SU1648376A1 - X-ray tomograph - Google Patents

Abstract

The invention relates to medical technology. The purpose of the invention is to improve the accuracy of image recovery and reduce exposure time by achieving the fact that in a tomographic X-ray device containing coaxially arranged X-ray tube 1, a rotatable slot collimator 2, a differential detector 3 and electrically associated with them a signal processing and image recovery system, X-ray tube is made with rotating system anode - slit rotary collimator and with fan-shaped gas-wrench of a point scanning beam of x-ray diffraction Cheney. 4 il.

Description

1

Isobolite), with to chedssch. technology, in particular for X-ray diagnostics

The purpose of the invention is to improve the accuracy of image recovery and reduce the exposure time /

Fig. 1 shows the function & diagram of the device, Fig. 2 shows the options for implementing the device (different - jc ti) vdr from the top and sbsk, n Fig. 3 shows the rotation scheme of the anode system - a slit v matrix with a rotary regulator in Fig. 4, a collimation slit with distances, pampro form pacro, rioxs nomes intersection in the plane

The trio contains an e-tube 1, a rotary click with limayo 2, a differentiating detector 3 sistem, 4 and 5 signal processing and restoration of the image

X-ray tube s) and connected with the differentiating detector in 3 way, iTOObi input window 6 of the diffractive detector of the rms state / position in the fan sweep point of the scanning beam 7 / irradiation from the air outlet port 8 pen i gene tube 1 This B design is enops. jBCc..11 tube a / edite zrazglyayuschie sp anode 9 you ech non, s t dimer and A prowl | H 10 two HJ g. IL (DR 11 DIZM8, roZO / YuM /

corresponds to the diameter of the bump. In the cylinder 11, rotating i3rotn circulates a cooling 1 slotted 9 inserted into the pliid of the left collimator 2 (figure /) with a / n calculation so that the gap in the obazovacnye with lindra clearance would put s rions.in the cathode 13 with antis-nsdom 14, t-free warping was carried out, which is 15 anode slit gtor

The stationary cathode 3G of p-v v 1 is made in the form of two zalchals and related parts, stretches with- v 13 p Fok ngo go spot 16 of the anode 9 and w its mechd / o / bay gap sufficient enough to get through hsni point scan on the beam and descend from the cathode to Hais

Slot-hole laminator 2 has COLLIMATION slots 17, noti-angled to the focus line, - a southern section 16 of the anode 9 so that the beginning of the slit is located on the same level as at the end of the first axis along the line of the axis and of the hydride length of the slot according to the length of the focal point of the 16 anode 9, each chip contains a set of partitions 18 perpendicular to the plane of the anode 0 and rg-pololech, so that the medium is 1 °

j. h and klippi ya H with the entire length of the focal spot 16 formed a fan shading of the x-ray point scanning beam. At the same time, a set of partitions 18 of each collimation slit 17 forms a fan tail with a defined focal distance and a displacement of the axis, a fan, and a body, a pattern, and a body, and a body, a pattern, a focal distance, and a displacement of the axis, fan, and the body, the body, and the body, the body of the body, the body of the body, the body of the body, the body of the body, the body of the body of the body, the body of the x-ray beam, the focal length, 18 of the focal spot 16 About with 9 Nzboo, adok 18 mozht to form carried o / kko fan razoyuk z

0) Oh shch: G 1

Will sweep d i5 node of the slot to the l l mm mm ator

twQ, n, ood Bp iuen 1 with a regulator 19

P rotations of rotation in the composition of

A glock of pgrs and sync when

condition of connection between the transmitter

9 C "Mjp Chg 805TsSSCHI vl SYSTEMS 4 OBZ5: i l sy rychloch

0slagodzr Nvli “yu additional

The openings 21, on the cylinder of the slotted collimator 2, are synchronized and synchronized and coded by signals taken from the detector 3 with a specific

