FR2869789A1 - Radiographic device, has anti-scattering discs with plates between which strips are placed, where each disc has core in which cylinder is placed to permit centering of rotational axis of disc on focal length of X-ray source - Google Patents

Abstract

The device has an X-ray source placed above a radiography table. An emitted X-ray receiver is positioned at the right side of the source under the table. Anti-scattering discs (6, 7) are constituted of two respective plates (8a, 8b) between which radio-opaque strips (9) are positioned. Each disc has a central core in which a cylinder is placed for permitting centering of rotational axis of the disc on focal length of the source. The disc (6) is placed between the source and a patient, and the disc (7) is placed between the table and the receiver.

Description

The present invention relates to an X-ray radiographic device or

  similar method comprising improving the S / P ratio of the scattered radiation to the primary radiation.

  X-ray radiographic devices having an X-ray source positioned above an X-ray table on which the patient to be radiographed is well known, said table being obtained in a radiolucent material, that is to say say a material permitting X-rays, an X-ray receiver emitted positioned in line with the X-ray source beneath the X-ray table and means for processing the data received by the receiver in order to transform them into an image. The image thus obtained is representative of the absorption of radiation through the body of the patient. Nevertheless, when the X-rays emitted by the source of emission pass through the body of the patient, certain rays interact with the matter and are diverted to form so-called scattered rays which, when they reach the receiver, limit the contrasts of the images. Thus, X-ray scattering affects the sharpness of the image. It will be observed that this scattered radiation consists of secondary photons of low energy resulting from the Compton interactions which are emitted while passing through the body of the patient in all directions and more particularly in the direction opposite to the incident X-ray beam.

  In order to remedy this problem, an anti-scattering grid positioned between the patient and the X-ray receiver has already been devised. This grid makes it possible to absorb a part of the scattered radiation, thus improving the sharpness of the image. This grid is composed of a series of blades obtained in a radiopaque material, said blades being all directed towards the focal point of X-ray radiation emitted towards the patient and the X-ray receiver. Thus, when the scattered radiations pass through the grid, these are absorbed by the radiopaque blades allowing only the incident rays said spokes primary. Nevertheless, the resolution APL-EN-4 TEXTE REMOVAL - 2 - X-ray receivers is generally less than the space between two successive blades so that the blades appear, like a shadow, on the image formed on the receiver X-ray, which is likely to be a problem for medical diagnosis.

  In order to overcome this drawback, it has already been imagined to linearly oscillate the grid in its plane along a short path so that the blades are no longer in a fixed position when exposed to the X-ray. such oscillating anti-diffusion grids are commonly referred to as Bucky grids. Although this oscillation of the gate decreases the intensity and, consequently, the contrast of the image formed on the receiver, said oscillation makes it possible to suppress the shadow of the blades on said receiver, thus improving the sharpness of the image.

  All these anti-diffusion devices have many disadvantages. Indeed, the focused grids are particularly sensitive to their positioning relative to the X-ray source. A defocusing, an insertion in the wrong direction or a bad adjustment of the orthogonality of the grid relative to the primary beam of X-rays causes a significant absorption of said primary beam and, consequently, a decrease in the contrast of the image obtained. The focus of these focused gates is perfect only in the plane of symmetry of the array of blades, that is to say in the plane orthogonal to the grid containing the axis of the primary beam of the radiation source. Therefore, any angular deviation of the plane of propagation generates an absorption of the beams of the primary beam. Finally, these grids are particularly fragile and expensive.

  In order to remedy all these drawbacks, anti-diffusion devices have already been devised consisting of radiopaque disks provided with radial slots and rotatably driven in a synchronized manner allowing the passage of the primary rays and stopping the scattered rays.

  This is the case, for example, of the American Patent Code APL-FR-4 TEXTE DEPOSE 3 US 4 315 146 which describes a method and a device for reducing the radii scattered radiography. The device comprises discs rotated synchronously. These discs are positioned between the patient and the source of X-ray emission and respectively between the patient and the receiver of said X-rays, each disc being obtained in a radiopaque material provided with radial slots. The slots of the different disks are in line with each other so as, on the one hand, to allow the passage of the primary rays of the source of X-ray emission in a quantity just sufficient for the cliche to improve efficiency. of the dose and, secondly, to avoid the passage of the scattered rays emitted by the source of X-ray emission and / or emitted during the passage of primary rays through the body of the patient.

