JPH0943359A - Radiation distribution measuring device - Google Patents

Abstract

(57) 【Abstract】 PROBLEM TO BE SOLVED: To perform reconstruction accurately in real time, a method of easily inputting the distance between a detector and a radiation source to a computer or a method of performing reconstruction without inputting the distance, and an object. There is provided a method for accurately and easily superimposing the image on the image. SOLUTION: An aperture 3 having a large number of pinholes 2 formed in a shielding plate made of a material that shields radiation, and a two-dimensional position detection type radiation detector 4 for detecting radiation transmitted through the pinholes of the aperture 3. A pipe having a radiation source 9 and provided with reconstructing means 5 and 6 for performing signal counting of the radiation detector 4 and reconstruction processing of the distribution based on the counted value, and a display device 7 for displaying the result of the distribution. Radiation distribution is measured by measuring objects, equipment, walls and other structures. A non-contact distance meter 20 for measuring the distance between the measurement object 9 and the radiation detector 4, and a means 2 for inputting a distance value obtained by the distance meter 20 to a computer online.
And 1. The radiation distribution is reconstructed based on the distance value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation distribution measuring apparatus, and more particularly to a radiation distribution measuring apparatus for visualizing a spatial distribution of radioactivity and a dose distribution on the surface of a pipe or the like from information of radiation input to a detector. .

[0002]

2. Description of the Related Art FIG. 11 shows an example of the configuration of a conventional radiation distribution measuring apparatus using a pinhole system.

The radiation distribution measuring apparatus 1 transmits through the aperture 3 and a large number of pinholes 2 formed in a shielding plate made of a radiation shielding material (eg, lead, tungsten, etc.). A two-dimensional position detection type radiation detector 4 that detects radiation, a measuring device 5 that counts a signal having a determined peak value among the signal pulses of this radiation detector 4, and a distribution reconstruction process based on the count value. And a display device 7 for displaying the result of the obtained distribution.

The radiation detector 4 comprises a large number of minute detectors 4a.
Is arranged two-dimensionally, and position information is obtained based on which microdetector 4a generated a signal. In FIG. 11, reference numeral 8 is an object to be measured such as piping, and 9 is a radiation source such as a leaking radioactive substance.

12A and 12B show a method of measuring the radiation emitted from the radiation source 9. In addition,
The description is one-dimensional for simplification, and the case where the number of pinholes 2 is 2 and the radiation sources 9 are distributed in one spot is considered.

In FIG. 12A, the axis connecting the radiation source 9, the aperture 3 and the radiation detector 4 is the Z axis, and Z =
The radiation source 9 is distributed at the position of 0 (point A), the aperture 3 is arranged at the position of Z = Z ₁ (X ′ axis), and the radiation detector 4 is arranged at the position of Z = 2Z ₁ (X ″ axis). consider the case where placed. pinhole 2 is assumed to meet the _{X'-X '1, X'} 1 position (B, C point). radiation except locations spaced pinhole 2 is shielded It shall not transmit to the radiation detector side.
= -2X ' ₁ , 2X' ₁ The radiation enters the positions (points D and E), is detected by the micro-detector 4a there, and a pulse signal is generated. This pulse signal is counted by the measuring device.

Next, a method of reconfiguration in the reconfiguration computer 6 will be described. A planar light emitting source 10 that isotropically emits light is virtually arranged at the same position (Z = 2Z ₁ ) as the radiation detector.
The location of light emission can be arbitrarily determined.
The reconstruction aperture 12 is arranged in the same manner as the pinhole 2 of the aperture 3 and only the pinhole 12a portion transmits light.
Are virtually arranged apart from each other by the distance between the radiation detector 4 and the aperture 3 (that is, arranged at Z = 3Z ₁ (X ″ ′
Axis)). The pinhole 12a has X '''=-X' ₁ , X '.
_It is open at ₁ (points F and G). Further, the reconstruction surface 13 on which the light generated by the light emission source 10 forms an image is virtually arranged with a distance between the radiation detector 4 and the radiation source 9 (that is, arranged at Z = 4Z ₁ (X ″) '' Axis).

By reading out the measuring device, it is possible to know at which position of the position detector the radiation has passed through the aperture 3 (the positions of points D and E in the above example). The planar light emitting source emits light only at the positions where the radiation enters (points D and E).
The light at point D is the pinhole 12a of the reconstruction aperture 12.
The point I (X ″ ″ = 0) on the reconstruction surface after passing through (F and G points)
And image at point J (X ″ ″ = 4X ′ ₁ ). Similarly, the light at the point E is the pinhole 12a (F, F of the reconstruction aperture 12).
Passing point G), point H (X '''' =-4 on the reconstruction surface
X _'1) and point I (X''''= 0 ) to be imaged.

