KR102446632B1 - Rotary radiation detector with multiple resolutions - Google Patents

Abstract

The present invention relates to a rotary radiation detector providing multiple resolution, comprising: at least one flash crystal that detects radiation emitted from a radiation emitting unit and incident on an outer peripheral surface and converts it into a flash signal; an optical sensor for converting a signal; and a rotation unit installed on the flash crystal to rotate the flash crystal so that an incident surface of the flash crystal on which radiation is incident can be changed.
The rotary radiation detector providing multiple resolutions according to the present invention changes the incident surface on which radiation is incident by rotating the scintillation crystal by the rotation unit, so it is possible to easily obtain images of various resolutions without replacing the detector. have.

Description

Rotary radiation detector with multiple resolutions

The present invention relates to a rotary radiation detector providing multiple resolutions, and more particularly, to provide multiple resolutions capable of operating in a high-resolution mode by rotating the radiation detector in a transverse direction and operating in a normal resolution mode by rotating the radiation detector in a reverse direction. It relates to a rotary radiation detector.

Dual energy X-ray Absorptiometry among nuclear medicine imaging devices acquires transmission/absorption images by irradiating high and low-energy X-rays, and transmits X-rays to bone or adjacent tissues to measure bone density and mineral content. It is a measuring instrument.

As the last DEXA detector, a detector using a CZT (CdZnTe) sensor with a wide band gap and excellent energy resolution is being used as a commercial product, but it has a fragile structure, damage over time, incomplete charge collection due to charge trapping, and temperature increase. There are technical problems such as large dark currents. Also, recently, cadmium has been selected as a hazardous material by the WHO, and the use of CZT sensors is sanctioned.

LYSO scintillation crystals have excellent properties such as fast decay time (~40 ns), high light output and low cost for DEXA applications. In addition, it had excellent detection efficiency (linear attenuation coefficient = 4356 cm-1 at 80 keV) for the DEXA energy range of 20 keV to 100 keV.

The GAPD optical sensor greatly improves the timing performance of the sensor by increasing the transit time spread, and has high performance advantages such as low supply voltage, good temperature stability, robustness, compactness and output uniformity. In addition, the detection efficiency is good because the minimum supply voltage is low, the maximum wavelength is similar to that of LYSO (420 nm), the PDE% is high, and the signal rise time is short. Therefore, recently, commercial products that replace the conventional CZT-based DEXA products using a radiation detector combined with LYSO-GAPD have appeared.

However, in the case of the conventional radiation detector, since the size of the incident surface of the scintillation crystal on which the radiation is incident is fixed, it is cumbersome because the detector needs to be replaced in order to change the resolution.

Registered Patent Publication No. 10-1661936: Double scintillation detector for improved hygroscopicity and removal of surface alpha particles and method for manufacturing the same

The present invention was devised to improve the above problems, and by rotating a scintillation crystal to change an incident surface on which radiation is incident, providing a rotary radiation detector providing multiple resolutions capable of providing general and high resolution images but it has a purpose.

A rotary radiation detector providing multiple resolution according to the present invention for achieving the above object includes at least one flash crystal that detects radiation emitted from a radiation emitting unit and incident on an outer peripheral surface and converts it into a flash signal; an optical sensor for converting a flash signal into an electrical signal; and a rotation unit installed on the flash crystal to rotate the flash crystal so that an incident surface of the flash crystal on which radiation is incident can be changed.

The scintillation crystal is formed to have a first incident surface and an area spaced apart from the first incident surface to have an area different from that of the first incident surface.

Preferably, the rotation unit rotates the flash crystal so that the radiation is incident on any one of the first and second incident surfaces.

The scintillation crystal is formed in a hexahedral shape.

Preferably, the scintillation crystal is formed such that the first and second incident surfaces are orthogonal to each other.

The photosensor is installed in the scintillation crystal at a position spaced apart from the first and second incident surfaces.

The photosensor may be installed on an outer peripheral surface opposite to the first incident surface with respect to the center of the scintillation crystal.

The photosensor is preferably fixed to the outer peripheral surface of the scintillation crystal by an optical grease or adhesive.

