EA010609B1 - Method of x-ray monitor of a tested object and apparatus therefor - Google Patents

Abstract

The invention relates to applied physics, in particular, to technology of radiation detection.The technical aim is to develop an apparatus and an effective method for providing high-accuracy full X-ray monitoring of a body being tested.The apparatus is embodied as a bearing stand with guides, a bar and, at least two C-shaped holders with radiators and linear detectors fastened at ends thereof. The bar and holders are connected therebetween and to the bearing stand adapted to longitudinal movement and turn relative each other and relative to the bearing stand in the plane parallel to the bearing stand plane and in the plane perpendicular to the bearing stand.The method comprises scanning the body to be tested by simultaneously preformed flat X-ray beams, simultaneously formed in N>1 any fixed planes by movement of the beams and detectors of X-ray radiation relative to the tested body, at each moment of the monitor time each X-ray beam, the tested body and each detector of the X-ray radiation being in one plane.

Description

The invention relates to the field of technical physics, in particular to the technique of detecting radiation, and can be used in photometry, dosimetry, as well as in measuring the spatial and energy characteristics of fields of optical and ionizing radiation in order, for example, x-ray monitoring of bodies, in particular the human body, to detect in them or on them some undesirable objects or substances both for medical control and for non-medical purposes, for example, to prevent theft or acts of terrorism and about Ensuring safety in buildings and structures, such as airports and other high-risk areas.

The prior art methods and installation of x-ray control of the studied objects.

The known method and installation of x-ray control (product VobuZeagsy, see the prospectus of the company Atepsay 8s1eisee Appb Eddteeppd, 1ps.). A person is irradiated with a low power radiation beam, the radiation reflected (scattered) by the surface of his body is caught, it is converted into an image and judged by the presence of, for example, prohibited items. The installation that implements this method has a housing in which a low-power x-ray source is located, a device for generating an x-ray beam and a reflected radiation detector. Close to the body is a platform that is open on three sides. A person stands on the platform close to the body, face or back to him. The source, located at a height of approximately half the height of a person, emits a conical diverging beam of low-power X-ray radiation, which, passing through clothing, is reflected from the surface of the passenger's body. The reflected radiation is captured by the detector and creates on it a picture of what is on the surface of the body, in the clothes and on the clothes of that half of the body that is turned to the body. For a complete inspection, it is necessary to expose a person to radiation in two positions: facing the body and with its back to it. At the same time, internal cavities of the body are not subject to inspection, i.e. it is impossible to detect objects swallowed and located in the stomach or placed in other natural cavities of the body.

A scanning X-ray system (EP No. 271723 A, 06/22/1988) is also known, which contains an X-ray sensor that has passed a body made as a vertical line of detectors and a collimator in the form of a pair of vertical parallel plates for forming X-ray radiation.

Known scintillation counter (AS USSR № 306770 A, 10/31/1983), containing in one case the first device for converting X-rays transmitted through the body into visible light (scintillator) and the second device adjacent to it for converting visible radiation light into an electrical signal (photomultiplier tube).

The closest to the proposed method is a method of x-ray control of the object of study (in particular, the body), including scanning the object of research pre-formed flat x-ray beam by moving the beam and the x-ray detector relative to the object of study (see RF Patent No. 2126550, 20.02.1999, bul No. 5).

In the installation that implements this known method, a radiation source, a collimator of special design and a sensor in the form of a matrix of radiation detectors are mounted on a holder that moves relative to a fixed object of study. Each of the radiation detectors contains devices for forming an optical image from X-rays transmitted through the object under study, fiber-optic communication elements, optical image amplifiers and devices for converting an optical image into an electronic image. Visualization tools include the specified sensor and a device for processing the specified electronic image.

Since the transmission of information in the form of an optical image is accompanied by significant losses, its intermediate amplification is required. To create an image suitable for converting an optical image, a stack of radiation beams having a certain height is required. The massive holder with the devices fixed on it cannot move fast enough.

Compliance with the minimum dose received by the body, provided that the source moves at a low speed in combination with the radiation power transmitted through the body, which is sufficient for obtaining an optical image, is a complex task.

As a result of the comparative analysis of the prior art, no analogues of the proposed design of the X-ray inspection facility of the object of study were identified.

An object of the invention is to create an installation and an effective method for the implementation of full X-ray control of the investigated body with greater accuracy.

The technical objective is achieved by the installation of X-ray inspection of the object of study made in the form of a carrier column with guides, on which a rod with guides and at least at least two C-shaped holders are installed with a slider with the possibility of longitudinal reciprocating movement with respect to the carrier column mounted on the ends opposite each other and located in the same plane by the emitter and the linear detector; the rod is hinged on the slider so that it can be rotated up to 360 ° in a plane parallel to the plane of the carrier column; each holder is mounted on the guide rod by means of a slider with the possibility of longitudinal reciprocating movement relative to

- 1 010609 rod and pivotally mounted on the slider with the ability to rotate up to 360 ° in a plane parallel to the plane of the rod, each holder is mounted on the slider through the connection node ensuring rotation of the holder to 180 ° in the plane perpendicular to the plane of the rod.