As a result of the above, individual light from the light emitting surface (lights at points D and E in the above example) is imaged at point I on the reconstruction surface.
The imaged position (X ″ ″ = 0) indicates the original distribution position (X = 0) of the radiation source 9, and the distribution can be obtained on a computer.

No matter where the original position of the radiation source 9 is in X (FIG. 12B shows an example when it is deviated from the origin of X), many radiations are distributed on the X axis. With the same method, the original position of the radiation source 9 can be accurately determined.
The images formed by J and H on the reconstruction surface become virtual images during reconstruction, but can be reduced by optimizing the pinhole arrangement (IEEE Trans. Nucl. Sci. NS-25 (1978) p184 etc.).

[0011]

In the conventional reconstruction of the radiation distribution measuring apparatus using the pinhole method, the reconstruction aperture is virtually arranged with the distance between the detector and the aperture, and the reconstruction surface is It is necessary to virtually arrange the detector and the radiation source at a distance. The distance between the detector and the aperture is determined at the time of designing the device and can be stored in advance in a computer.

However, it is necessary to dispose the reconstruction surface at a distance between the detector and the radiation source, and it is necessary to input it to the computer for each measurement.

Conventionally, measuring the distribution using this method has been mainly applied to the field of measuring the direction of the radiation coming from a star in space. In this case, the distance between the detector and the radiation source may be infinite and the reconstruction may be performed, and it is not necessary to determine the arrangement of the reconstruction surface each time. The following problems occur when the radiation distribution measuring apparatus is used to obtain the radiation distribution from the surfaces of piping and equipment in nuclear power plants and the like.

(1) Since the distance between the measuring object and the detector is different, it is necessary to measure the distance between the detector and the measuring object each time and input the measured distance information to the computer.
Therefore, even if the device is measured toward the object, the distribution state cannot be imaged unless the distance is measured separately. If the distance between the detector and the measurement target is matched with the distance input to the computer, the distribution can be reconstructed at the same time as the measurement, but the measurement target is limited.

(2) When the distribution of invisible leak points is measured as an object of measurement, the leak points cannot be specified, so that the distance cannot be accurately determined and reconstruction cannot be performed accurately.

(3) When measuring an object to be measured which has a plurality of different distances, the distance used for the reconstruction is limited to one of the objects to be reconstructed. The focus during reconstruction is out of alignment, and the distribution cannot be obtained at the same time.

(4) When the object has a depth, the radiation distribution also has a depth, and in this case, the distance of the measurement object cannot be specified. Therefore, the reconstruction can be performed only by limiting the distance used for the reconstruction to a part of the measurement object. In this case, the entire distribution cannot be obtained because the focus of the reconstruction is shifted except for the designated part of the object.

(5) When reconstructing, it is necessary to set the distance to the measurement object in some form. Further, in order to confirm to which position of the device or the pipe the obtained distribution of the radiation corresponds, it is necessary to superimpose and display the radiation distribution and the visible image of the device or the pipe. Therefore, it is necessary to use an image capturing device such as a CCD camera near the radiation distribution measuring device, which causes the following problems.

(6) CCD near the radiation distribution measuring device
Since the camera is placed, the angles of the images obtained by the radiation distribution measuring device and the CCD camera are different, which causes an error in superimposing. This is a particular problem when targeting nearby objects.

(7) In addition to the original radiation distribution measuring device, an image capturing device is required, and the entire device becomes large,
Increases costs.

The present invention has been made in view of the above circumstances, and relates to the reconstruction of a radiation distribution measuring apparatus using a pinhole system, in order to perform the reconstruction in real time and with high accuracy, the detector and the radiation source An object of the present invention is to provide a method for easily inputting a distance into a computer, a method for performing reconstruction without inputting a distance, and a method for accurately and easily superimposing an image on an object.

[0022]

In order to solve the above-mentioned problems in the reconstruction of a radiation distribution measuring apparatus using a pinhole system, a radiation distribution measuring apparatus of the present invention is provided between an object and a detector. It has a non-contact distance meter that measures the distance and a means that can input the value of the distance obtained by this distance meter online to the computer, and reconstruct the radiation distribution based on the value of the distance. It is the one.

In the radiation distribution measuring apparatus of the present invention,
A function to freely set the distance value used for reconstruction from the operation panel to minimize the blur of the reconstructed image, and a function to reconstruct the distribution based on the distance value and display the result. It is desirable to change the value of the distance from the operation panel so as to reduce the blur of the reconstructed image.

In the radiation distribution measuring apparatus of the present invention,
It is desirable to automatically determine the reconstruction distance so that the intensity of the reconstructed image of the distribution is maximized.

In the radiation distribution measuring apparatus of the present invention,
The distance between the shield and the radiation detector is changed, and the distance between the object to be measured and the radiation detector is calculated based on the similarity ratio of the pinhole pattern measured by the detector. It is desirable to reconstruct the distribution in and.