 / yumei 1 about federa tion (olpimatsiN th th. photo ncs about the co-ordinate sensor, nijaT u, u O4i.

 i-jinn is associated with the system

5. -fi system of bb 20 board

O i /. c / inxpT 1zatpm in ao, T and the same bocci 2 and 23 sisokogog. power pack and herzgch charges, csv xv related

leV / J. „SOGI SIBI AND TIES

/ Tooches of kooodina (those are shown) of the LRB from the Duplex holes of 21 pioieh from the control and synchronization unit 20 of the control unit / and connection with cncTeMot 4 processing

fi The preemptive tsector 3 contains a dhop matrix 4 divided between

goboi about x-ray

  id ty H agsoial 25 thickness cat rj bmaeicp from foomula v f (N)

1-matrix of the matrix 4 in the detector and & o, oC1-i-e of material 25 rcc. Iyuga11 with its fusion plane fd3aapTfM pf-schstom to close in the op. a / cda matrices on Bcefvi from i-psh / -5C and rstso spernoy raz nepiKH

K-ATSZG & Geptsa 4 contains a set of 4f-Ot “sensors“ .divided .exAv by itself and is located eix other about him differently in the course of / in the form of strips, stretched 5 times to the oTri fan rcchvrat, d with his raster, way, ahhm the sensor had a definite sensibility — 3T dccTs quenched read by B dvdule r - - 0), Ml - —.k i, i dtch. Tomographic 051 ire jo t, (/ ss eohit

also standard signal processing and image recovery systems.

Tomographic x-ray device operates as follows.

In the area of the fan scanning of the point scanning beam 7 of the radiation of a rigidly connected X-ray tube system 1 - the differentiating detector 3 is placed the object 27 of the study. Depending on the purpose of the study, one of the standard programs is set, or a free program, in which the exposure modes are set in advance and using the speed controller 19, the rotation speed of the anode-slider collimator drive system 15 provides the geometric resolution required for the research goal. An X-ray tube 1 and a differentiating detector 3 are supplied with a preparatory voltage. This starts the rotation of the anode slit collimator system 15, heating the cathode 13 in the x-ray tube 1 and charging the initial potential of the x-ray sensors 26 in the differential detector 3.

The duty cycle begins with the supply of high voltage to the rotating anode 9 and cathode 13 with anti-anode 14, whereby the electron beam rushes to the anode 9 and slows down in the area of the focal spot 16 of the anode 9. As a result of braking, a pool of electrons forms 99% of heat and 1 % x-ray. During the rotation of the anode 9, the wire 10 is uniformly heated. It transfers excess heat to the cylinder 11. The cooling medium 12 circulating through the lumen of the cylinder 11 moves at a speed sufficient to extract heat and cool the cylinder 11 of the rotating anode 9.

Point scanning beam 7 goes through the outlet 8 of the x-ray tube 1.

Reading signals from differentiating detector 3 begins after triggering a coordinate sensor (not shown), which is part of the synchronization control unit 20, by affecting it with x-rays passing through the additional key hole 21 of the slotted rotary collimator 2.

The key hole 21 encodes information about a specific collimation slit 17. That allows you to turn off the high voltage and get all the necessary information at one turn of the anode system 15 - a slit rotary collimator.

At each time point of the study, X-ray radiation is emitted only through one hole formed by the walls of the collimation gap 17 and transverse partitions 18, in the form of a directional scanning beam 7 in a certain way. When the entire length of the focal spot 16 intersects the entire length of the collimation gap 17, a sweep is formed (or several fan sweeps) of the point scanning beam 7 with given partitions 18 of the creeping slit 17 by the focal distance and displacement of the axis of the fan sweep relative to si5 Tel'nykh center of the focal spot 16, i.e., provides an object scan with a 27 x-ray scanning point beam 7 with known beam coordinates at each time point.

0 By synchronizing the high voltage generator unit 22 and the detector charging unit 23 with the initial potential, the synchronization and control unit 20 is autoregulated.