  Although these devices improve the sharpness of the image, the latter is not optimal because, the axis of rotation of the discs not being aligned with the focusing axis of the X-ray emitter, part of primary rays emitted by the X-ray emission source is absorbed by the radiopaque discs. Indeed, the discs of the prior art have in their center is a recessed area or an opaque radio zone, given the lack of precision of the slot cutting means, which affects the sharpness of the image.

  One of the aims of the invention is therefore to remedy all these drawbacks by proposing an X-ray radiographic device comprising means for limiting the amount of scattered X-rays reaching the X-ray receiver of a simple and inexpensive design.

  For this purpose and in accordance with the invention, there is provided an X-ray radiographic device comprising at least one X-ray source positioned above an X-ray table on which the patient to be X-rayed rests, an X-ray receiver. emitted positioned at the X-ray source beneath the X-ray table, means for processing the data received by the receiver in order to transform them into an image and the means for limiting the quantity of the X-ray source. X-ray scattered with respect to the X-ray forming an image on the receiver, said means being constituted by at least two disks which, extending coaxially with the emission focal length of the X-rays, are respectively positioned between the source of X-ray emission and the patient is between the X-ray table and the X-ray receiver, and are rotated in rotation about their axis, each disk having a succession of radiopaque sectors and radio-transparent radial sectors; said device is remarkable in that each disk consists of two generally circular plates, obtained in a radiolucent material, between which radiopaque lamellae are positioned, said plates and said lamellae being held in position by an annular flange.

  It is well understood that unlike the devices of the prior art, where the discs are radiopaque discs in which are cut radial slots, which, given the fineness of the slots required in the central part of the disc, is particularly expensive; the device according to the invention makes it possible to produce anti-diffusion disks at a lower cost while providing the desired effect of absorption of the scattered rays.

  In order to allow centering of the axis of rotation of the disk on the focal length of the X-ray emission source, each disk advantageously comprises, between the radiolucent plates, a central recess known as hub in which is positioned either a cylinder obtained in a material having a uniform absorption mass coefficient, preferably substantially equal to the absorption coefficient of the succession of radio-opaque and radiolucent radial sectors, or a cylinder obtained in a radiolucent material at one of the ends of which is engraved a spiral in a radiopaque material, the center of the spiral coinciding with the axis of the disc, a cut of a flat spiral spring obtained in Code APL-EN-4 TEXTE REMOVAL - 5 - radio-opaque material forming a spiral lamella positioned in the hub of the disc so that the center of the spiral lamella coincides with the axis of the disc.

  Other advantages and features will emerge more clearly from the following description of several variant embodiments, given by way of non-limiting example, of the radiographic device according to the invention, with reference to the appended drawings in which: FIG. 1 FIG. 2 is an exploded perspective view of an anti-scattering disk of the radiographic device according to the invention; FIG. 3 is a perspective view of the radiographic device according to the invention; a cylinder positioned in a central recess practiced between the radiolucent plates of the antidiffusion disc shown in FIG. 2; FIG. 3B is a perspective view of an alternative embodiment of the cylinder positioned in the central recess practiced between the radiolucent plates of the disc shown in FIG. 2; - FIG. 3C is a perspective view of a spiral lamella positioned in the recess; FIG. 4 is a cross-sectional view of an alternative embodiment of the anti-scattering disk shown in FIG. 2; FIG. 2 is a cross-sectional view of the anti-scattering disk shown in FIG. FIG. 5 is a cross-sectional view of a last variant embodiment of the anti-diffusion disc according to the invention shown in FIG.

  With reference to FIG. 1, the radiographic device comprises an X-ray source 1 positioned above a radiography table 2 on which a patient 3, obtained in a radiolucent material, bears, said X-ray source being Code APL-1. FR-4 REMOVAL TEXT 6 - positioned so that the focal length of the X-ray emission source 1 is substantially orthogonal to the plane of the X-ray table 2, and an X-ray emitter 4 positioned at the source X-ray 1 beneath the X-ray table 2, said receiver 4 also being positioned so that it is substantially orthogonal to the focal length of the X-ray emission source 1. The x-ray receiver 4 is connected to processing means 5 data received by said receiver 4 such as an image processing computer for example. The X-ray source 1 is, for example, constituted by a tungsten-coated copper or molybdenum target placed in a high vacuum and bombarded with electrons in order to emit a spherical photon beam which is advantageously focused by jaws. in lead and homogenized by a filter at the exit of the head of said X-ray source 1. In spite of the homogenization filters of the X-ray beam emitted by the X-ray source 1, the latter may emit scattered rays capable of altering the sharpness of the image collected by the receiver 4. In order to limit, or even to suppress, these scattered rays, the radiographic device according to the invention advantageously comprises a first anti-diffusion disc extending coaxially with the focal length X-ray emission between the X-ray emission source 1 and the patient 3, said disk 6 comprising a succession of radio-opaque radial sectors and radio radial sectors -Transparents rotated as will be detailed below.

