FR2706628A1 - Device for locating radiation sources, using variable-collimation detection means - Google Patents

Abstract

This device also comprises means (8) for adjusting the collimation, a camera (10) providing an image of the region, means (12) for making the imaging axis of the camera coincide with the axis of the detection solid angle, and means (16) for forming an image of the region, centred on the imaging axis, and a circle (C) superposed on this image, centred on this axis and corresponding to the intersection of the detection solid angle with the plane of the observed scene, and for forming an indication regarding the intensity of the radiation detected in this solid angle.

Description

DEVICE FOR LOCATING RADIATION SOURCES,
USING COLLIMATION DETECTION MEANS
VARIABLE
DESCRIPTION
The present invention relates to a device for locating radiation sources.

 It particularly applies to the location of sources of radiation y.

 A technique for locating radiation sources is already known.

 According to this known technique, a counter is moved, manually or by means of a remote manipulator, which is capable of measuring this radiation.

 However, this known technique has the drawback of being relatively imprecise in locating sources.

 The object of the present invention is to remedy this drawback by proposing a much more precise location device.

The subject of the present invention is a device for locating sources of radiation, which may be located in an area, this device being characterized in that it comprises - means for detecting radiation, using collimation
variable, able to supply, in the form of a signal
information on the intensity of the
radiation detected in a solid angle of
detection, which is a function of the collimation, - means of adjusting the collimation, suitable for
vary this solid detection angle, - a camera capable of providing an image of the area under
form of an electrical signal, - optical means provided to make the axis coincide
camera shooting and angle axis
solid detection, and - electronic means for processing and
visualization, planned on the one hand to form, in
function of an information on the angle value
solid detection and signals provided by the
camera and detection means, an image of the
area, which is centered on 1V shooting axis, and
a circle which is superimposed on this image, which is
centered on this axis and which corresponds to the intersection
of the solid detection angle T with the plane of the
scene observed with the camera (i.e. the shot
perpendicular to the shooting axis and containing
the intersection of this axis with the surface of ltobj
targeted by the device), and secondly to provide
an indication of the intensity of the detected radiation
in this solid angle.

 According to a particular embodiment of the device which is the subject of the invention, the means for adjusting the collimation are provided to supply, to the electronic processing and display means, information on the value of the solid detection angle.

 Preferably, the device which is the subject of the invention further comprises a range finder, the optical means are provided to make the measurement range of the range finder coincide with the axis of view of the camera, the range finder being capable of providing the information distance between the device and the plane of the scene observed, and the electronic processing and display means are further able to supply, as a function of this distance information, the dose rate at any point on the axis of taking of view and the area delimited by the circle which is located in the plane of the observed scene and which is displayed.

Preferably, the detection means comprise - a body which has a longitudinal bore and which
is made of a material capable of strongly attenuating the
radiation, - a radiation detector, which is placed in this
longitudinal drilling, to detect radiation
which arrives at it by one end of the bore, and - means of displacement of this following detector
the axis of this drilling.

 Due to their design, such detection means are likely to have a small footprint and a low weight.

In a particular embodiment, preferred for its simplicity, the displacement means comprise - a threaded rod which is movable in translation in
longitudinal drilling along the axis thereof,
but locked in rotation, and whose end located
on the side of said end of the longitudinal bore
is secured to the detector, and - a nut which is secured to the body as regards
concerns translations parallel to the axis of
this one, but free to rotate around this axis and
which is placed on the side of the other end of the hole
and screwed onto the other end of the threaded rod.

 The detection means can include a y-radiation detector (when it is desired to locate sources of y-radiation).

In this case, we choose to make the body in question above a material which is capable of strongly attenuating the radiation Y
The invention could also apply to the detection of other radiation such as for example ss radiation (by providing of course suitable detection means).