On the other hand, the rotary radiation detector providing multiple resolution according to the present invention is installed so as to surround the outer peripheral surface of the scintillation crystal except for the first and second incident surfaces and the installation surface on which the photosensor is installed to detect the flash signal. A reflective reflector may be further provided.

In addition, the rotary radiation detector providing multiple resolution according to the present invention is formed to surround the outer peripheral surface of the optical sensor so as to reduce radiation loss generated when the scintillation crystal is rotated, further comprising a shielding sheet for shielding radiation You may.

The rotation unit may include a frame, a rotation bracket rotatably installed on the frame, the scintillation crystal or optical sensor installed on one side, and a driving member installed on the rotation bracket to rotate the rotation bracket. .

The rotation unit may further include a rotation control unit for controlling the driving member so that the scintillation crystal is set so that an incident surface selected by a user so that radiation is incident among the first and second incident surfaces is opposite to the radiation emitting unit. have.

The scintillation crystals are BGO (Bismuth Germanate), LSO (Lutetium Oxyorthosilicate), LYSO (Lutetium Yttrium Oxyorthosilicate), LuAP (Lutetium Aluminum Perovskite), LuYAP (Lutetium Yttrium Aluminum Perovskite), LaBr3 (Lanthanum Iodide), LuI3 (Lanthanum Bromide), GSO(Gadolinium oxyorthosilicate), LGSO(lutetium gadolinium oxyorthosilicate), LuAG(Lutetium aluminum garnet), GAGG(Gd3Al2Ga3 O123Al2Ga3O12), LFS(Lutetium Fine Silicate), NaI(Tl) (Thallium doped Sodium) (Thallium doped Sodium) activated Cesium Iodide).

The photosensor is preferably made of at least one of a PN diode, a PIN diode, an Avalanche Photo Diode (APD), a GAPD, and a PMT.

On the other hand, the rotary radiation detector providing multiple resolution of the present invention is installed on the first incident surface of the scintillation crystal, and detects the radiation emitted from the radiation emitting unit and is incident and converts it into a scintillation signal, but the second A subcrystal having an incident surface having an area different from that of the incident surface may be further provided.

The sub-crystal is formed with a third incident surface opposite to the contact surface in contact with the first incident surface with respect to the center, and is adjacent to the second incident surface so that radiation incident to the second incident surface is incident. , a fourth incident surface is formed on an outer peripheral surface extending parallel to the second incident surface to have an area different from that of the second incident surface.

The sub-crystal may be formed in a hexahedral shape, and the third incident surface may be formed to have an area corresponding to an area of the first incident surface.

The rotary radiation detector providing multiple resolutions according to the present invention changes the incident surface on which radiation is incident by rotating the scintillation crystal by the rotation unit, so it is possible to easily obtain images of various resolutions without replacing the detector. have.

1 is a perspective view of a rotary radiation detector providing multiple resolution according to the present invention;
2 and 3 are views showing the operating state of the rotary radiation detector providing the multi-resolution of FIG. 1,
Fig. 4 is a block diagram of a rotary radiation detector providing multiple resolutions of Fig. 1;
5 is a conceptual diagram of a rotational radiation detector providing multi-resolution of the present invention manufactured for performance inspection;
6 is a plan view of a phantom sample used for performance testing of a rotary radiation detector providing multiple resolution of the present invention;
7 is a result of examining the double energy X-ray spectrum for the rotary radiation detector of the present invention;
8 is a DEXA image of a phantom sample obtained using the radiation detector of the present invention;
9 and 10 are diagrams illustrating an operating state of a rotary radiation detector providing multiple resolution according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to the rotary radiation detector providing multiple resolution according to an embodiment of the present invention. Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals have been used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged than the actual size for clarity of the present invention.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate that a feature, number, step, operation, component, part, or a combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 to 4 show a rotary radiation detector 100 providing multiple resolutions according to the present invention.