5 voltages, i.e. operation of the X-ray tube 1 and the differentiating detector 3. This allows the entire tomographic X-ray device to be powered from un-energized current sources, for example, mobile power plants, and also allows to obtain comparable X-rays from the X-ray sensor 26 with the differentiated detector 3 Vanilla on the intensity of radiation transmitted through the object 27. Since all sensors 26 differ in their sensitivity to x-rays, the point-scanning scanner 7 that has passed through

0 object 27 of the study, triggers the sensors 26, depending on the intensity.

The signal from the differentiating detector 3 enters the address-coordinate

5 is a unit (not shown) included in the control and synchronization unit 20, and from there with the assigned coordinate address and material density of the object under study 27 into a computer memory (not shown) of the system 4

0 signal processing, where the further processing of signals received during one revolution of the anode-slot rotary collimator system 15, and the restoration of the tomogram image of the cross-section 5 for the object under study 27 in a known manner.

The rotating anode 9 of the X-ray tube 1 operates as follows.

For each power value of the X-ray tube 1, the program for controlling the circulation of the cooling medium 12 is calculated in such a way that the flow of the cooling medium is sufficient to select the generating heat during operation. This takes into account the magnitude of the current and high voltage on the X-ray tube, the heat production coefficient of the electron beam, the thermal conductivity of the wire 10 of the anode 9 and cylinder 11, the coefficient of heat capacity of the cooling medium and the operating time. The coolant circulation control program is synchronized in the control unit 20 with the plant control programs, which provides automatic control of the rotating anode operation in a pre-selected mode.

The cathode 13 with antianode 14 operates as follows.

When a voltage is applied to the cathode 13, an electron cloud is formed around each of its mirror parts due to their heating. When a high-voltage potential is switched on from cathode 13 to anti-anode 14, a stream of electrons rushes, forming in the form of a plane due to the electromagnetic field of anti-anode 14, thus forming a linearly extended focal spot 16 on the rotating anode 9. To create an adequate electron beam density m its uniformity both mirror parts of the cathode 13 have a high degree of processing and sufficient diameter, and the solenoids of anti-anode 14 have a sufficient amount of WITCH.

Slit surface collimator 2 works as follows.

When applied to the X-ray tube 1 of the preparatory voltage, the system of 15 cylinders anode-collimator rotates at a pre-selected speed.

The rotational speed of the slit collimator 2 is calculated from the condition of sufficient exposure time of the differentiating detector 3 with the point scanning beam 7 and is set by the drive controller 19. When a high voltage voltage is applied to the X-ray tube 1, X-ray emission starts through the holes of the collimation slots 17 that are currently at the intersection with the focal spot line 16. After the focal spot 16 intersects with the additional key hole 21 by triggering the coordinate sensor (not shown) begins reading signals from. differentiating detectors 3 for a given program. Since the number of slots 17 on the collimation cylinder is known, after

the intersection of all the collimation gaps 17 with the focal spot line 16 of the anode 9, the coordinate sensor shuts down the readout system and the high voltage on

x-ray tube 1.

In a certain way, the partition walls 18 of the collimation slots 17 form at each instant of time a point scanning beam 7 with a given

0 by the direction of radiation, and the entire set of partitions 18 of the water collimation slit 17 allows, during this intersection of the focal line, to form a 16-fan sweep or several fan sweeps with a certain focal length and / or displacement of the fan-axis axis relative to the center of the focal point It is 16. Thus, a condition is created under which, due to the rotation of the system 15, the anode-collimator forms a certain set of fan sweeps, sufficient to obtain a tomographic slice of the object 27.

Differentiating detector 3 of X-ray Neva radiation works as follows.