The present invention will be better understood on reading the description of an exemplary embodiment given below, by way of purely indicative and in no way limiting, with reference to the appended drawings in which
- Figure 1 is a schematic view of a mode of
particular realization of the device object of
the invention, and
- Figure 2 is a schematic view of a mode of
particular realization of detection means to
variable collimation which are usable in the
device shown in Figure 1.

The device according to the invention, which is schematically shown in Figure 1, is for example intended to locate sources of radiation
Y who are likely to be in an area such as a local.

This device of FIG. 1 comprises - means 4 for detecting the radiation,
variable collimation, which are able to provide, under
form of an electrical signal, information about
the intensity of the radiation detected in an angle
detection solid 6 whose value is a function of
collimation, - means 8 for adjusting this collimation, which
are able to vary this solid angle by
detection 6, - a video camera 10 which is capable of providing an image
of the area in the form of an electrical signal, - optical means 12 which are provided to make
coincide with the camera's shooting axis (which is
the axis of the solid angle of the field of view 14
associated with this camera), with the X axis of the angle
solid detection 6, and - electronic processing means 16 which are
planned, in association with means of
display 18, on the one hand to form, depending
information on the value of the solid angle of
detection and signals provided by the camera and
detection means 4, an image of the area, which is
centered on the X axis, and a circle C which is superimposed
to this image, which is centered on this X axis and which
corresponds to the intersection S of the solid angle of
detection 6 with the plane P of the scene observed with
camera 10, and secondly to provide a
indication I on the intensity of the detected radiation
in this solid angle 6.

The plane P is the plane which is perpendicular to the X axis and which contains the intersection of this X axis with the surface of an object 2 aimed by the camera (intersection closest to the camera)
In the example shown in FIG. 1, the collimation adjustment means 8 are provided to supply the electronic processing means 16 with information on the value of the solid detection angle 6.

 The device schematically shown in FIG. 1 also includes a rangefinder 20, the optical means 12 are provided to make the measurement axis of the rangefinder coincide with the X axis and this rangefinder is capable of providing information relating to the distance from the plane P to the device, according to the measurement axis.

 In addition, the electronic processing means 16 are provided to supply, as a function of this distance information obtained by means of this rangefinder 20, the dose rate at any point of the axis X and the surface S of intersection.

 In this case, the display means 16 which consist, for example of a video monitor, display the distance of the device with observed object 2, the value of the surface S of intersection of the solid detection angle 6 and of the object plane P, and the dose rate measured.

 The rangefinder 20 which, in the example shown, is a laser rangefinder, n V is not essential if one only wishes to locate the sources of radiation but it is used if one wants to quantify this radiation (that is to say know the dose rate at different distances from an observed source, located on the X axis).

 The optical means 12 comprise two mirrors 22 and 24 parallel to each other and inclined at 45 "on the axis X, as seen in FIG. 1.

 The mirror 22 is opposite the variable collimation detection means 4 and it is for example produced using a glass of thin thickness to be as transparent as possible to the y radiation.

 The mirror 24 is opposite the lens of the camera 10.

 Thus, the light coming from the observed room is reflected first on the mirror 22 then on the mirror 24 before reaching the camera 10.

 In the case where the laser range finder 20 is used, the mirror 24 is a semi-transparent mirror, to let part of the laser beam F coming from the range finder pass this part then being reflected by the mirror 22 in the direction of the objects observed.

 The laser beam then returns to the range finder 20 by the reverse path, reflecting on the mirror 22 and partly passing through the semi-transparent mirror 24.

 The variable collimation detection means 4, the collimation adjustment means 8, the video camera 10, the laser rangefinder 20 and the mirrors 22 and 24 are mounted on the same support 26, as seen in FIG. 1.

 A particular embodiment of the detection means 4 is schematically represented in longitudinal section in FIG. 2.

