FR2706626A1 - Remote location device for radiation sources. - Google Patents

Abstract

This device comprises a pinhole chamber (12), a radiophotoluminescent screen (34) facing the pinhole, a latent image of the sources forming on this screen, a camera (37) supplying, in the form of electrical signals, an image of the zone, optical means (38) allowing the camera and the screen to observe the same scene, means (42) for reading the screen providing, in the form of electrical signals, an image of the sources from the latent image and electronic means (44, 46) for processing and displaying signals, for superimposing and visualizing the images of the zone and of the sources.

Description

DEVICE FOR REMOTE LOCATION OF SOURCES OF
RADIATION
DESCRIPTION
The present invention relates to a device for locating remote sources of radiation, more particularly sources of y radiation.

 It applies in particular to the location of radiation sources likely to be contained in a room such as a high activity cell, for example, or accidentally present in a room.

We already know by the document (1)
FR-A-2 575 821 (see also EP-A-0188973 and US-A4 797 701) to which reference will be made, a device for remote location of radiation sources.

 This known device uses, for the location of sources of radiation, a pinhole chamber in which are placed a film sensitive to radiation and a film sensitive to visible light from the area in which the sources of radiation are likely to be located.

 The shutter, the opening of which allows shooting in visible light, is transparent to radiation from sources.

 After developing these films and superimposing them, we can locate the sources of radiation in their environment.

 This known device has the drawback of requiring relatively long exposure times.

 The object of the present invention is to remedy the preceding drawback by proposing a device for localizing remote sources of radiation, which requires significantly lower exposure times than the known device, disclosed in the document (1).

Specifically, the subject of the present invention is a device for remote location of sources of radiation, likely to be located in an area, this device comprising a pinhole chamber whose walls form a shield against radiation from sources, this pinhole chamber having an opening, this device being characterized in that it further comprises
- a radiophotoluminescent screen, which is sensitive to the radiation emitted by the sources and placed in the pinhole chamber, facing the pinhole camera, the opening allowing the introduction of this screen a latent image of the sources forming on this screen,
- a camera capable of providing, in the form of electrical signals, an image of the area,
- optical means allowing the camera and the screen to observe the same scene,
means for reading the screen capable of providing, in the form of electrical signals, an image of the sources from the latent image, and
- Electronic means for processing and viewing the electrical signals supplied by the camera and by the screen reading means, these electronic processing and viewing means allowing the superimposition and viewing of images of the area and of the sources.

The use of a radiophotoluminescent screen, also called photostimulable screen, has the following advantages over conventional films
- it allows a very significant gain in sensitivity,
- it has a very large dynamic,
- it is insensitive to visible light,
- it has better linearity than these classic films, and,
- it is reusable.

Therefore, the device object of the present invention has the following advantages over the known device, mentioned above
the device which is the subject of the invention requires exposure times that are significantly lower than those required by this first known device,
- it allows better quantification of the sources of radiation y,
- it does not require the use of a dark room (photographic laboratory), and
- It allows a faster shot acquisition than that allowed by this first known device.

 According to a preferred embodiment of the device which is the subject of the invention, said pinhole chamber further comprises a plug constituting a shielding for radiation and serving to close said opening during operation of the device.

 According to a particular embodiment of the device which is the subject of the invention, the pinhole chamber comprises a collimator delimited by a wall in the form of a cone, the narrowest part of which constitutes the pinhole.

 According to another particular embodiment, the pinhole chamber comprises a collimator delimited by a wall in the form of a double cone formed by two cones of the same opening, opposite by the apex, the latter constituting the pinhole.

 Preferably, the optical means comprise a reflex sighting system.

 The present invention will be better understood on reading the description of an embodiment given below, purely by way of indication and in no way limiting, with reference to the single appended figure.

 The device according to the invention, which is schematically represented in this figure, is for example intended to locate sources 2 of radiation y which are likely to be located in an area such as a room.

 This device comprises a body 4 which is provided with means bearing the reference 6 in the figure and symbolizing an orientable support of the body 4 and therefore of the device.

 The body 4 comprises a front face 8 intended to be placed facing the sources to be identified and an opposite face 10 called the rear face.

 The device schematically shown in the figure also comprises a pinhole chamber 12, formed in the body 4 which constitutes a shielding of the chamber 12 against the y radiation.

 This body 4 can be made of a suitable alloy based on tungsten, such as the alloy known as VVDenalVV.

 The high density of this alloy gives it good radiation attenuation power.

 The use of this material thus makes it possible to reduce the thickness of the shielding and, consequently, the size of the device and its weight.

 The pinhole chamber includes a collimator 14.

 The latter is delimited by a first circular cone 16 whose base is located on the front face 8.

 The collimator 14 is centered on the axis 18 of the body 4 and the top of the cone 16 is pierced to form the pinhole 20.

