UA135146U - DEVICE FOR X-RAY TELEVISION CONTROL - Google Patents

Abstract

Device for X-ray television control, which includes an opaque housing, one of the walls of which is X-ray transparent, in which X-ray fluorescent screen is installed in series, a mirror located at an angle of 45 ° to the direction of light rays, lens, television camera based on photoelectric Additionally, it contains a computing unit connected to the output of the television camera, an X-ray exposure dose rate meter and a monitor, which are connected to the computing unit.

Description

The useful model belongs to the technique of radiation non-destructive testing and can be used in medical X-ray machines, for the control of cargo, the contents of luggage, the quality control of materials and products in industry and various branches of technology, in particular for defectoscopy of the walls of main pipelines.

Digital fluoroscopic radiography is the most widely used process to replace film radiography. Today, almost every district polyclinic has a radiological laboratory equipped with digital radiological equipment. This technique is widely used in the examination of suitcases, bags and various baggage at airports and train stations, and it is no exaggeration to say that thanks to it, it was possible to avoid the likelihood of numerous emergency situations and terrorist acts.

But the widespread use of radiological technology is somewhat hampered by its complexity and size, which makes its use in some conditions (for example, in the field) rather problematic. This problem creates the need to develop portable radioscopic equipment.

In the prior art, there are many publications aimed at improving existing and creating new types of these devices, which have both their advantages and disadvantages.

Yes, a known device based on an X-ray image receiver (patent RF Mo 2352086,

МПК":НОБа 1/64, publ. 10.04.2009), containing a case with one X-ray transparent wall, in which an X-ray fluorescent screen, a lens and a television camera based on a photoelectronic "light-signal" converter are sequentially installed. In such a receiver of x-ray images, the shadow x-ray image of the controlled object is transformed by the x-ray fluorescent screen into a visible one, which is then sent through the lens to the input of the television camera. The image of the internal structure of the controlled object is observed by the operator on a monitor connected by a cable to the output of the television camera and located on a safe distance from the source of X-ray radiation.

However, in all receivers of this class, there is the problem of protecting the photoelectronic converter of the television camera from the X-ray radiation that passes through the X-ray fluorescent screen and hits the converter, causing it

From destruction after some time of operation. In the receiver (patent RF Mo 2352086) for such protection, an X-ray fluorescent screen with an absorption of at least 30 95 X-rays is used, and the lens contains at least ten lenses with a refractive index of at least 1.6. All this significantly complicates the design of the receiver, and the large number of objective lenses increases the loss of light when transferring the image from the X-ray screen to the photoelectronic converter.

A device based on an X-ray image receiver is also known (patent 05 Mo 6002743, MPKU:O06T 11/00, publ. 14.12.1999), in which a plate of X-ray-proof lead glass is installed between the X-ray fluorescent screen and the lens to absorb residual X-ray radiation. Such a plate protects the photoelectric converter more effectively, the greater its thickness. Accordingly, the reliability of the receiver as a whole increases significantly. However, the use of such a plate leads to an undesirable side effect - to the amplification of parasitic light fluxes between the X-ray screen and the optical system and, as a result, to additional distortions of the output image of the controlled object.

The closest analog of a useful model is a device for X-ray television control, which consists of a light-proof housing, one of the walls of which is an X-ray window, in which an X-ray fluorescent screen, a mirror located at an angle of 45" to the direction of light rays, a lens, a television a camera based on a photoelectronic converter (X-ray technology: Handbook. In 2 books /

Ed. V.V. Klyueva, book 2. - M.: Mashinostroenieye, 1980. - P. 246.).

The mirror of the device changes the path of light rays from the X-ray screen by 90", which then enter the photoelectronic converter of the camera. Thus, the photoelectronic converter is removed from the direct X-ray beam passage zone due to the geometric separation of light and X-ray rays.

Such devices for X-ray television control usually work in the mode of separation in time of the processes of accumulation and reading of images in the photoelectronic converter, which allows to significantly improve the relative sensitivity of control. At the same time, for each combination of the type of material and the thickness of the controlled object, the electrical mode of operation of the X-ray machine (anode current and anode voltage of the X-ray tube) and the geometry of the transillumination, there is an optimal duration of image accumulation in the photoelectronic converter, which ensures the best quality of the X-ray image and the best detection defects in the controlled object. (Confirmation of this information is an article

Troitsky V.A., Beliy N.G., Buhensky V.N., Mykhaylov S.R. etc. High-sensitivity X-ray television system based on X-ray screens and CCD cameras with image accumulation // Technical diagnostics and non-destructive control. - 2009. - Mo 3. - P. 41-46.).

