SU1071295A1 - X-ray diagnostic apparatus - Google Patents

Abstract

X-RAY DIAGNOSTIC DEVICE, containing a control panel, a high-voltage generator, a deep-diaphragm emitter and detectors installed in it, and means for measuring the signals of the detectors and obtaining control of the two signals for adjusting the parameters of the high-voltage generator connected to the detectors, in order to ensure the power and increase the accuracy of the registration of the radiation load on the patient, the detectors are located in the zone of secondary radiation from the diaphragm mirror .

Description

The invention relates to X-ray technology, and more specifically to X-ray diagnostic devices. A X-ray diagnostic apparatus containing a control panel, a high-voltage generator, a deep-diaphragm emitter, X-ray detectors located behind the object of study, and measuring signals for the detectors and obtaining 1 control signals for adjusting the parameters of the high-voltage generator connected to the detectors Cl are known. This device does not allow to determine the surface area of the body under irradiation, and therefore, to calculate the radiation load on the patient. In addition, the accuracy of stabilizing the x-ray power is low, since the signal used by the detectors is greatly attenuated by the tissues of the patient's body. Closest to the present invention is an X-ray diagnostic apparatus comprising a control panel, a high-voltage generator, a deep-diaphragm emitter and detectors installed therein, and means for measuring the signals of the detectors and obtaining control signals for adjusting the parameters of the high-voltage generator connected to the 2J detectors. In this case, a group of detectors finds from outside the working beam on the Wax diaphragm curtains, and one detector in the area of the working beam. However, the known apparatus does not allow stabilizing the X-ray power and not having accurate registration of the radiation load on the patient. This is because the x-ray power is measured by the detectors moving around the periphery of the primary radiation beam on the diaphragm shutters, the radiation beam has a significant spatial inhomogeneity, changing not only from the apparatus to the apparatus, but also in one apparatus when different filaments are connected : cathode (different focal spots). The product of the dose per area is measured by a detector located in the working radiation beam. Such an arrangement of the detector changes the qualitative composition of the radiation, and the magnitude of the spectral bending depends on the anodic voltage that is variable in the research process (fluoroscopy) and the remotely inserted replacement filter between the radiator and the diaphragm. The purpose of the invention is to stabilize the power of x-ray radiation and increase the accuracy of recording / guts load on the patient. The goal is achieved by the fact that in an X-ray diagnostic apparatus containing a control panel there is a high-voltage generator, an emitter with a deep diaphragm and detectors installed in it, and means for measuring the signals of the detectors and obtaining control signals for controlling the parameters of the high-voltage generator connected to the detectors, the detectors are located in the secondary radiation zone from the diaphragm mirror. The drawing shows the structural scheme of the proposed apparatus. The device contains an X-ray emitter 1 with a deep diaphragm 2, in which an optical centering device 3 is located, having a light source 4 and a mirror 5. The device also contains a control panel 6 and a high-voltage generator 7. The detec- tor 8 and 9 of ionizing radiation are located in the diaphragm 2. V The control unit 6 is equipped with measuring means for measuring signal detectors and receiving control signals, comprising a processing unit 10, a stabilization unit 11, an anode current adjustment unit 12, and a digital display unit 13. BbOiOKa detectors 8 and 9 are connected to the input of the processing unit 10, and the output of the processing unit 10 is connected with the input of the stabilization unit 11. and with the digital display unit 13, the output of the stabilization unit 11 is connected with the input of the anodic current control unit 12, the output of which zan with emitter 1. The device operates as follows. AnnapaiT is included in the network. Measured by the operator (using a measuring tool) and set in the control panel b (and thus entered into the processing unit 10) the distance from the radiator to the object of study, and the thickness of the object | neither A high voltage is applied to the anode of the X-ray tube. With the passage of the radiation beam through the mirror 5 of the optical centering device. 3, scattered radiation is generated, the intensity of which is measured with the help of two detectors 8 and 9. Detector 8 is collimated so that it measures scattered radiation only from the central part of mirror 5, and detector 9 measures scattered radiation from the entire mirror 5 Signals

