distribution not happening. About that In addition, the dose required to take an X-ray image can be be reduced. The method is a particularly accurate measurement the dose rate possible.

Of the The value obtained during the measurement is used to control the X-ray storage phosphor layer irradiated X-ray intensity used. To control the dose rate, using the with the light-sensitive sensor measured values, the dose is determined and when reaching a predetermined dose, an X-ray source will be switched off. It can be safe and reliable guaranteed be that a patient does not take an unnecessarily high dose of x-rays is charged.

The proposed X-ray device is easy and inexpensive produced. It allows one Production of radiographic X-ray images at a reduced Dose rate. A falsification the X-ray pictures through outside the X-ray storage phosphor layer Absorbent detector materials are avoided.

Of the light-sensitive sensor is at a distance from the X-ray storage phosphor layer at one the X-ray storage phosphor layer receiving cassette-like housing attached.

To In one embodiment, the photosensitive sensor has a photosensitive Shift up.

Furthermore, it is expedient that the photosensitive layer is formed from elements with an atomic number Z <50. This is particularly useful when the photosensitive sensor is disposed between the X-ray source and the X-ray storage phosphor layer. Thus, an unwanted absorption of X-rays by the light sensitive sensor avoided. The photosensitive layer may be made of an amorphous or polycrystalline semiconductor, preferably amorphous silicon, amorphous selenium or polycrystalline silicon. Conveniently, the photosensitive sensor is a conventional photodiode. Such a photodiode is available at low cost.

Of the Photosensitive sensor is further equipped with a device for regulation on the X-ray storage phosphor layer radiated X-ray intensity connected. With such a device, for example, the dose rate determined and depending a predetermined maximum dose, the X-ray source are turned off.

following an exemplary embodiments of the x-ray device will be explained in more detail with reference to the drawings. It demonstrate:

1 a schematic view of a radiography apparatus according to the prior art,

2A , B are schematic cross-sectional views of an X-ray detector.

In 1 schematically shows the structure of a radiographic apparatus according to the prior art. An x-ray source 1 radiates through a beam of light 2 a patient 3 , After passing through the patient 3 the beam falls 2 on an X-ray storage phosphor layer 4 , A detector is connected to a control device 6 , The control device 6 is connected to a generator for regulation 7 , in turn, with the X-ray source 1 connected to the supply of high voltage.

At the in 1 The radiography apparatus shown, the detector is a photosensitive sensor 8th , For example, a photodiode. As in 1 is shown is the photosensitive sensor 8th with a distance to the X-ray storage phosphor layer 4 arranged, and opposite to one of the X-ray source 1 facing away back 9 the X-ray storage phosphor layer 4 ,

In the in the 2A and 2 B schematically shown X-ray detector is a substrate 12 with the X-ray storage phosphor layer applied thereon 4 in a cassette 16 added. Opposite one of the (not shown here) X-ray source facing front 14 the X-ray storage phosphor layer 4 is on the inner wall of a lid of the cassette 16 the photosensitive sensor 8th appropriate. How out 2 B it can be seen, one from the substrate 12 with the X-ray storage phosphor layer picked up thereon 4 formed unit from the cassette 16 be removed. This unit can then be inserted into a read-out device (not shown here).

The function of the radiography apparatus is as follows:
As can be seen from the figures, the detection on the X-ray storage phosphor layer becomes 4 radiated X-ray intensity, a photosensitive sensor 8th used. With the photosensitive sensor 8th becomes due to the absorption of X-radiation from the X-ray storage phosphor layer 4 spontaneously emitted scintillation light detected. The intensity of the radiated scintillation light is a measure of the intensity of the incident X-ray radiation. From this a dose rate can be calculated. By means of the control unit 6 can reach the generator when a predetermined dose is reached 7 and thus the X-ray source 1 be switched off.

Claims (5)

X-ray device with an X-ray source ( 1 ), one in the radiation area of the X-ray source ( 1 ) arranged on a substrate ( 12 ) applied X-ray storage phosphor layer ( 4 ) and a detector for detecting an X-ray storage phosphor layer ( 4 ) irradiated X-ray intensity, wherein the detector is a photosensitive sensor ( 8th ), which with respect to the X-ray storage phosphor layer ( 4 ) is mounted so that scintillating light emitted thereby upon the absorption of X-ray radiation is detectable, whereby the scintillation light emitted by a device ( 6 ) for controlling the X-ray storage phosphor layer ( 4 ) irradiated x-ray intensity connected photosensitive sensor ( 8th ) with a distance to the X-ray storage phosphor layer ( 4 ) on an inner wall of an X-ray storage phosphor layer ( 4 ) receiving cassette-like housing ( 16 ) is mounted so that one of the X-ray storage phosphor layer ( 4 ) and the substrate ( 12 ) formed unit from the housing ( 16 ) is removable. X-ray device according to claim 1, wherein the photosensitive sensor ( 8th ) opposite one of the X-ray source ( 1 ) facing away from the back ( 9 ) or one of the X-ray sources ( 1 ) facing front ( 14 ) of the X-ray storage phosphor layer ( 4 ) is arranged. X-ray device according to claim 1 or 2, wherein the photosensitive sensor ( 8th ) has a photosensitive layer. X-ray device according to claim 3, wherein the photosensitive layer of elements with an atomic number Z <50 is formed. X-ray device according to one of Ansprü che 1 to 4, wherein the photosensitive layer is made of an amorphous or polycrystalline semiconductor, preferably amorphous silicon, amorphous selenium, polycrystalline silicon.