The detection means 4, which are schematically represented in FIG. 2, comprise - a cylindrical body 28 whose axis is the X axis, which
has a longitudinal hole and is made of a
material capable of strongly attenuating Yr radiation
this body 28 forming a collimator, a dosimetric detector of radiation y, with a diode
semiconductor, referenced 30, which is placed in this
longitudinal drilling and which is intended to detect the
Y radiation (referenced 32) which reaches it by a
end of this bore, and - a threaded rod 34 which forms an endless screw and which
cooperates with a grooved nut 36 to move the
detector 30 in this hole, along the X axis, as
we will see it later.

 As seen in Figure 2, the detector 30 is mounted at one end of a rod 38 which extends along the axis X and which is hollow to allow the passage of son of electrical conductors for connection of the detector (not shown) and the other end of this rod 38 is fixed to the threaded rod 34 whose diameter is greater than that of the rod 38.

 Of course, these conductors are electrically isolated from each other and from the other components of the detection means 4.

 The longitudinal bore of the body 28 comprises a first part referenced 40 whose diameter is slightly greater than that of the rod 38, in order to receive the latter, and a second part 42, whose diameter is greater than that of the part 40, and which is designed to receive the threaded rod 34.

 It can be seen in FIG. 2 that a part of the threaded rod 34 protrudes from the end of the body 28 opposite to that by which the Y radiation is detected.

 The nut 36 is screwed, inside the body 28, onto this part of the threaded rod 34.

 This nut 36 is made integral with the body 28, as regards the translations parallel to the axis X, but free in rotation around this axis X, by means of a flange 36a fixed to nut 36 and by means of a ring 36b which is fixed to the body 28 and which retains the collar 36b, as seen in FIG. 2.

 In addition, the rod 34 has a longitudinal groove 34a parallel to the axis X and the body 28 is provided with a stud 34b which is inserted in this groove 34a to immobilize the rod 34 in rotation (while this rod is movable in translation in the longitudinal bore of the body 28).

 Thus, the nut 36 allows, when it is rotated, to move the worm, and therefore to move the detector 30 in the part 40 of the longitudinal bore.

 In this way, it is possible to vary the solid detection angle (solid angle for measuring the radiation y) between a few millistadians and 2 X steradians.

 It is specified that the threaded rod 34 is hollow to allow the passage of the connection conductors of the detector 30 and we see in FIG. 2 these connection conductors 44 which emerge from the threaded rod 34, on the nut side 36, and which are placed in a protective envelope 46.

 The constituent material of the body 28 is for example a metal of high density, at least equal to 10, such as a suitable alloy based on lead or a suitable alloy based on tungsten, such as the alloy known as Denal .

 As a purely indicative and in no way limitative, the detector 30 has a detection surface of the order of 1 mm 2, the rod 38 has a diameter between 1 and 2 mm, the body 28 has a diameter between 1 and 3 cm and a length of between 7 and 15 cm, the weight of all of the detection means 4 being of the order of 1.5 kg.

 We thus obtain means 4 of low weight and small footprint while maintaining good sensitivity and good measurement dynamics.

 The detector 30 can be provided with a screen 48, for example made of tungsten, gold or copper, to reduce the sensitivity of this detector to low energy Y rays and to X rays.

 In the example shown, this screen 48 is fixed to the detector 30, on the entry face of the radiation in this detector 30.

 FIG. 1 shows means 50 intended for the preamplification of the signal supplied by the detector 30.

 The means (not shown) intended for processing the signal thus preamplified in order to measure the radiation, are incorporated into the electronic processing means 16.

 The means 8 for adjusting the collimation, that is to say the solid detection angle, or solid measurement angle, comprise a motor 52, for example a stepping motor, and a toothed belt 54 thanks to which the motor 52 rotates the nut 36 which is toothed as seen in FIG. 2, the toothed belt 54 cooperating with this toothed nut 36.

 The stepping motor 52 supplies the electronic processing means 16 with a signal which is characteristic of the collimation adjustment carried out, and therefore of the value of the solid detection angle (which the means 16 need to define and display S).

 In addition, these electronic processing means 16 comprise means (not shown) of acquisition (digitization and storage) of the signals supplied by the video camera 10 and also receive the signals coming from the laser range finder 20.