In the radiation distribution measuring apparatus of the present invention,
In order to simultaneously and accurately reconstruct the distribution of radiation from multiple measurement objects with different distances, set the distance to the detector for the required number of measurement objects, and also set the individual distance values that have been set. It is desirable to reconstruct the distributions in and and display the results in an overlapping manner.

In the radiation distribution measuring apparatus of the present invention,
In order to simultaneously and accurately reconstruct the distribution of radiation from a deep measurement object, the distance settings used during reconstruction are set by dividing the specified distance range by the specified number and setting Reconstruct based on the distance value of
It is desirable to display the results in a stack.

In the radiation distribution measuring apparatus of the present invention,
A two-dimensional light-emitting panel having the same shape as that of the two-dimensional position detection type radiation detector for reconstruction of the distribution is arranged at a distance that is the same as that of the radiation detector, and the radiation shielding plate or the radiation. A light shield plate that has the same shape as the shield plate and is thin is placed at the same distance as the radiation shield plate from the measurement object, and the light emitted from the light-emitting panel is transmitted through the pinhole to the measurement object. It is desirable to visualize the distribution of the radiation by projecting it on the.

In the radiation distribution measuring apparatus of the present invention,
It is desirable to arrange the two-dimensional light emitting panel on the radiation detector.

In the radiation distribution measuring apparatus of the present invention,
An optical reflection plate is placed on the axis that passes through a shield plate with many pinhole-shaped holes and a radiation detector, and the visible image reflected by the reflection plate is captured by an image camera, and the radiation obtained by the radiation distribution measurement device is measured. It is desirable to display it over the distribution of.

In the radiation distribution measuring apparatus of the present invention,
The radiation detector is a two-dimensional image sensor that is also sensitive to visible light. Of the many pinholes made in the shield plate, one hole is left and the other hole is shielded, and the shield plate and the radiation detector are shielded. It is housed in a container that can be opened and closed, and a window that can be opened and closed is prepared on the front of the container. A visible image obtained by the detector through one pinhole when the window is opened and a reconstructed image when the window is closed are obtained. It is desirable to superimpose and display the radiation distribution.

[0032]

BEST MODE FOR CARRYING OUT THE INVENTION As shown in FIGS. 1 to 10, a radiation distribution measuring apparatus according to the present invention is implemented in the following modes. 1 to 10, the same members as those in the conventional example will be described using the same reference numerals as those shown in FIGS. 11 and 12.

FIG. 1 shows a first embodiment. This radiation distribution measuring device 1 is used for measuring objects 8 such as pipes and equipment.
Which visualizes the distribution of the radiation emitted from the radiation source 9 in the inside, and a non-contact type range finder 20 for measuring the distance between the measurement object 8 and the position detector 4, and the indicated value of the range finder 20 again. An interface circuit 21 for inputting to the configuration computer 6 is provided.

Also in this embodiment, as in the case of the conventional example described above, an aperture 3 having a large number of pinholes 2 formed in a shield plate made of a radiation shielding material (such as lead or tungsten), and a pinhole. A two-dimensional position detection type radiation detector 4 for detecting the radiation passing through 2, a measuring device 5 for counting a signal of a determined crest value among the signal pulses of this radiation detector 4, and a distribution from the count value. And a display device 7 for displaying the result of the obtained distribution.

The radiation detector 4 comprises a large number of minute detectors 4a.
Is arranged two-dimensionally, and position information is obtained based on which microdetector 4a generated a signal.

In the radiation distribution measuring apparatus having such a configuration, the direction of the range finder 20 is made to coincide with the direction of the radiation detector 4, and it is installed on the same pedestal (not shown) as the radiation detector 4. With this, when the direction of the radiation detector 4 is changed,
The direction of the rangefinder 20 also changes at the same angle.

The distance between the object 8 to be measured and the radiation detector 4 and the distance between the object 8 to be measured and the distance meter 20 are set to be the same. At the same time as measuring the radiation by directing the radiation detector 4 toward the measurement object 8, the rangefinder 20
Is used to measure the distance to the measurement object 8. In addition,
The range finder 20 may be of any type as long as it is a non-contact type.

The distance measured by the distance meter 20 is read by the interface circuit 21. The reconstruction computer 6 reads the data from the measuring device 5 in a timely manner. Then, the radiation distribution is reconstructed based on the distance measured by the distance meter 20, and the radiation distribution state is visualized and displayed on the display device 7.

According to the radiation distribution measuring apparatus of the first embodiment described above, the distance from the object to be measured 8 is measured by the distance meter 20, and the reconstruction computer 6 automatically reads the distance, and the distance at the time of reconstruction is measured. It is possible to save the operator the trouble of measuring each time. Also, by automatically taking in the distance, the reconstruction can be performed simultaneously with the measurement of the distribution.