However, determining in practice such an optimal duration of accumulation is a difficult and time-consuming task, therefore, usually when using such devices, the duration of image accumulation in the photoelectronic converter does not correspond to the optimal one, which leads to a deterioration in the quality of X-ray images.

The basis of the useful model is the task of increasing the efficiency of the device for X-ray television control by improving its structural construction and optimizing the connections between elements, in particular, by equipping it with a computing unit connected to the output of the television camera, and an X-ray exposure dose power meter and a monitor, which are connected to the computing unit, which allows measuring the power of the exposure dose of X-ray radiation at the input of the device and calculating the required optimal duration of image accumulation in the photoelectronic converter, thereby ensuring high quality X-ray images of the controlled object and simplifying the operation of the device.

The task is solved by the fact that the device for X-ray television control, which consists of a light-proof case, one of the walls of which is an X-ray window, in which an X-ray fluorescent screen, a mirror located at an angle of 457" to the direction of light rays, a lens, a television a camera based on a photoelectric converter, according to a useful model, further includes a computing unit connected to the output of the television camera, an X-ray exposure dose power meter and a monitor that are connected to the computing unit.

The X-ray luminescent screen of the device can be made of a thallium-activated cesium iodide material, can be a terbium-activated gadolinium oxysulfide powder screen, and the terbium-activated gadolinium oxysulfide screen is flexible.

The device can be equipped with a mirror with an upper coating of a reflective layer made of aluminum or silver, a high-power lens with a variable focal length (vario lens) and at least one diaphragm.

A television camera for additional protection of the photoelectronic converter from direct and diffuse X-ray radiation can be placed in a lead protective screen with a through hole through which the lens is attached to the camera.

The above-mentioned technical result, which is achieved during the operation of the device, is due to the features by which it differs from devices of a similar purpose, in particular from the one described in the prototype. Thus, by equipping it with a computer unit that controls the operation of the device and connecting it to the output of the television camera, as well as by equipping the device with an X-ray exposure dose power meter connected to the computer unit, full compliance of the duration of image accumulation in the photoelectronic converter with the optimal value for each type of material and thickness of the controlled object, and, therefore, to improve the quality of X-ray images.

As an X-ray luminescent screen in the device, it is advisable to use efficient single-crystal screens based on cesium iodide activated by thallium C5I(TI) or powder screens based on gadolinium oxysulfide activated by terbium СагО25(ТІ). The advantage of screens based on gadolinium oxysulfide is their flexibility, which allows them to take the shape of the controlled object. Thus, the proposed device for X-ray television monitoring with a gadolinium screen is capable of acquiring a cylindrical shape and can be effectively used to monitor pipelines with a radius of at least 200 mm. The possibility of oval fitting of the pipe surface allows to increase the productivity of the control process, reduce the number of exposures and improve the quality of images.

The device for X-ray television control uses a mirror with an upper coating of a reflective layer made of aluminum or silver. This allows you to eliminate double reflection from the upper and lower surface of the mirror glass and provides more accurate adjustment of the device.

Matrix converters based on charge-coupled devices (CCD matrices) or matrix converters based on complementary metal-oxide-semiconductor structures are used as the photoelectronic converter of the device's television camera. (KMON matrices).

The device also uses a fast lens with a variable focal length (vario lens) and at least one aperture. The variable focal length of the lens allows you to change the size of the area of the X-ray fluorescent screen that fits into

P33- or KMON-matrix, and thus change the size of the working field and the spatial resolution of the device for X-ray television control. The presence of at least one diaphragm allows you to adjust the light flow entering the photoelectronic converter.

The television camera for additional protection of the photoelectronic converter from direct and diffuse X-ray radiation is placed in a lead protective screen with a through hole through which the lens is attached to the camera.

The drawing shows the structural diagram of the device for X-ray television control.