Referring to the drawings, the rotational radiation detector 100 providing the multi-resolution includes a scintillation crystal 110 that detects radiation emitted from a radiation emitting unit and incident on an outer circumferential surface and converts it into a scintillation signal, and the scintillation crystal 110 ), the optical sensor 120 for converting the flash signal into an electrical signal, and the flash crystal 110 is installed in the flash crystal 110 so that the incident surface of the flash crystal 110 to which radiation is incident can be changed. and a rotation unit 130 for rotating the .

The scintillation crystal 110 generates a scintillation signal by radiation incident from a radiation emitting part, such as a radiopharmaceutical or a radiation emitter from which radiation is emitted, injected into the body of the subject, BGO (Bismuth Germanate), LSO (Lutetium Oxyorthosilicate). ), LYSO (Lutetium Yttrium Oxyorthosilicate), LuAP (Lutetium Aluminum Perovskite), LuYAP (Lutetium Yttrium Aluminum Perovskite), LaBr3 (Lanthanum Bromide), LuI3 (Lutetium Iodide), GSO (Gadolinium oxy), LuI3 (Lutetium Iodide), GSO (Gadolinium oxyorthosilicate) oxyorthosilicate (Lutetium aluminum garnet), GAGG (Gd3Al2Ga3 O123Al2Ga3O12), LFS (Lutetium Fine Silicate), NaI (Tl) (Thallium doped Sodium Iodide), CsI (Tl) (Thallium activated Cesium Iodide) consists of at least one.

Here, LYSO has excellent characteristics such as fast decay time (~40 ns), high light output and low cost for DEXA application, and has excellent detection efficiency (linear at 80 keV) for the DEXA energy range of 20 keV to 100 keV. Attenuation coefficient = 4356 cm-1), so the scintillation crystal 110 is preferably LYSO applied.

The scintillation crystal 110 is formed in a rectangular parallelepiped shape extending in the vertical direction. Here, the upper surface of the scintillation crystal 110 forms a first incident surface 111 on which radiation is incident, and a second incident surface 112 is formed on the rear surface of the scintillation crystal 110 spaced apart from the first incident surface 111 . The first and second incident surfaces 111 and 112 are formed to be orthogonal to each other.

In addition, the scintillation crystal 110 is formed so that the areas of the first and second incident surfaces 111 and 112 are different from each other, that is, the first incident surface 111 has a larger area than the second incident surface 112 . The scintillation crystal 110 is preferably formed of 3×3×2 mm ³ . Here, the first incident surface 111 has an area of 3×3 mm ² , and the second incident surface 112 has an area of 3×2 mm ² .

Meanwhile, the scintillation crystal 110 is not limited thereto, and 3×3×1 mm ³ of LYSO and 3×3×1 mm ³ GAGG may be applied. The optical sensor 120 is installed on the lower surface of the scintillation crystal 110 .

On the other hand, the scintillation crystal 110 is formed with a reflector (not shown) so as to surround the first and second incident surfaces 111 and 112 and the outer peripheral surface excluding the installation surface on which the photosensor 120 is installed. The reflector reflects the flash signal generated by the flash crystal 110 toward the photosensor 120 to improve the sensing efficiency of the photosensor 120 . The operator grinds the outer peripheral surface of the scintillation crystal 110 excluding the first and second incident surfaces 111 and 112 and the corresponding installation surface, and then wraps it with a reflector.

Meanwhile, in the illustrated example, one flashing crystal 110 is provided, but the present invention is not limited thereto, and a plurality of flashing crystals 110 may be arranged in a lattice form.

The photosensor 120 is bonded and fixed to the lower surface of the scintillation crystal 110 by an adhesive layer 121 made of optical grease or adhesive. The photosensor 120 is for detecting a flash signal generated by the flash crystal 110, and at least one of a PN diode, a PIN diode, an avalanche photo diode (APD), GAPD, and PMT is applied. Here, GAPD greatly improves the timing performance of the sensor by increasing the transit time spread, and has high performance advantages such as low supply voltage, good temperature stability, robustness, miniaturization and output uniformity, and has a low supply voltage and a maximum wavelength similar to that of LYSO ( 420 nm), the PDE% is high and the signal rise time is short, so the detection efficiency is good.