Due to the fact that the sensitivity of sensor 26 is determined by the formula z y (M)., Where M is the number of sensors 26 in the matrix,

About the amount of radiation power, each sensor is triggered with a normalized sensitivity. Since a certain number of sensors are assembled into a matrix in decreasing or increasing sensitivity to X-ray gene rays one after another along their course, and the individual matrices 24 are separated by a layer of absorbing rays of material 25, it becomes possible to differentiate a scanning point beam passing through the object 27 under study a large number of steps. Each stage, to which a separate normalized sensitivity of sensor 26 corresponds, registers a certain density of the research material being studied, which makes it possible to obtain density data without mathematical calculation of their value and significantly shortens the signal processing time. Since differentiating detector 3 has no divisions along the course of the fan sweep, this allows the detector to change its geometric resolution by synchronizing the frequency of the signals with the fan sweep speed and, when the speed of the fan sweep is increased, to increase the geometric resolution of the controlled plane over a large range depending on research objectives by changing the rate of information gathering from a differentiating detector. After the synchronization connection between the charging unit 23 and the initial potential of the differentiating detector and the high voltage generator unit 22 of the x-ray tube, the ratio of the sensitivity of the sensors 26 to the radiation power remains unchanged throughout the study. This allows the use of any type of current source.

An x-ray tomographic device can significantly improve image recovery accuracy by increasing the resolution with a simultaneous decrease in the sensitivity of sensors to spurious radiation. This is achieved due to the presence of an x-ray radiation device with a point fan scanning radiation beam and a differentiating detector, each sensor of which is elongated along a fan sweep and has a normalized sensitivity. The exposure time is reduced by limiting the time of translucency by one turn of the anode-slit collimator system. In addition, the radiation load on the object of study and into the surrounding space is significantly reduced due to the fact that the radiation beam emitted through the collimation orifice is point-like and does not have parasitic rays.

In addition, the use of an x-ray tube with a rotating anode and a rotary slotted collimator in a tomographic x-ray device makes it possible to significantly reduce the cost of the entire device by eliminating the complex high-frequency systems of mechanical displacements (translational and rotational) of the x-ray tube and detector.

The use of a differentiating detector allows one to obtain a signal with an assigned density and a coordinate address without having to calculate the density of each point of the plane under investigation at each time point. In addition, the quality of the reconstructed image of the tomographic slice of the object is higher due to the absence of artifacts that are inevitable when using traditional tomographic equipment.

Claims (1)

Tomorrow X-ray device containing coaxially arranged X-ray tube, rotatable a slit collimator, a differentiating detector, and an electrically coupled signal processing and image recovery system, characterized in that. that, in order to increase the accuracy of the restoration of the image and reduce the exposure time, the X-ray tube is made with an anode-slot rotary collimator rotating system, a fixed cathode with an anti-anode is placed in the inter-v gap between the anode and collimator cylinders, and both cylinders are connected a rigid system, in the cylinder of a slotted collimator are collimation slots at an angle to the line focal point of the anode in such a way that the beginning of each slit is at the same level along the long axis of the cylinder with the end of the previous one, and the size of the slit corresponds to the size of the focal point, in continuation the collimation slit lines in the slit rotary collimator cylinder are an additional key hole or a set of DENIED, each collimation slit contains a set of partitions installed perpendicular to the plane of the focal point of the rotating anode and arranged to form at the intersection of the entire length of the collimation slit; the entire length of the focal spot of the anode of the sweep of the point scanning beam peHTrertOBCKoro radiation, in the plane of which the entrance window of the X-ray radiation detector is installed, while the detzctor contains a set of matrices located in the plane of the fan sweep of radiation separated from each other by a layer of absorbing X-rays of material calculated by the formula for f (N), where (M is the number of matrices in the detector, and each matrix contains a set of x-ray sensors, which are located one behind the other in oskosti fan sweep perpendikulzrno move point scanning beam in the form of strips, elongated in the plane aeernoy sweep, each sensor has a normalized sensitivity calculated by formula z - p (M), where M - the number of sensors the matrix. Fig.Z  / I. N Fig