  Moreover, in order to limit or even eliminate the scattered rays produced during the passage of primary X-rays through the body of the patient 3, the device advantageously comprises a second antidiffusion disc 7 extending coaxially with the emission focal length. X-ray 1, and positioned between the X-ray table 2 and the X-ray receiver 4, said disk 7 comprising a succession of lamellae in the form of radio-opaque radial sectors 9 and radial sectors Code APL-EN-4 TEXT REMOVAL - 7 - radio-transparencies 9 'and being driven synchronously in rotation about its axis with the first disk 6 as will be detailed below.

  With reference to FIG. 2, each disc 6, 7 consists of two generally circular plates obtained in a radiolucent material, such as polycarbonate for example, a first upper plate 8a and a second lower plate 8b, between which sectors are positioned. Radiopaque radials 9. A constant angular aperture is maintained between two successive radio-opaque radial sectors 9 in order to provide radiolucent radial sectors 9 ', in the air being radiolucent.

  It is obvious that radial sectors obtained in a radiolucent material 9 'can be positioned between two radial radiopaque sectors 9 successive without departing from the scope of the invention.

  In order to ensure a constant angular opening between two radio-opaque radial sectors 9, the inner face of the upper plates 8a and lower 8b are advantageously provided with radial slots 10 flaring from the center of the plates 8a, 8b to their periphery and in which the radio-opaque radial sectors fit together 9. The upper plates 8a and lower 8b and the radiopaque radial sectors 9 are held in position by an annular flange 11 consisting of two hemi-annular portions 11a and 11b respectively provided with male and female fasteners not shown in FIG.

  In order to overcome the difficulty of machining the tips of the radial sectors 9 'so that said tips of said radial sectors 9 join along the axis of rotation of the disk 6, 7, the latter advantageously comprises between upper trays 8a and lower 8b a central cylindrical recess said hub 12 extending coaxially with the trays 8a, 8b from the upper plate 8a to the lower plate 8b. The diameter of this hub 12 is as small as possible in order to limit the diffusion phenomena and it is able to receive primary X-ray filtration means. Moreover, the inner faces of the upper plates 8a and lower 8b comprise a central recess 13 coaxial with the same diameter as the hub 12.

  With reference to FIG. 3A, the X-ray filtering means consist of a cylinder 14 obtained in a material having a uniform absorption mass coefficient, said cylinder 14 having dimensions just smaller than the dimensions of the hub 12 in order to allow its introduction in the latter. The mass absorption coefficient of the cylinder 14 placed in the hub 12 of the disk 6, 7 is advantageously equal to the absorption coefficient of the succession of radiopaque radial sectors 9 and radiolucent 9 '. It will be observed that the mass absorption coefficient is usually expressed in cm 2 / gr and is equal to the linear absorption coefficient (Ex) divided by the density (p) of the material. This mass coefficient of absorption enters into the relation allowing to express the intensity I of a beam emerging from a thickness of matter crossed by an incident beam of intensity and which is written in the form: I = Ioxe According to an alternative embodiment of the device according to the invention, with reference to FIG. 3B, the filtering means consist of a cylinder 14 'obtained in a radiolucent material and of dimensions just below the dimensions This cylinder 14 'comprises at one of its ends, preferably the upper end, a spiral 15 etched in a radiopaque material, such as lead, tantalum, tungsten or the like, the center spiral 15 being coincident with the axis of revolution of the cylinder 14 'and, therefore, with the axis of the disk 6, 7 in which the cylinder 14' is placed.

  According to a last alternative embodiment of the means of filtration capable of being positioned in the hub 12 with reference to FIG. 3C, the said filtering means consist of a cut of a flat spring. in a spiral, obtained in a radiopaque material, forming a spiral lamella 16 adapted to be positioned in the hub 12 of the disk 6, 7 in such a way that the center of said spiral lamella 16 coincides with the axis of the disk 6, 7.