FIG. 2 shows a second embodiment of the radiation distribution measuring apparatus according to the present invention. This radiation distribution measuring device also visualizes the distribution of radioactivity leaking from pipes and the like.

This radiation distribution measuring apparatus is provided with an operation panel 22 for setting information on the distance used at the time of reconstruction, and an interface circuit 21 for inputting the state of this operation panel 22 to the reconstruction computer 6. Operation panel 2
Reference numeral 2 is composed of, for example, a variable resistor having a variable resistance value and a knob for varying the resistance value. The reconstruction computer 6 uses the interface circuit 21 to read the resistance value.

Since the other structure is similar to that of the first embodiment, the corresponding parts in FIG. 2 are designated by the same reference numerals as those in FIG. 1 and their explanations are omitted.

In the radiation distribution measuring apparatus shown in FIG. 2, the radiation detector 4 is directed to a location where the radiation is considered to leak from the piping and the measuring apparatus 5 measures the radiation.

At the same time, the resistance value is read from the operation panel 22 by the interface circuit 21. The resistance value and the value of the distance used at the time of reconstruction are decided in advance. For example, it is assumed that the resistance value can be changed from 0 to 1 kΩ. If the resistance value is 0Ω, the reconstruction distance is 0 m, and if the resistance value is 1 kΩ, the reconstruction distance is infinite.

The reconstruction computer 6 reads out the data from the measuring device 5 in a timely manner, converts the reconstruction distance based on the resistance value read from the operation panel 22, and reconstructs the distribution based on the value. The distribution state is visualized and displayed on the display device 7. If the distance between the leaked radioactivity and the distance used for reconstruction are different, the images of each pinhole will not be gathered at one place on the reconstruction surface, resulting in a blurred distribution image on the display device 7. (See FIGS. 3A and 3C).

The reconstructing computer 6 repeatedly reads the values of the measuring device 5 and the operation panel 22 to reconstruct them, and displays them on the display device 7. The operator changes the resistance value of the operation panel 22 while observing the distribution image on the display device 7 so that the distribution intensity becomes the strongest. This operation allows visualization of the distribution.

According to the radiation distribution measuring apparatus of the second embodiment described above, the distance at the time of reconstruction is calculated based on the information on the operation panel 22, and the operator at the time of reconstruction based on the reconstructed distribution image. By changing the information of the operation panel 22 and optimizing the distance of 1, the radiation distribution can be visualized even if the distance to the measurement object is unknown or the distance is not directly measured.

Next, a third embodiment will be described.
This form is a modification of the radiation distribution measuring apparatus shown in FIG. 2, in which the reconstruction computer 6 is provided with functions such as storing and discriminating the intensity distribution. That is, in the second embodiment, the operator changes the resistance value of the operation panel 22 so that the distribution intensity becomes the strongest while looking at the distribution image of the display device 7. However, this operation is automatically performed by the reconstruction computer 6. It is intended to be carried out.

Specifically, first, the position of the reconstruction surface is set to a distant position for reconstruction (state of FIG. 3A), and the intensity distribution at this time is stored. Next, the position of the reconstruction surface is moved closer by a predetermined value for reconstruction, and the intensity distribution at this time is stored. This operation is repeated until the reconstruction surface reaches the position of the reconstruction pinhole 12a, and the intensity distribution at the strongest position (state in FIG. 3B) of the intensity distribution obtained at each reconstruction position. The distribution is visualized by displaying.

According to the radiation distribution measuring apparatus of the third embodiment, since the reconstruction computer 6 selects the distance at the time of reconstruction so that the intensity distribution becomes maximum, the distance from the object is reduced. The radiation distribution can be visualized without knowing the distance or directly measuring the distance.

FIG. 4 is an operation explanatory view for explaining the fourth embodiment. The radiation distribution measuring apparatus of this embodiment is such that the reconstruction computer 6 automatically performs the same operation as in the third embodiment, but the measurement is performed by changing the distance between the aperture 3 and the radiation detector 4. The point to do is different.

That is, FIG. 4A shows the case where the distance is z ', and FIG. 4B shows the case where the distance is z ". The distance between the pinholes 2 of the aperture 3 is set to L ₁ and the measurement is performed by the radiation detector 4. The distances between the pinholes 4a are L ₂ and L _{3. The} following equations are obtained from the similar relationships in FIGS.

[0053]

[Number 1] (z-z '): L 1 = z: L 2 (1)

[Number 2] (z-z "): L 1 = z: L 3 (2)
From the expressions (1) and (2), the distance z between the radiation source and the radiation detector is as follows.