 Behind this pinhole 20, a second circular cone 22 is provided with an opening angle equal to that of the cone 16.

 This second cone 22 opens at its widest part into a circular chamber 24 which is centered, like the cone 22, on the axis 18.

 This chamber 24 extends to the rear face 10 through a cylindrical opening 26.

 This opening 26 is normally closed by a cylindrical plug 28.

 A handle 30 and blocking means 32 allow this plug 28 to be pushed in and then blocked.

 The device is loaded by placing in the chamber 24 a photostimulable screen 34 which is sensitive to the radiation y from the sources 2.

This photostimulable screen is, for example, of the type sold by the Company.
Molecular Dynamics under the reference MD17-991.

 A spring 36 which is fixed on the inner face of the plug 28 enables said screen (which is arranged perpendicular to the axis 18) to be pressed against a shoulder formed in the chamber 24.

 The thickness of the plug 28 is such that, like the body 4, it constitutes a shield against the radiation from the sources 2.

 The device schematically shown in the figure also includes a video camera 37 which is made integral with the body 4 by means not shown.

 This device further comprises a reflex optical sighting system which allows the camera 37 to film the same scene as that which is seen by the screen 34 through the pinhole 20.

 This aiming system is for example a mirror 38 which is made integral with the body 4 by means not shown, which is placed in front of the collimator 14 and which does little attenuation of the radiation there.

The device schematically shown in the figure also includes
means 40 for acquiring (digitizing and storing) the electrical signals supplied by the video camera 37 when the latter observes the area containing the radiation sources 2,
means 42 for reading and conversion which are provided for reading the latent image formed on the screen 34 due to these radiation sources 2, for converting this latent image into digital signals and for storing these digital signals,
electronic means 44 for processing the digital signals stored in the means 40 and 42, these means 44 being able to superimpose the digitized image of the sources, which is formed on the screen 34, and the digitized image of the area containing these sources, which was filmed by camera 37, and
- Means 46 for viewing these superimposed images (video monitor or printer for example), which make it possible to identify the position of the sources in the area.

 It is specified that the video camera 37 and the pinhole camera 20 are adapted so that the digital images which correspond to them respectively have the same magnification and this, taking into account the means 42 for reading the screen 34, the acquisition means 40 and processing means 44.

The device schematically shown in the figure is used in the manner indicated below
After having chosen the area to be studied, the screen 34 is placed in the chamber 24 intended to receive it, the area is filmed with the video camera 37 and this image is digitized and stored in the means 40.

 During this time, the radiation sources generate there, on the photostimulable screen 34, a latent image in the form of spots which are more or less contrasted according to the activity of the corresponding sources.

 Then, the photostimulable screen 34 is extracted from the pinhole chamber and read using the means 42 and the latent image is digitized and stored in these means 42.

 Then, in the electronic processing means 44, the digitized image of the area and the latent image thus digitized are superimposed in order to highlight the location of each source 2 of radiation y and this location is displayed thanks to the means 46.

 It is specified that the plug 28 is not strictly essential in the case where the user of the device is certain that no radiation coming from the rear risks impressing the photostimulable screen 34.

 The device which is the subject of the invention applies in particular to the mapping of contaminated areas and, to do this, can be placed on a carrying means.

Claims (5)

 1. Device for localizing remote sources of radiation (2), likely to be located in an area, this device comprising a pinhole chamber (12) whose walls form a shield against radiation from sources, this pinhole chamber having an opening (26), this device being characterized in that it further comprises  - a radiophotoluminescent screen (34), which is sensitive to the radiation emitted by the sources and arranged in the pinhole chamber, facing the pinhole (20), the opening allowing the introduction of this screen, a latent image of the sources is forming on this screen,  - a camera (37) capable of providing, in the form of electrical signals, an image of the area,  - optical means (38) allowing the camera and the screen to observe the same scene,  means (42) for reading the screen capable of supplying, in the form of electrical signals, an image of the sources from the latent image, and  - electronic means (44, 46) for processing and viewing the electrical signals supplied by the camera and by the screen reading means, these electronic processing and viewing means allowing the superimposition and viewing of the images of the area and sources.  2. Device according to claim 1, characterized in that said pinhole chamber (12) further comprises a plug (28) constituting a shielding for radiation and used to close said opening (26) during operation of the device.  3. Device according to any one of claims 1 and 2, characterized in that the pinhole chamber (12) comprises a collimator delimited by a cone-shaped wall the narrowest part of which constitutes the pinhole.  4. Device according to any one of claims 1 and 2, characterized in that the pinhole chamber (12) comprises a collimator (14) delimited by a wall in the form of a double cone formed by two cones (16, 22) of same opening, opposite by the top, the latter constituting the pinhole.  5. Device according to any one of claims 1 to 4, characterized in that the optical means comprise a reflex sighting system (38).