The unit is equipped with a radiolucent table for taking pictures of bedridden patients.

In the method of X-ray control of the object of study, including scanning the object of study by a preformed flat X-ray beam by moving the beam and the X-ray detector relative to the object of study, scanning the object of research is carried out simultaneously N> 1 flat X-ray beams simultaneously formed in different predetermined planes at each time point control X-ray beam, the investigated area of the object and the X-ray detector are located lag in the same plane.

Flat x-ray beams form simultaneously in at least two horizontal planes.

Flat x-ray beams form simultaneously in at least two inclined planes.

Flat x-ray beams form simultaneously in vertical and inclined planes.

Scanning of an object of research is carried out with at least two flat X-ray beams located at a given angle to the object under study and formed in at least two either horizontal, or vertical, or inclined planes.

The proposed installation and method are illustrated by drawings, where:

in fig. 1 shows the general scheme of the installation;

in fig. 2, 3 - examples of the working positions of the installation;

in fig. 4 shows an example of a method with two horizontally formed flat X-ray beams;

in fig. 5 shows an example of a method with a vertically and obliquely shaped X-ray beam;

in fig. 6 - examples of the method when obliquely formed x-ray beam;

in fig. 7 is an example of a working position with three holders.

The installation includes (see Fig. 1) carrier column 1, rod 2 and at least two holders 3 and 4 with radiators 5 and 6 and linear detectors 7 and 8, respectively. On the carrier column 1 there are longitudinal guides 9 in which a slider 10 is mounted for fastening the rod 2 on it. The rod 2 is fixed on the slider hingedly with the possibility of ensuring that the rod 2 rotates 2 to 360 ° in a plane parallel to the plane of the carrier column 1. Each of the holders 3 and 4 is made C-shaped.

The emitter 5 and the linear detector 7 are installed and fixed at the ends of the holder 3 opposite each other so that the fan-shaped X-ray beam always falls directly on the working surface of the linear detector 7, and the radiator 6 and the linear detector 8 are installed and fixed at the ends of the holder 4 opposite each other so that the formed fan-shaped X-ray beam always falls directly on the working surface of the linear detector 8. On the rod 2, longitudinal guides 11 are made, in which vlen slider. Holders 3 and 4 through the joints 12 and 13, respectively, are hinged on the slide of the rod 2 with the ability to rotate the holders 3 and 4 to 360 ° in a plane parallel to the plane of the rod 2 and the carrier column 1. The joints 12 and 13 provide the rotation of the holders 3 and 4 to 180 ° in the plane perpendicular to the plane of the rod 2 and the carrier column 1. The unit is equipped with an X-ray transparent table for taking pictures of bedridden patients.

FIG. 2 shows a general view of the installation before starting work; FIG. 3 - various installation operating positions (from left to right): during the scan, holders 3 and 4 move along rod 2; for taking pictures of oblique projections (forming an X-ray beam in an inclined plane) holders 3 and 4 can be rotated up to 360 °; Holders 3 and 4 rotate up to 180 °, ensuring the implementation of various projections.

The proposed installation implements the proposed method.

The essence of the method is as follows.

As mentioned above, the technical result of the claimed invention is to create an installation and an effective method for performing full x-ray control of the body with greater accuracy.

The problem is solved due to the fact that the radiation beam is simultaneously formed in the form of at least two (if necessary and more) flat X-ray beams of a fan-shaped form and at least at least two (or more) of any given planes.

Depending on the required viewing area of the object of study, X-ray beams are simultaneously formed either in two or more horizontal planes, or simultaneously in two or more inclined planes, or simultaneously in vertical and inclined planes.

FIG. 4 shows taking pictures of a standing patient. The rod 2 of the installation by means of rotation is installed in a vertical position, the holders 3 and 4 are installed horizontally perpendicular

- 2 010609 radar to the plane of the rod 2. The patient (or object of study) is placed inside the C-shaped holders 3 and 4 between the emitters 5 and 6 and the linear detectors 7 and 8 so that the viewing area is in the same plane with the X-ray beams and linear detectors 7 and 8. The holders 3 and 4 move along the rod 2 along the guides 11. In FIG. 4 shows an example of scanning the chest region simultaneously with two flat X-ray beams, simultaneously formed in two horizontal planes. In this study of a standing patient, it is possible to obtain two projections of the area under study at once in one study, in this example, in two horizontal planes. If one of the holders is turned at any angle relative to the rod 2, and the other holder is left in the same position, then it is possible to simultaneously receive two projections in different planes, in this example, in the horizontal and inclined planes

In the process of examining a standing patient, it is possible to simultaneously take two or more pictures of various projections of any area studied. To do this, either one of the holders is necessary, or both holders can be immediately rotated to any given angle in the range from 0 to 360 ° relative to rod 2 in a plane parallel to the plane of rod 2, or to a given angle in the range from 0 to 180 ° relative to rod 2 the plane perpendicular to the plane of the rod 2, or depending on the task of the study, the rotation of the holders is carried out in both planes at the same time at any given angle. FIG. 3 (photo in the middle and on the right) shows an example of the reversal of the holder relative to the rod 2.