[0054]

(Equation 3) z ′ and z ″ are known from the set values at the time of measurement, and L
₂ / L ₃ and L ₃ / L ₂ are distribution intensity ratios of the detector at the time of measurement and can be obtained by measurement. Therefore, the distance z between the measurement object and the radiation detector is obtained. The distribution can be visualized by reconstructing the distribution based on the obtained distance value.

According to the radiation distribution measuring apparatus of the fourth embodiment, the distance between the aperture 3 and the radiation detector 4 is changed and the measurement is performed, and the pattern of the pinholes measured by the radiation detector 4 is similar. Since the distance between the object to be measured and the radiation detector 4 is set based on the ratio, it is possible to visualize the distribution of radiation even if the distance to the object is unknown or the distance is not directly measured. Become.

FIG. 5 shows a fifth embodiment. This radiation distribution measuring device visualizes the distribution of radiation emitted from radiation sources in several pipes and devices having different distances from the radiation detector 4.

That is, in addition to the first embodiment, the rangefinder 2
An operation panel 22b having a switch for setting the timing for reading the distance read at 0 by the reconstruction computer 6 and canceling the read distance information, and the operation panel 22b.
An interface circuit 21b for inputting the state of b to the reconstruction computer.

In such a radiation distribution measuring apparatus, the distance to each individual object is measured using the range finder 20 which measures each distance to each of a plurality of objects. Here, consider a case where the radiation distributions of two pipes 8a and 8b having different distances are visualized at the same time. First, the distance is aimed at the first pipe 8a and the distance is measured. When the distance is obtained, the switch on the operation panel 22b is pressed. The reconstruction computer 6 is
When the switch is pressed, the distance is input from the rangefinder 20, the distance is stored, reconstruction is performed based on the value, and the result is displayed on the display device 7. In this state, since the distribution of the second pipe 8b is reconstructed by using the distance from the first pipe 8a, the distribution image becomes blurred on the display device.

Next, aim the distance meter 20 toward the second pipe 8b,
Measure the distance. When the distance is calculated, the operation panel 22
Press the b switch. When the switch is pressed, the reconstruction computer 6 inputs the distance from the distance meter 20 to the second pipe 8b and stores the value. The reconstruction computer 6 independently performs the reconstruction based on the values of the two distances, that is, the distance to the first pipe 8a and the distance to the second pipe 8b, and the results are simultaneously displayed on the display device 7. indicate.

In this state, the distribution of the first pipe 8a and the second pipe 8a
Since the distribution of the pipe 8b and the distribution of the pipe 8b are reconstructed using the respective distances, a distribution image can be simultaneously obtained on the display device 7. When the number of objects is N, by repeating this, the distribution of N objects can be obtained at the same time. When another object is newly measured, the switch for releasing the distance on the operation panel 22b is pressed. As a result, the reconstruction computer deletes the stored distance information.

According to the radiation distribution measuring apparatus of the fifth embodiment as described above, a plurality of distances at the time of reconstruction are designated, reconstruction is performed at each designated distance, and the results are superposed, whereby the distances are different. It becomes possible to simultaneously visualize the radiation distribution of a plurality of objects.

FIG. 6 shows a sixth embodiment. This radiation distribution measuring device visualizes the radiation distribution of an object having a depth, and in addition to the first embodiment described above, the operation panel 22d and the interface circuit 21d.
And The operation panel 22d sets a switch for setting the timing at which the reconstruction computer 6 reads the shortest distance read by the rangefinder 20, and the timing for the reconstruction computer 6 to read the farthest distance read by the rangefinder 20. It has a switch, a switch for canceling the read distance information, and a keyboard for inputting the distance information.
The interface circuit 21d inputs the state of the operation panel 22d to the reconstruction computer 6.

In such a radiation distribution measuring apparatus, the depth of the object 8 is measured using the range finder 20.
The direction of the range finder 20 is adjusted to the closest point of the object 8 and the distance is measured. When the distance is obtained, the switch for setting the timing at which the reconstruction computer 6 reads the closest distance on the operation panel 22d is pressed. When the switch is pressed, the reconstruction computer 6 inputs the distance information from the distance meter 20 and stores the distance.

Next, the direction of the rangefinder 20 is adjusted to the farthest point of the object 8 to measure the distance. When the distance is obtained, the switch for setting the timing at which the reconstruction computer 6 reads the farthest distance on the operation panel 22d is pressed. When the switch is pressed, the reconstruction computer 6 inputs the distance information from the distance meter 20 and stores the distance. The reconstruction computer 6 reads from the keyboard the interval at which the closest point and the far point are divided, and sets the distance used at the time of reconstruction.
The distance between the shortest distance and the longest distance is divided and set by the number read from the keyboard, and reconstruction is performed independently based on the set individual distance values, and the results are displayed simultaneously.
To display.