  According to another variant embodiment of the radiographic device according to the invention, with reference to FIG. 4, each disc 6, 7 comprises, in addition to the central hub 12, two generally concentric parts 17a, 17b respectively provided with a succession of sectors. radiopaque radials 9a, 9b and radial radiolucent sectors 9'a, 9'b, the angular aperture of the radial sectors 9a, 9'a of a first portion 17a being preferably a multiple of angular opening of the radial sectors 9b, 9'b of the second portion 17b concentric. Thus, in the exemplary embodiment shown in FIG. 4, the first portion 17a of the disk comprises 60 sectors of an angular aperture of 6 each and the second portion 17b of said disk 6, 7 comprises 120 sectors each having an angular aperture of 3, the angular opening of the sectors 9a, 9'a of the first part 17a thus being twice as large as the angular opening of the sectors 9b, 9'b of the second part 17b concentric.

  It is obvious that each disk 6, 7 may comprise more than two concentric parts 17a, 17b respectively provided with a succession of radio-opaque radial sectors 9a, 9b and radiolucent radial sectors 9'a, 9'b, in which the angular opening of the sectors 9a, 9'a of a portion 17a is different from the angular opening of the sectors 9b, 9'b of each of the other concentric portions 17b of said disc 6, 7, without departing from the scope of the invention.

  Furthermore, the separation line 18 between the two concentric portions 17a, 17b of sectors APL-FR-4 TEXTE DEPOSE - 10 radial 9a, 9'a; 9b, 9'b advantageously consists of a spiral branch of 360 whose center is coincident with the center of the disc 6, 7 and whose free ends are joined by a radial line segment which is advantageously merged with the side of a radial radiopaque sector 9a of the first portion 17a with the radiopaque radial sector side 9b of the second portion 17b concentric. Such a separation line 18 between the two parts 17a, 17b in the form of a spiral, makes it possible to avoid the artifacts associated with the projection of the shadow of a circular separation line. Thus, the separation line moving during the exposure time of the image, the latter wants to be confused with the image blur.

  It goes without saying that the line of separation 18 between the two parts 17a and 17b may nevertheless consist of a circular line without departing from the scope of the invention.

  According to a last variant embodiment of the disks 6, 7 of the radiography device according to the invention, with reference to FIG. 5, each disk 6, 7 is, in the same manner as previously, constituted by two generally circular trays obtained in a radiolucent material between which are positioned one or more radio-opaque lamellae, said plates and said lamellae being held in position by an annular flange not shown in FIG. 5. In this particular embodiment, each disc 6, 7 comprises radiopaque strips 9 in the form of identical spirals angularly offset by an angle 8 = 2 n n imbricated in each other leaving a constant empty space between two lamellae 9 in the form of consecutive spirals. It will be noted that the spaces formed between two consecutive radiopaque strips 9 form transparent radio-shaped lamellae 9 'in the form of spirals. Moreover, such a construction makes it possible to obtain a particularly rigid disk allowing low exposure times.

  However, it is quite obvious that the disk 6, 7 may comprise a single radiopaque strip 9 wound up in a spiral of a radial pitch k, the center of the spiral coinciding with the center of rotation of the disc 6, 7 without departing from the scope of the invention.

  With reference to FIG. 1, in order to drive the disks 6, 7 in rotation about their axes, the latter are respectively positioned in a circular rail 19 provided with holding rollers and drive means for rotating the disk, said drive means consisting, for example, in a ring gear cooperating with a toothed gear integral with the output shaft of an electric motor, or in an annular bearing also provided with means for driving the disk in rotation.

  Furthermore, the device comprises firstly means for measuring the angular travel of the disk 6, 7 from its initial angular position corresponding to the position of the disc 6, 7 at the initiation of the emission of X-rays by the source X-ray emission 1 until the receiver 4 has received the minimum exposure of X-rays, the disc 6, 7 then being in a so-called intermediate angular position, and secondly means of calculating the final angular position of the disk at which the X-ray emission is stopped so that the amount of primary X-rays received by the receiver 4 is homogeneous.

  It goes without saying that the radiopaque material in which the slats 9, 9a, 9b are obtained consists of a material having a high atomic number such as lead, cerro, tantalum, tungsten or the like and that the radio material in particular, the upper plates 8a and 8b of the disks 6, 7 are obtained, for example, in polycarbonate of polymethyl methacrylate (PMMA) or the like.

  Finally, it goes without saying that the x-ray device may have a vertical X-ray table 2, the emitted X-ray receiver 4 being positioned in line with the x-ray source 1 behind the x-ray table 2 and the x-ray source 1 extending to the right of said table so that the focal length of the X-ray emission source 1 is generally orthogonal to the plane of the X-ray table 2, it is - ie horizontal, to perform chest X-rays and the examples just given are only particular illustrations in no way limiting as to the fields of application of the invention.