At this time, the photosensor 120 is formed to have an area of 3×3 mm ² to correspond to the shape of the flash crystal 110 , but is not limited thereto and may be formed in various ways depending on the size of the flash crystal 110 . have.

On the other hand, the optical sensor 120 has a shielding sheet (not shown) is formed to surround the outer peripheral surface of the optical sensor 120 to reduce radiation loss generated when the scintillation crystal 110 is rotated. The shielding sheet is formed of a radiation shielding material such as lead to shield radiation, and is preferably formed to have a thickness of 2 mm. In addition, a fixing block 122 made of lead is installed on the rear surface of the optical sensor 120 . The fixing block 122 is formed to extend to a length corresponding to the left and right widths of the optical sensor 120 .

The rotation unit 130 is rotatably installed on the frame 131 and the frame 131 , and a rotation bracket 132 in which an optical sensor 120 is installed on one side, and the rotation bracket 132 . A driving member 133 for rotating the rotation bracket 132 and a rotation control unit (not shown) for removing the driving member 133 are provided.

The frame 131 is positioned opposite to the radiation emitting part, and although not shown in the drawing, is installed in the test apparatus opposite to the bed on which the subject lies. At this time, the radiation detector 100 and the X-ray apparatus of the present invention are disposed on opposite sides of each other, and a lead collimator having a thickness of 3 mm may be used and may be passed through a k-edge Ce filter having a thickness of 1 mm. On the other hand, the frame 131 is not limited thereto, and can be any structure installed in a detection means capable of detecting radiation.

The rotation bracket 132 is rotatably installed on the frame 131 by the driving member 133 . At this time, the rotation bracket 132 is installed on the lower portion of the optical sensor 120, it is preferable to be installed on the driving member 133 rotatably based on the center line extending in the left and right direction. On the other hand, although the illustrated example shows a structure in which the rotation bracket 132 is installed on the optical sensor 120 , the rotation bracket 132 is not limited thereto and may be fixed to the side of the flash crystal 110 .

The driving member 133 is installed on the frame 131, and a step motor generating rotational force by the applied electricity is applied. At this time, the driving member 133 has a driving shaft fixed to the rotation bracket 132 . Meanwhile, the driving member 133 is not limited thereto, and any driving means capable of rotating the rotation bracket 132 may be applied.

The rotation control unit controls the driving member 133 to set the spheroid crystal so that the incident surface selected by the user so that the radiation is incident among the first and second incident surfaces 111 and 112 is opposite to the radiation emitter. Although not shown in the drawing, the rotation control unit includes a selection module so that the user can select any one of the first and second incident surfaces 111 and 112 . When the first incident surface 111 is selected through the selection module, the rotation control unit drives the driving member 133 such that the first incident surface 111 is positioned on the upper side so that radiation is incident to the first incident surface 111 as shown in FIG. 2 . ), and when the second incident surface 112 is selected through the selection module, the driving member so that the second incident surface 112 is positioned on the upper side so that radiation is incident to the second incident surface 112 as shown in FIG. 3 . (133) is controlled.

The operation of the rotary radiation detector 100 providing multi-resolution according to the present invention configured as described above will be described in detail as follows.

First, when a user wants to acquire a normal resolution image, the user selects the first incident surface 111 through the selection module. The rotation control unit controls the driving member 133 to rotate the scintillation crystal 110 so that the first incident surface 111 is located on the upper side. At this time, radiation is incident through the first incident surface 111 having an area of 3×3 mm ² , and the scintillation crystal 110 emits a scintillation signal corresponding to the incident radiation. The optical sensor 120 converts the emitted flash signal into an electrical signal, and the optical sensor 120 transmits the converted electrical signal to the signal processing unit 200 .

In addition, when the user wants to acquire a high-resolution image, the user selects the second incident surface 112 through the selection module. The rotation control unit controls the driving member 133 to rotate the scintillation crystal 110 so that the second incident surface 112 is located on the upper side. At this time, radiation is incident through the second incident surface 112 having an area of 2×3 mm ² , and the scintillation crystal emits a flash signal corresponding to the incident radiation. The optical sensor 120 converts the emitted flash signal into an electrical signal, and the optical sensor 120 transmits the converted electrical signal to the signal processing unit 200 .