On the display device 7, the distribution of the object 8 in the specified range is simultaneously obtained. When another object is newly measured, the switch for canceling the distance on the operation panel 22d is pressed. The reconstruction computer 6 deletes the stored distance information.

According to the radiation distribution measuring apparatus of the sixth embodiment as described above, the closest distance and the farthest distance from the object to be measured are designated, and the distance between them is set by dividing by the designated number. By performing reconstruction based on the values of the individual distances, and superimposing the results, it is possible to simultaneously visualize the radiation distribution of a deep object.

FIG. 7 shows a seventh embodiment. This radiation distribution measuring device visualizes the distribution of radiation emitted from a radiation source in piping and equipment. That is, an aperture 3 having a large number of pinholes 2, a two-dimensional position detection type radiation detector 4 for detecting radiation transmitted through the pinholes 2, and a signal pulse of the detector 4 are determined. Signal processing device 23 that generates a current proportional to the counting intensity of the crest value signal, two-dimensional emission panel 24 having the same shape as radiation detector 4 that emits light in proportion to the intensity of the current, and the same position as aperture 3. And a light shielding plate 25 having the same number of pinholes 25a.

In such a radiation distribution measuring apparatus, the radiation detector 4 measures the incident intensity of the radiation from the object 8 which passes through the pinhole 2 of the aperture 3. The signal pulse from each micro-detector 4a is used to generate a current that is proportional to the counting intensity of the signal having the peak value determined by the signal processing device 23. A two-dimensional light-emitting panel 24 having the same shape as the radiation detector 4 is arranged at the same distance as the distance between the radiation detector 4 and the measurement object 8, and a light shielding plate 25 having a pinhole 25a at the same position as the aperture 3 is provided. Place it at the same distance as aperture 3.

Each light emitting element 24a of the light emitting panel 24 is caused to emit light by a current generated in the signal processing device 23 and proportional to the detection intensity of each detector. The light emitting panel 24 corresponds to a virtually arranged planar light emitting source at the time of reconstruction performed by a conventional computer. The light emitted from the light emitting panel 24 is transmitted through the pinhole 25 a of the light shielding plate 25 and projected onto the measurement target 8. By directly projecting onto the measurement object 8, the distance at the time of reconstruction will match the distance to the measurement object 8 and an image will be formed on the measurement object 8, and the distribution of radiation can be visualized. .

According to the radiation distribution measuring apparatus of the seventh embodiment, the light emitted from the light emitting panel 24 is used by using the light emitting panel 24 and the light shielding plate 25 having the pinhole 25a for reconstruction of the radiation distribution. By projecting the light through the pinhole 25a and projecting it onto the measurement object 8, the radiation distribution can be visualized without measuring the distance to the measurement object. Moreover, a computer for reconstruction is not necessary.

FIG. 8 shows an eighth embodiment. This radiation distribution measuring apparatus is a modification of the seventh embodiment, in which a light emitting panel 24 is arranged in a merged state on the front surface side of the radiation detector 4 on the side opposite to the measurement object 8 side of the aperture 3, and these radiation detectors are arranged. 4 and the light emitting panel 24 are connected to the signal processing device 23.

In such a radiation distribution measuring apparatus, the light emitted from the light emitting panel is transmitted through the pinhole 2 of the aperture 3 and projected onto the measuring object 8. As a result, as in the seventh embodiment, by directly projecting on the measurement target 8, the distance at the time of reconstruction coincides with the distance to the measurement target 8 and the image on the measurement target 8 is changed. Can be imaged and the distribution of radiation can be visualized.

According to the radiation distribution measuring apparatus of the eighth embodiment, by disposing the light emitting panel 24 for reconstruction of the distribution used in the seventh embodiment in front of the radiation detector 4, The function of the light shielding plate used for the reconstruction can be substituted by the aperture 3, the light shielding plate becomes unnecessary, and the device can be downsized. Further, it is not necessary to match the distance and direction of the light emitting panel, and the operation of the device can be simplified.

FIG. 9 shows a ninth embodiment. This radiation distribution measuring device visualizes the distribution of radiation emitted from a radiation source in a pipe or a device, and an optical reflection plate 26 placed on an axis 0 passing through the aperture 3 and the radiation detector 4.
An image camera 27 for taking an image of piping or the like at a position reflected by the optical reflection plate 26, and an interface circuit 28 for inputting an image to the reconstruction computer 6.

In such a radiation distribution measuring apparatus, the image of the pipe which is the measuring object 8 is the optical reflection plate 26.
It is reflected by and is photographed by the image camera 27. The radiation source 9 of the measurement object 8 is measured by the radiation detector 4.