The device consists of a light-proof housing 3, one of the walls of which, directed towards the X-ray machine 1 and the controlled object 2, is X-ray transparent. Housing C contains an X-ray fluorescent screen 4, a mirror 5, a lens 6 and a television camera 7 based on a photoelectronic converter. Outside the housing C are the computing unit 8, the X-ray exposure dose power meter 9 and the monitor 10. To protect the photoelectronic converter from X-ray radiation, the television camera 7 is placed in a lead protective screen with a through hole through which the lens is attached to the camera (these elements not shown in the drawing).

The device works as follows:

The flow of X-ray radiation generated by the X-ray machine 1 shines through the controlled object 2 and falls through the X-ray transparent wall of the housing C onto the X-ray fluorescent screen 4, as a result of which a shadow X-ray image of the controlled object is created on its surface (the X-ray radiation is shown by dashed lines) . The X-ray fluorescent screen 4 converts the shadow X-ray image into a visible one. Light flux of the visible image using a mirror 5

Zo turns 90" and hits the lens b, which focuses the visible image on the photoelectronic converter of the television camera 7. The television camera 7 converts the visible image into a digital video signal that enters the computer unit 8, where it is stored and further displaying the image of the controlled object on the monitor 10.

The operation of the device for X-ray television control is controlled by computer unit 8. At the beginning of the work cycle, the X-ray machine is turned on and a certain electrical mode of operation of the X-ray tube (anode current and anode voltage) is set, which corresponds to the type of material and the thickness of the controlled object, as well as the geometry of the illumination . The best quality of the X-ray image will be ensured if the device during the image accumulation in the photoelectronic converter receives a certain optimal exposure dose of X-ray radiation Uop, which is determined experimentally once for each device for X-ray television control and is entered into the computing unit 8. Then the power meter of the exposure dose of X-ray radiation 9 measures the power of the exposure dose P for the controlled object at the entrance of the X-ray fluorescent screen 4, and the computer unit 8 calculates the necessary optimal duration of image accumulation in the photoelectronic converter T according to the formula Tn-ХОотп/Р and switches the photoelectronic converter of the television camera to the image accumulation mode for the time Tk. After the end of the accumulation mode, the image is read from the photoelectronic converter and stored in the computing unit 8, from which it is output for display on the monitor 10. This completes the work cycle of obtaining an X-ray image of the controlled object. Such a work cycle must be repeated if the type of material and the thickness of the controlled object change, as well as the geometry of the illumination.

A significant advantage of the proposed device is its compactness, small dimensions and available components included in its composition (tablet, computer, telephone, etc.), which made it possible to make it portable and convenient for work in the field.

For example, in 2017, the device was used to conduct digital radiological studies on the integrity of the protective plates of the body armor of ATO fighters. The results of these studies were successful and extremely important at the time they were conducted, and proved the feasibility and effectiveness of the device.

Information about the research is presented in the article, which can be read at the link Прр://1104781/как ргоигмодиейі ргопериій ідгауцші |ігпуати роіівом.

Claims (5)

USEFUL MODEL FORMULA 1. A device for X-ray television control, which includes a light-proof housing, one of the walls of which is an X-ray window, in which an X-ray fluorescent screen, a mirror located at an angle of 45" to the direction of the light rays, a lens, a television camera based on photoelectron the converter, which is characterized by the fact that it additionally contains a computing unit connected to the output of the television camera, an X-ray exposure dose power meter and a monitor, which are connected to the computing unit. 2. The device according to claim 1, which is characterized by the fact that the X-ray luminescent screen is selected from the series - a screen made of a material based on cesium iodide activated with thallium, a powder screen based on gadolinium oxysulfide activated with terbium, and a screen based on gadolinium oxysulfide activated terbium, is flexible. 3. The device according to claims 1-2, which is characterized by the fact that the device is equipped with a mirror with an upper coating of a reflective layer made of aluminum or silver. 4. The device according to claims 1-3, which is characterized by the fact that the device is equipped with a high-power lens with a variable focal length (vario lens) and at least one diaphragm. 5. The device according to claims 1-4, which is characterized by the fact that the television camera for additional protection of the photoelectronic converter from direct and scattered X-ray radiation is placed in a lead protective screen with a through hole through which the lens is attached to the camera. schi AI | shk Y She | | | : Kaya ro t Y : oh! Tk! we are 7 now shshi she; Iy t Mo Konya 00 Metu E m, : E sei, x I I N rya her i I mice