Patent Number: 045340528
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENT FIG. 1 shows a first limiting block 1 in accordance with the invention, having a longitudinal axis Y--Y perpendicular to a reference direction A, in which is emitted a radiation beam (not shown in FIG. 1). This limiting block 1 comprises an active surface 2 cylindrical in shape having as directrix an arc of a circle 3, formed by an edge of the active surface 2. The arc of a circle 3 comprises a center O situated on an axis V--V parallel to the longitudinal axis Y--Y and passing through one end 17 of the arc of a circle 3; since its radius R is determined by means of elements not shown in FIG. 1, it will be described further on in the description with reference to FIG. 2. In the non limiting example described, the active surface 2 comprises a height H equal to the thickness E of block 1, formed by the projection of the arc of a circle 3 and so of the active surface 2 on the reference direction A. Block 1 also comprises moving means 4, shown in a broken line frame on one of its sides 5. The following description of these means 4 concerns the visible part of the figure, since the piece is symmetrical and a non visible side of block 1, opposite side 5, comprises the same means. These moving means 4 comprise: on the one hand guide means such as rolling rollers 6, situated on an axis U parallel to axis Y--Y, for cooperating with a path of movement (not shown in FIG. 1); this cooperation allowing the first limiting block 1 to move along the first axis Y--Y. the moving means 4 further comprise securing means such as a stud 7 or 8 for securing block 1 to drive means (not shown), in a way which will be explained further on in the description. FIG. 2 shows schematically the first limiting block 1 of the invention, associated with a second block 1A identical to the first one, these two blocks 1,1A forming a first limiting assembly 20 associated with a radiation source 10. Source 10 generates a radiation beam in the reference direction A; this beam is delimited by a pre-collimator 11, 11A which defines for this beam a first limit X and a second limit X'. These first and second limits X,X' present, with respect to the reference direction A, an angle .alpha., .alpha.' forming a first and a second maximum half angle of opening of the beam, the sum of these angles .alpha., .alpha.' forming the full opening angle .alpha.1. The beam finds in its path the first and second blocks 1,1A, situated at positions P2,P2', on each side of the reference direction A, along the same first axis Y--Y. These blocks 1,1A may be moved manually or by motor means parallel to axis Y--Y, which in the non limiting example described allows them: for block 1 to occupy N positions between positions P1,PN, PA1 and for block 1A, to occupy N' positions P1' to PN'. This symmetry of the positions of blocks 1,1A is shown by way of non limiting example, their positions being possibly assymetrical depending on the way in which their respective moving means 4,4A are associated with drive means (not shown). In the non limiting example described, this travel of the limiting blocks 1,1A allows them to limit a first and a second part of the beam; the first part, limited by block 1, being located between the first limit X and the straight reference line A, corresponds to the first maximum half angle of opening .alpha.. The second part of the beam, limited by the second block 9, being located between the second limit X' and the straight reference line A, corresponds to the second maximum half angle of opening .alpha.'. The first block 1 is thus capable of limiting this first part of the beam, by defining therefor new limits A,B, . . . X, depending on its position P1,P2, . . . PN, between the reference direction A and the first limit X; the second block 9 is able to limit the second part of the beam, by defining therefor new second limits A, B', . . . X', depending on its position P1',P2', . . . PN, between the reference direction A and the second limit X'. These new limits are determined by the active surfaces 2,2A which, in the position occupied by the first and second blocks 1,1A in FIG. 2, define for the beam a first and a second new limit B,B'. These limits B,B', since they have source 1 as origin, are tangential to the cylindrical active surfaces 2,2A, at contact points 12, 13 situated on these active surfaces 2,2A. This tangential condition, which allows the beam to be limited with a maximum accuracy and a minimum penumbra, is maintained for all the limits A, B, . . . X and A,B', . . . X', because of a starting orientation of the active surfaces 2,2A. It should be noted that, when blocks 1,6 occupy respectively the positions P1,P1', the beam is completely closed. By taking as example the first limiting block 1, this example being also valid for the second limiting block 1A which has the same combination of means; the orientation of the active surface 2 is determined by the position of the center O of the arc of a circle 3; this arc of a circle 3, shown in FIG. 1, merging in FIG. 2 with the active face 2. As has already been explained this center O is situated on an axis V--V passing through one end 17 of the arc of a circle 3; this end 17 being that one of the ends 17,19 the closest to source 10. Radius R is determined, on the one hand with respect to the maximum half angle of opening .alpha. of the beam and, on the other hand, by the height H of the active surface 2; this height H being generally imposed by conditions relative to the nature of the radiation beam and the absorption thereof. Thus, this radius R in a limiting block 1 in accordance with the invention is determined by the following relationship: EQU R=H/sin.alpha.; in which R is the radius of the arc of