It is desirable that the optical reflection plate 26 is made of a thin structural material whose absorption of radiation is negligible. When the radiation detector 4 is aimed at the measurement target 8, the optical reflection plate 26 also moves accordingly, and the image of the measurement target 8 is constantly captured.
The image of the image camera 27 is input to the reconstruction computer 6 by the interface circuit 28, and is displayed on the display device 7 while overlapping with the radiation distribution image.

According to the radiation distribution measuring apparatus of the ninth embodiment, the optical reflection plate 26 is placed on the axis 0 passing through the aperture 3 and the radiation detector 4, and the visible image reflected by the optical reflection plate is placed. By capturing the image with an image camera, the axes of the radiation distribution image and the visible image coincide with each other, and an error is eliminated when the images are superimposed. Further, by disposing the optical reflection plate 26, which absorbs little radiation, on the axis 0 that passes through the aperture 3 and the radiation detector 4, it is possible to reduce the influence on the radiation distribution measurement.

FIG. 10 shows a tenth embodiment.
This radiation distribution measuring apparatus uses a pinhole system, and the radiation detector 4 is sensitive to visible light as well.
A shield plate 30 having a three-dimensional image sensor and having a large number of pinholes 29 formed therein, and the pinholes 2
A light-shielding plate 32 having a pinhole 31 overlapping with one of the holes 9, a light-shielding container 33 for accommodating the shielding plate 30 and the radiation detector 4, and a window 34 that can be opened and closed in front of the light-shielding container 33, The measuring device 5, the reconstruction computer 6 and the display device 7 similar to those of the above-described respective embodiments are provided.

In such a radiation distribution measuring apparatus, when the radiation from the object 8 to be measured is measured, the opening / closing window 34 of the light shielding container 33 is closed to shield the light, and a large number of pinholes 2 are provided.
The radiation distribution is measured by the radiation detector 4 through the shielding plate 30 in which 9 is opened, and the radiation distribution is reconstructed.

When photographing an image of the object 8 to be measured, the opening / closing window 34 of the light shielding container 33 is opened, and the radiation detector 4 photographs through the pinhole 31 opened in the light shielding plate 32 (specifically, the light Measure the intensity distribution). Then, the image (light intensity distribution) information is loaded into the reconstruction computer 6,
It is displayed on the display device 7 so as to overlap the radiation distribution image. It should be noted that the light shielding container 33 and the light shielding plate 32 are preferably made of a thin structural material in which absorption of radiation can be ignored.

According to the radiation distribution measuring apparatus of the tenth embodiment as described above, the radiation detector 4 uses the two-dimensional image sensor which is also sensitive to visible light, so that the ninth embodiment
The optical reflector and the image camera used in the above embodiment are not required, and the device can be simplified and downsized. Further, since the distribution image obtained in the ninth embodiment and the axis of the visible image are in agreement with each other, no error occurs when superimposing them.

[0082]

As described in detail above, according to the present invention, the distance between the measuring object and the measuring object can be obtained at the same time when the distribution measurement is started. Therefore, the distance between the detector and the measuring object is measured each time. Then, it becomes unnecessary to input the measured distance information into the computer. As a result, the distribution of the object whose distance is unknown can be reconstructed simultaneously with the measurement.

Further, by applying the present invention, it becomes possible to visualize an invisible leak or the like, or when the distance cannot be measured, or the visualization can be performed accurately without measuring the distance. Even without input, the distance information can be calculated based on the measurement result and the distribution can be reconstructed.

Furthermore, simultaneous visualization of the radiation distributions of a plurality of measurement objects with different distances, accurate simultaneous visualization of the distribution of the entire radiation when the object has a depth, and re-creation without the need to measure the distance to the measurement object The configuration can be made possible, the size of the device can be reduced by eliminating the need for a computer for reconfiguration, and the distribution state can be projected directly onto the measurement target to facilitate grasping the distribution state.

Furthermore, it is possible to make the axes of the radiation distribution image and the visible image coincide with each other without affecting the radiation distribution measurement, thereby eliminating the error in superimposing.

[Brief description of drawings]

FIG. 1 is a configuration diagram illustrating a first embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 2 is a configuration diagram illustrating a second embodiment of a radiation distribution measuring apparatus according to the present invention.

3 (a), (b) and (c) are explanatory views of the operation of the second and third embodiments of the radiation distribution measuring apparatus according to the present invention.

4 (a) and 4 (b) are operation explanatory views of the fourth embodiment of the radiation distribution measuring apparatus according to the present invention.

FIG. 5 is a configuration diagram illustrating a fifth embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 6 is a configuration diagram illustrating a sixth embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 7 is a configuration diagram illustrating a seventh embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 8 is a configuration diagram illustrating an eighth embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 9 is a configuration diagram illustrating a ninth embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 10 is a configuration diagram illustrating a tenth embodiment of a radiation distribution measuring apparatus according to the present invention.

FIG. 11 is a configuration diagram showing a conventional radiation distribution measuring apparatus.