With all these data (value of the solid detection angle), intensity of the radiation y, observed image of the area, distance from 1 object 2 to the device), the electronic processing means 16 restore, on the video monitor 18, a visible image of the zone where the circle C is inscribed which is the image of S, that is to say of the periphery of the solid angle of measurement on the object plane P (visible scene plane)
The dose rate, at a chosen point on the X axis, induced by the area inside this circle C and which is measured using the dosimeter 30, is also recorded on the video monitor 18.

 All the means mounted on the support 26 can be made compactly and can be adapted to any carrier means, in particular a manipulator arm.

 This device allows an operator to perform a mapping of the area observed by successive approaches, by playing on the collimation of the detection means and the positioning of the device.

 Indeed, if the collimation is varied, the diameter of the circle C formed on the video monitor 18 varies.

 If the quantity of radiation detected (represented by the dose rate) does not vary, this means that an irradiating object present in the observed area has a size smaller than that of the intersection disc S of the solid detection angle 6 and of the object plane P.

 If, on the contrary, the dose rate varies, this means that 1 the object and has a size greater than that of this disc or is not completely in this disc.

 The device which is the subject of the invention can also be used for video-dosimetric surveillance of an area or objects, on a nuclear site.

Claims (6)

 1. Device for locating sources of radiation, likely to be located in an area, this device being characterized in that it comprises - means (4) for detecting radiation,  variable collimation, able to provide, in the form  an electrical signal, information on  the intensity of the radiation detected in an angle  solid detection, which is a function of the  collimation, - means (8) for adjusting the collimation, suitable for  varying this solid detection angle, - a camera (10) capable of providing an image of the area  in the form of an electrical signal, - optical means (12) provided for making coincide  the camera shooting axis and the (X) axis of  the solid detection angle, and - electronic means (16, 18) for processing and  visualization, planned on the one hand to form, in  function of an information on the value of the angle  solid detection and signals provided by the  camera (10) and the detection means (4), an image  of the zone, which is centered on 1V taking axis  view, and a circle (C) which is superimposed on this  image, which is centered on this axis and which corresponds to  the intersection of Solid Angle Detection with the  shot (P) of the scene observed with the camera, and  on the other hand to provide an indication on  the intensity of the radiation detected in this angle  solid.  2. Device according to claim 1, characterized in that the collimation adjustment means (8) are provided to supply, to the electronic processing and display means (16), information on the value of the solid angle detection.  3. Device according to any one of claims 1 and 2, characterized in that it further comprises a rangefinder (20), in that the optical means (12) are provided to make the measurement axis of the rangefinder coincide with the axis of the camera, the rangefinder being able to provide the distance information between the device and the plane of the scene observed, and in that the electronic processing and display means (16) are furthermore able to supply, as a function of this distance information, the dose rate at any point of the shooting axis and the area delimited by the circle which is located in the plane of the scene observed and which is displayed.  4. Device according to any one of claims 1 to 3, characterized in that the detection means (4) comprise - a body (28) which has a longitudinal bore and  which is made of a material capable of strongly attenuating  radiation, - a radiation detector (30), which is placed in  this longitudinal drilling, to detect radiation  which arrives at it by one end of the bore, and - means (34, 36) for moving this detector  along the axis of this hole.  5. Device according to claim 4, characterized in that the displacement means comprise - a threaded rod (34) which is movable in translation  in the longitudinal drilling along 1V axis from that  Ci, but locked in rotation, and whose end  located on the side of said end of the bore  longitudinal is made integral with the detector, and - a nut (36) which is made integral with the body (28)  with regard to translations parallel to  ltax of it, but free in rotation around  this axis and which is placed on the side of the other end  drilling and screwed on the other end of the rod  threaded (34).  6. Device according to any one of claims 1 to 5, characterized in that the detection means (4) comprise a detector (30) of radiation there.