a circle 3, H is the height of the active surface 2, .alpha. is the value of the maximum half angle of opening. This definition of the position of center O defines an orientation of the active surface 2 such that: (a) with the first block 1 in the endmost position P1, the limit formed by the reference direction A is tangential to the active surface 2 at the endmost point 17, (b) with the first block 1 in the endmost position PN, the limit formed by the first limit X is tangential to the active surface 2 at the other endmost point 19; all the new limits A,B, . . . X being tangential to this active surface 2 at points located between these endmost points 17,19, as is shown in FIG. 2, where the new limit B is tangential to the active surface at point 12. Such an arrangement is particularly advantageous in that it allows a part of a beam to be limited within desired limits A,B, . . . X by the rectilinear movement of the limiting block 1 of the invention without modifying the starting orientation of the active surface 2 as a function of the position P1,P2, . . . PN which block 1 may occupy. This arrangement is remarkable in that it allows the beam to be limited while retaining a minimum penumbra, whatever the positions P1, PN and P1',PN' occupied by blocks 1,6 may be; this penumbra never being greater than that obtained by devices of the prior art, which require a highly accurate orientation of their active surface, depending on the position which they occupy. Thus, in the non limiting example described, each of the limiting blocks 1,1A limits a part of the beam such as represented by the first maximum half angle of opening .alpha., for the first limiting block 1, and by the second maximum half angle of opening .alpha.' for the second block 1A. It is also possible for one of these blocks 1,1A to comprise a different starting orientation of its active surface 2,2A, depending on a different value of the first or of the second maximum half angle of opening .alpha., .alpha.'; this allowing a useful beam, off-centered (not shown) with respect to the reference direction A, to be defined on the first axis Y--Y. FIG. 3 shows a collimator 30 in accordance with the invention comprising on the first longitudinal axis Y--Y the first and the second limiting blocks 1,1A forming a first limiting assembly 20, such as already shown in FIG. 2; this collimator 30 comprising on a second axis Z--Z perpendicular to the first one a third and a fourth limiting block 1C, 1D, in accordance with the invention, these third and fourth blocks 1C,1D forming a second limiting assembly 20A identical to the first one. These first and second limiting assemblies 20,20A are centered on the straight line A, defined above, and representing the reference direction of the beam. The first limiting assembly 20 is associated with a rectilinear path of movement formed in the non limiting example of the description by rails 25,26 secured together at each end by a first and a second plate 27,28. The rolling means for the first and second blocks 1,1A formed by rollers 6 roll on these rails 25,26 disposed parallel to the first axis Y--Y. These blocks 1,1A are driven by drive means which are simplified because of the rectilinear movement of these blocks 1,1A; in the non limiting example described, these drive means comprise a motor 31 whose rotation, in one direction or in the other, is transmitted through a shaft 32 to a first pulley 33; this latter is fixed to rail 25 by a bracket 34 and a conventional rolling means, not shown. Rotation of the first pulley 33 is in the direction shown by arrow 38, in a plane parallel to that of sides 5,5A of the first and second blocks 1,1A. This rotation causes the movement of a chain or, as in the example described, a notched belt 35 passing round a return pulley 36; this defines for belt 35 an upper part 41 and a lower part 42 which are parallel and which have opposite directions of movement. This property is used for causing the movement of the first and second blocks 1,1A in a direction opposite to each other. For this purpose, the first block 1 is firmly secured to the upper part 41 of belt 35 by a stud 7 which is situated in the vicinity thereof; the second block 9 being firmly secured to the lower part 42 by stud 8. Setting motor 31 in rotation causes a movement of block 1 in the direction of arrow 43 when block 1A is moved in the direction of arrow 44, and vice versa. This allows a symmetrical travelling movement of the two blocks 1,1A, the symmetry being adjustable by positioning the attachment between studs 7,8 and belt 35. Motor 31 may also control on rail 26 side a similar combination of drive means (not shown) as the one which has just been described. A different arrangement, comprising for example for each limiting block 1,1A, a motor (not shown) allowing these blocks to be driven independently by motor in a simplified way because of the rectilinear movements of these blocks 1,1A is also possible. The previously described motorization of the limiting assembly 20 is also valid for the limiting assembly 20A, whose third and fourth blocks 1C,1D are movable parallel to the axis Z--Z on rails 25A,26A; these blocks 1C,1D using a a similar combination of drive means (not shown) as that of limiting assembly 20. With a collimator 30 in accordance with the invention, while being particularly space-saving, a useful beam may be delimited with a minimum penumbra and a maximum of accuracy. This saving of space is due to the simplification of the mechanical and drive means, since the movements of blocks 1, 1A and 1C,1D are rectilinear; this being made possible by the fact that these blocks comprise an active surface 2,2A,2C, 2D which does not require new orientations for each new position that these blocks occupy.