12 (a) and (b) are explanatory views of the operation of the device shown in FIG.

[Explanation of symbols]

 1 Radiation distribution measuring device 2 Pinhole 3 Aperture 4 Two-dimensional position detection type radiation detector 4 4a Micro detector 5 Measuring device 6 Reconstruction computer 7 Display device 8 Measurement object 8a, 8b Piping 9 Radiation source 10 Light emitting source 12a Reconstruction pinhole 20 Distance meter 21,21d Interface circuit 22,22d Operation panel 24 Two-dimensional light emitting panel 24a Light emitting element 25 Light shielding plate 25a Pinhole 26 Optical reflector 27 Image camera 28 Interface circuit 29 Pinhole 30 Shielding plate 31 Pinhole 32 Shading plate 33 Shading container 34 Opening / closing window

Claims (10)

[Claims] 1. An aperture in which a large number of pinholes are formed in a shield plate made of a material that shields radiation, a radiation detector of a two-dimensional position detection type that detects radiation transmitted through the pinholes of the aperture, and this radiation. Reconstructing means for performing a signal count of the detector and reconstruction processing of the distribution based on the count value, and a display device for displaying the result of the distribution,
In a radiation distribution measuring device that measures the distribution of radiation by measuring piping, equipment, walls, and other structures in which the radiation source exists, a non-contact type distance that measures the distance between the measurement object and the radiation detector. And a means for inputting the value of the distance obtained by this rangefinder online to the computer, and the radiation distribution is characterized by performing the reconstruction of the radiation distribution based on the value of the distance. apparatus. 2. The radiation distribution measuring apparatus according to claim 1, wherein a function of freely setting a distance value used for reconstruction from an operation panel and a reconstruction of the distribution based on the distance value are performed. A radiation distribution measuring apparatus having a function of displaying, and performing reconstruction by changing a value of a distance from an operation panel so as to reduce blur of a reconstructed image. 3. The radiation distribution measuring device according to claim 1, wherein the reconstruction distance is automatically determined so that the intensity of the reconstructed image of the distribution is maximized. . 4. The radiation distribution measuring device according to claim 1, wherein the distance between the shielding plate and the radiation detector is changed to perform measurement, and the object to be measured is based on the similarity ratio of the pinhole pattern measured by the detector. The radiation distribution measuring device is characterized in that the distance between the radiation detector and the radiation detector is calculated, and the distribution is reconstructed based on the value of the distance. 5. The radiation distribution measuring device according to claim 1, wherein in order to simultaneously and accurately reconstruct the distributions of radiation from a plurality of measurement objects having different distances, a detector is provided for each necessary number of measurement objects. The radiation distribution measuring apparatus is characterized in that the distances between and are set, the distribution is reconstructed based on the set individual distance values, and the results are displayed in an overlapping manner. 6. The radiation distribution measuring apparatus according to claim 1, wherein a distance used for reconstruction is set by dividing a specified distance range by a specified number, and the set individual distance values are set. A radiation distribution measuring apparatus characterized by performing reconstruction based on the original and displaying the results in an overlapping manner. 7. The radiation distribution measuring apparatus according to claim 1, wherein a two-dimensional light-emitting panel having the same shape as that of the two-dimensional position detection type radiation detector is used for reconstruction of the distribution, and the distance from the measurement object is the radiation detector. Placed at the same distance as, and a light shielding plate having the same shape as the radiation shielding plate or the radiation shielding plate and having a reduced thickness, is arranged at a distance at which the distance to the measurement object is the same as the radiation shielding plate, A radiation distribution measuring device characterized in that light radiated by a light emitting panel is transmitted through a pinhole and projected onto a measurement object to visualize a radiation distribution. 8. The radiation distribution measuring apparatus according to claim 1, wherein the two-dimensional light emitting panel is arranged so as to overlap with the radiation detector. 9. The radiation distribution measuring apparatus according to claim 1, wherein an optical reflection plate is placed on an axis passing through the shield plate having a large number of pinhole-shaped holes and the radiation detector, and a visible image reflected by the reflection plate. The radiation distribution measuring device is characterized in that the image is photographed by an image camera and is displayed so as to be superimposed on the radiation distribution obtained by the radiation distribution measuring device. 10. The radiation distribution measuring apparatus according to claim 1, wherein the radiation detector is a two-dimensional image sensor sensitive to visible light, and one of the many pinholes formed in the shield plate is left. The other holes are shielded from light, the shielding plate and the radiation detector are housed in a container that can shield light, and a window that can be opened and closed is prepared on the front of the container.When the window is opened, it can be obtained by the detector through one pinhole. A radiation distribution measuring apparatus, wherein a visible image and a radiation distribution obtained by reconstruction when the window is closed are displayed in an overlapping manner.