The signal processing unit 200 is connected to a plurality of radiation detectors 100 arranged according to a predetermined pattern, and converts an electrical signal provided from the photosensor 120 into a digital signal. The analog processing unit 210 and the digital A processing unit 220 is provided.

The analog processing unit 210 is installed in each of the radiation detectors 100, receives an analog electrical signal and compares it with a signal according to a preset threshold voltage to generate a trigger signal, and a first preamplifier 211 ), a comparator 212 , a second preamplifier 213 , and a switching unit 214 .

The first preamplifier 211 receives an electrical signal from the optical sensor 120 and receives a plurality of analog electrical signals for each channel of the optical sensor 120 so that the electrical signal gain is uniform. amplifies the electrical signal. Meanwhile, the first pre-amplifier 211 may synthesize and output a plurality of amplified electrical signals into one signal.

The comparator 212 receives the electric signal amplified by the first pre-amplifier 211 and compares the received electric signal with a signal according to a preset threshold voltage so that the electric signal exceeds the signal according to the threshold voltage. This generates a trigger signal.

The second pre-amplifier 213 receives the plurality of electrical signals amplified by the first pre-amplifier 211 , performs pulse shaping, and then outputs them. The switching unit 214 receives a standardized pulse from the second pre-amplifier 213, receives a switching signal from the digital processing unit 220, and responds to the received switching signal of the plurality of photosensors 120. A plurality of analog electrical signals for the channel selected by the switching signal are selected and outputted from the electrical signals respectively received from the channels.

The digital processing unit 220 receives the trigger signal from the plurality of analog processing units 210, and in response thereto acquires positional information and energy information on the radiation detection position. The digital processing unit 220 includes a processing control unit 221 , an address location conversion unit 222 , and a counting unit 223 .

The processing control unit 221 receives the trigger signal generated from the comparison unit 212 of the analog processing unit 210, and based on the first received trigger signal among the received trigger signals, a first position expected to be the radiation detection position. create information The processing control unit 221 generates a switching signal to select one analog processing unit 210 corresponding to the first position information among a plurality of analog processing units 210 , and transmits the generated switching signal to the analog processing unit 210 . to the switching unit 214 of

The address location conversion unit 222 receives a plurality of analog electrical signals from the analog processing unit 210 selected by the switching unit 214 among the plurality of analog processing units 210 and 140 and converts them into digital signals. In this case, the converted digital signal may have a size of 10 bits. In particular, the address location conversion unit 222 outputs, from the digital signal, second location information indicating the detailed detection position of the radiation and energy information indicating the energy state at the time of detection of the radiation. In this case, the address location conversion unit 222 may have a sampling rate of 80 MHz, respectively. The counting unit 223 counts the electrical signals provided from the analog processing units 210 .

The signal processing unit 200 provides the processed digital signal, location information, and energy information to an image generation unit (not shown), and the image generation unit displays an analysis image to the user based on the information. Meanwhile, the signal processing unit 200 is not limited to the above-described example, and any signal processing means capable of generating an image by processing an electrical signal provided from the photosensor 120 may be applied.

On the other hand, a performance test was performed on the rotary radiation detector 100 providing the multi-resolution of the present invention. 5 is a conceptual diagram of a rotary radiation detector 100 providing multiple resolutions manufactured for performance testing. Here, the scintillation crystal 110 is 3×3×2 mm ³ LYSO is applied, and the photosensor 120 is 3.07×3.07 mm ² GAPD is applied. A radiation source emitting radiation is set below a phantom sample provided with a pattern of a predetermined pattern, and rotational radiation that provides multiple resolution of the present invention on the upper side of the phantom sample to collect radiation that has passed through the phantom sample Set the detector 100 . 6 is a plan view of the phantom sample. Here, the radiation source is Max. Voltage/Current is 80 kVp/0.1 mA, lead collimator is 3mm thick, and k-edge Ce filter is 0.1mm thick. The distance between the radiation source and the phantom sample is set to 186 mm, and the distance between the radiation source and the radiation detector 100 is set to 584 mm. Table 1 and FIG. 7 below show the results of examining the dual energy X-ray spectrum for the rotary radiation detector 100 of the present invention.