The proposed method and installation allow for research and lying patient. The patient is placed on the top panel of the radiolucent table (in Fig. 2 on the right, an example of the location of the table relative to the holder 3 is shown). The table with the patient is placed inside the C-shaped holders 3 and 4 so that the top panel of the table is between the emitters 5 and 6 and the linear detectors 7 and 8, and the viewing area is in the same plane as the x-ray beams and the linear detectors. When the patient is lying down, the emitters 5 and 6 are in the upper position on the holders 3 and 4, and the linear detectors 7 and 8 are in the lower one.

FIG. 5 shows an example of simultaneously performing vertical and oblique projections (X-ray beams are formed simultaneously in vertical and inclined planes) lying at an angle to the horizon of the patient. Head above the legs. When turning and moving the holders 3 and 4 relative to the rod 2 and relative to each other, as shown in FIG. 3, it is possible to perform almost any projection in any given plane.

FIG. 6 shows an example of another arrangement of the patient's body on the table. Head below the feet. At the same time, two flat X-ray beams, which are located at different angles to the patient, are formed in two vertical planes. At the same time, a doctor has two projections immediately after one examination. With various possible movements and turns of the holder 3 and 4 and such an arrangement of the patient’s body on the table, any projections are ensured.

FIG. 7 shows an example of obtaining, for example, three projections. The method provides simultaneous execution of projections and in a larger number of planes, depending on the task of the study of the patient. For this installation is additionally supplied with the required number of holders.

Thus, using the proposed installation of x-ray control of the object of study and the method implemented on it, you can scan any part of the body from any side and at any angles relative to the patient. Such a study of the patient makes it possible to conduct more accurate examinations of various parts of the body, allows you to identify various diseases at earlier stages, establish a more accurate diagnosis, and you can create a stereo effect and three-dimensional image of organs. In addition, when conducting research, the energy of the beams may be different, which will allow us to have additional information that will help in calculating the density of the parts of the object under study.

The proposed facility and method can also be used for scanning objects and for non-medical purposes, for example, to prevent theft or acts of terrorism and to ensure security in buildings and structures, for example, at airports and other high-risk areas.

Claims (8)

1. Installation of x-ray inspection of the object of study, made in the form of a supporting column with guides on which, with a slider with the possibility of longitudinal reciprocating movement relative to the supporting column, a rod with guides and at least two C-shaped holders with opposite ends fixed to each other is mounted each other and located in the same plane by the emitter and the linear detector, while the rod is pivotally mounted on a slider with the possibility of rotation up to 360 ° in the plane, p column-parallel carrier plane, each holder is mounted on the guide rods by a slider for longitudinal reciprocating movement relative to the rod and hinged to the slider pivotably to 360 ° in a plane parallel to the rod, - 3 010609 and each holder is mounted on a slider through the connection node, ensuring rotation of the holder to 180 ° in a plane perpendicular to the plane of the rod. 2. The installation of x-ray control of the research object according to claim 1 is equipped with an x-ray transparent table for taking pictures of bedridden patients. 3. The method of x-ray control of the object of study, including scanning the object of study with a preformed flat x-ray beam by moving the beam and the X-ray detector relative to the object of study, characterized in that the scanning of the object of study is carried out simultaneously N> 1 flat x-ray beams simultaneously formed in different predetermined planes at the same time, at each time point of control, the x-ray beam, the studied area of the object and the detector X-ray radiation is placed in one plane. 4. The method of x-ray control according to claim 3, characterized in that the flat x-ray beams are formed simultaneously in at least two horizontal planes. 5. The method of x-ray control according to claim 3, characterized in that the flat x-ray beams are formed simultaneously in at least two inclined planes. 6. The method of x-ray control according to claim 3, characterized in that the flat x-ray beams are formed simultaneously in the vertical and inclined planes. 7. The method of x-ray control according to claim 3, characterized in that the flat x-ray beams are formed simultaneously in horizontal and inclined planes. 8. The method of x-ray control according to claim 3, characterized in that the scanning of the object of study is carried out by at least two flat x-ray beams located at a given angle to the object being studied and formed in at least two horizontal, vertical or inclined planes.