From detectors 8 and 9, they are fed to the input of unit 10, where they are processed. The ratio of the readings of the signals of the detectors 8 and 9 allows, at a known distance from the radiator for the object of study, to determine the area of the irradiation field, which is performed by the processing unit 10. The processing unit 10 also performs the operation of multiplying the area of the irradiation field by the thickness of the object of study. , by the magnitude of the duration of the study and by the magnitude of the exposure dose rate. The result of the bleed is indicated by the indicia 13 block and is the value of the integral absorbed dose received by the patient for the study. The duration of the study is fixed | It is automatically set up using an electronic second, “Opera is not shown) on the remote control b. the magnitude of the exposure dose is determined by a 9 ps detector of the intensity of scattered radiation from the entire mirror area, the output control signal of the processing unit 10, depending on the magnitude of the radiation output / input to the input of the stabilization unit 11, the signal of which is fed to the input of the adjustment block anode current 12. With the help of the stabilization unit 11 and the anode current adjustment unit 12,. selected anode voltage, a constant power is maintained at the output of the emitter 1, for example, by varying the voltage on the grid of the X-ray three-electrode tube.

The invention makes it possible to stabilize the power of X-ray radiation, as well as to increase the accuracy of registration of the radiation load on the patient.

Stabilizing the radiation of the Btixol X-ray radiation, the research process allows, in turn, to reduce the radiation load of the person and patients by 15–20% by eliminating the unresolved size of the eye and reducing the number of defective images.

Claims (1)

X-ray diagnostic apparatus, comprising a control panel, a high voltage generator, an emitter with a deep diaphragm and detectors installed therein, and means for measuring the signals of the detectors and receiving control signals for adjusting the parameters of the high voltage generator, connected to the detectors, characterized in that, in order to stabilize the power of the x-ray radiation and increasing the accuracy of recording the radiation load on the patient, the detectors are located in the secondary radiation zone from the diaphragm mirror. 10 ^ 1295 The purpose of the invention is the stabilization of the power of x-ray radiation and improving the accuracy of registration of the radiation load on the patient. c The goal is achieved by the fact that in the X-ray diagnostic apparatus containing a control panel, a high-voltage generator, an emitter with a deep diaphragm and detectors ¹⁰ installed therein and means # for measuring the signals of the detectors and receiving control signals for adjusting the parameters of the high-voltage generator, the detectors connected to the detectors 15 are located in the secondary radiation zone from the diaphragm mirror. The drawing shows a structural diagram of the proposed apparatus. The apparatus contains an x-ray 20 emitter 1 with a deep diaphragm 2, in which an optical centering device 3 is located, having a light source 4 and a mirror 5. The apparatus contains 25 g® control panel 6 and a high-voltage generator 7. The ionizing radiation detectors 8 and 9 are located in the diaphragm 2. In the control panel 6 there are means for measuring the signals of the detectors and receiving control signals, comprising a processing unit 10, a stabilization unit 11, an anode current adjustment unit 12 and a digital indication unit 13. Detector outputs Orors 8 and 9 are connected to the input of the processing unit 10, and the output of the processing unit 10 is connected to the input of the stabilization unit 11 and to the digital indication unit 13, the output of the stabilization unit 11 is connected to the input of the anode current adjustment unit 12, the output of which is connected to the emitter 1. The device operates as follows. The device is connected to the network. Measured by the operator (using a measuring tool) and installed in the control panel 6 (and thus entered into the processing unit 10), the distance from the emitter to the object of study and the thickness of the object of investigation. A high voltage is applied to the anode of the x-ray tube. When radiation beam 55 passes through the optical centering device mirror 5. Scattered radiation 3 is generated, the intensity of which is measured using two detectors 8 and 9. Detector 8 is collimated in such a way that it measures scattered radiation only from the central part of mirror 5, detector 9 measures the scattered radiation from the entire mirror 5. Signals