Code APL-EN-4 TEXT REMOVAL - 13 -

Claims (12)

  1 - X-ray radiographic device comprising at least one X-ray source (1) positioned at the right of a radiography table (2) on which the patient (3) to be radiographed bears, an X-ray receiver emitted (4) positioned at the X-ray source (1) behind the X-ray table (2), means (5) for processing data received by the receiver (4) to transform them into images and means (6, 7) for limiting the amount of X-ray scattered relative to X-rays forming an image on the receiver (4), said means (6, 7) being made of at least two disks (6, 7) which, extending coaxially with the X-ray emission focal length, are respectively positioned between the x-ray source (1) and the patient (3) and between the x-ray table (2) and the x-ray receiver (4) , and are driven synchronously in rotation about their axis, each disk (6, 7) comprising a succession of radiopaque lamellae (9) and radiolucent lamellae (9 ') characterized in that each disc (6, 7) consists of two generally circular trays (8a, 8b) obtained in a radiolucent material, between which are positioned radiopaque lamellae (9), said plates (8a, 8b) and said lamellae being held in position by an annular flange.   2 - Device according to the preceding claim characterized in that each disc (6,7) comprises between the radiolucent plates (8a, 8b) a central recess said hub (12).   3 - Device according to claim 2 characterized in that it comprises a cylinder (14) obtained in a material having a mass coefficient of homogeneous absorption.   4 - Device according to claim 3 characterized in that the mass absorption coefficient of the cylinder (14) placed in the hub (12) of the disc (6,7) is generally equal to the absorption coefficient of the Code APL-FR -4 TEXT REMOVAL - 14 - succession of radiopaque (9) and radiolucent (9 ') lamellae.   - Device according to claim 2 characterized in that it comprises a cylinder (14 ') obtained in a radiolucent material on at least one of the transverse walls is etched a spiral (15) in a radiopaque material, the center of the spiral (15) coinciding with the axis of the disk (6, 7).   6 - Device according to claim 2 characterized in that it comprises a cut of a spiral flat spring obtained in a radiopaque material forming a spiral strip (16) positioned in the hub (12) of the disk (6.7 ) so that the center of the spiral strip (16) coincides with the axis of the disk (6, 7).   7 - Device according to any one of the preceding claims characterized in that each disc comprises at least two parts (17a, 17b) generally concentric respectively provided with a succession of radiopaque radial sectors (9a, 9b) and radial sectors radiotransparents (9'a, 9'b), the angular aperture of the sectors (9a, 9'a) of a first portion (17a) being different from the angular aperture of the sectors (9b, 9'b) of the concentric second part (17b).   8 - Device according to claim 7 characterized in that the angular opening of the sectors (9a, 9'a) of a first portion (17a) is a multiple of the angular opening of the sectors (9b, 9'b) of the second part (17b) concentric.   9 - Device according to any one of claims 7 or 8 characterized in that the line of separation (18) between two generally concentric parts, consists of a spiral branch of 360 whose center is coincident with the center of the disc (6 , 7) and whose free ends are joined by a radial line segment.   - Device according to claims 8 and 9 characterized in that the radial straight segment joining the free ends of the spiral branch is coincident APL-FR-4 code TEXT REMOVAL - 15 - with the side of a radiopaque radial sector (9a) of the first portion (17a) and with the side of a radiopaque radial sector (9b) of the second portion (17b) concentric.   11 - Device according to any one of the preceding claims, characterized in that each disc (6,7) is positioned in a circular rail (18) provided with holding rollers and drive means for rotating the disc (6,7). ).   12 - Device according to claim 11 characterized in that the drive means consist of a ring gear cooperating with a toothed gear integral with the output shaft of a motor.   13 - Device according to any one of   Claims 1 to 10 characterized in that each   disc (6,7) is positioned in an annular bearing (18) provided with drive means for rotating the disc (6,7) 14 - Device according to any one of the preceding claims, characterized in that it comprises a part of the means for measuring the angular position of the disk (6,7) from its starting angular position corresponding to the position of the disk at the initiation of the X-ray emission until the receiver (4) has received the minimum exposure of X-rays, the disk (6,7) then presenting itself in an intermediate so-called angular position, and secondly means for calculating the final angular position of the disk to which the X-ray emission is stopped in such a way that the amount of primary X-rays is homogeneous on the receiver (4).   15 - Device according to claim 14 characterized in that the calculation means cut the X-ray emission when on the one hand, the minimum exposure of X-rays is reached and on the other hand, an integer number of alternations of radio-opaque areas (9) and radiolucent sectors (9 ') is reached. Code APL-EN-4 TEXT OF INSTALLATION