Here, the 'Normal-resolution mode' is a state in which the first incident surface 111 is set to face the radiation source, and the 'High-resolution mode' is a state in which the second incident surface 112 is set to face the radiation source. to be. Referring to Table 1 and Figure 7, there is no change in energy information such as spectra shape, PPP, and PVR, and the decrease in the count rate (31.3%) is almost identical to the predicted value (33.3%) predicted before the test. can be known

8 shows a DEXA image of a phantom sample obtained using the radiation detector 100 of the present invention. Here, the 'normal resolution mode' is a DEXA (Dual Energy X-Ray Absorptiometry) image obtained in a state in which the first incident surface 111 is set to face the radiation source, and the 'high resolution mode' is the second incident surface 112 ) is a DEXA image obtained in a state where it is set to face the radiation source. Referring to the drawings, it can be seen that, in the image acquired in the high-resolution mode, the fine details of the patterns of the phantom sample are relatively clearly visible, and the contrast and spatial resolution are excellent.

The rotational radiation detector 100 providing multiple resolution according to the present invention configured as described above rotates the scintillation crystal 110 by the rotation unit 130 to change the incident surface on which the radiation is incident, so the detector 100 It has the advantage of being able to easily acquire images of various resolutions without replacing the .

In addition, the present invention can be applied to the development of a DEXA detector and system, and can be utilized in various X-ray detector applications. In addition, since the radiation detector 100 of the present invention can convert the scintillation crystal 110 from the normal resolution mode to the high resolution mode by rotating the scintillation crystal 110 from the vertical to the horizontal axis by 90 degrees, in the normal resolution mode, 3 × 3 mm ² in the incident area By collecting X-rays and collecting X-rays at an incident area of 2 × 3 mm ² in high-resolution mode, the intrinsic resolution can be improved by 33%.

Meanwhile, FIGS. 9 and 10 illustrate a rotational radiation detector 300 providing multiple resolutions according to another embodiment of the present invention.

Elements having the same function as in the drawings shown above are denoted by the same reference numerals.

Referring to the drawings, the rotary radiation detector 300 providing the multi-resolution further includes a sub-crystal 310 installed on the first incident surface 111 of the scintillation crystal 110 .

The sub-crystal 310 detects the radiation emitted from the radiation emitting part and converts it into a flash signal, and is GO (Bismuth Germanate), LSO (Lutetium Oxyorthosilicate), LYSO (Lutetium Yttrium Oxyorthosilicate), LuAP (Lutetium Aluminum). Perovskite), LuYAP (Lutetium Yttrium Aluminum Perovskite), LaBr3 (Lanthanum Bromide), LuI3 (Lutetium Iodide), GSO (Gadolinium oxyorthosilicate), LGSO (lutetium gadolinium oxyorthosilicate), LGSO (lutetium gadolinium oxyorthosilicate), LuAG(Lutetium) 123 Al2AlGa2O3O3 (Lutetium Aluminum 123Gd3Al2OGa3O3) (Lutetium Fine Silicate), NaI(Tl) (Thallium doped Sodium Iodide), and CsI(Tl) (Thallium activated Cesium Iodide). Preferably, the sub-crystals 310 are formed of a LYSO material.

The sub-crystals 310 are formed in a rectangular parallelepiped shape extending in the vertical direction with reference to FIG. 9 . At this time, the lower surface of the sub-crystal 310 becomes a contact surface that is fixed in contact with the first incident surface 111 of the scintillation crystal 110, and the upper surface opposite to the contact surface with respect to the center is the third incident radiation. An incident surface 311 is provided.

In addition, the sub-crystals 310 are adjacent to the second incident surface 112 so that the radiation incident to the second incident surface 112 can be incident, and extend in parallel with the second incident surface 112 . On the outer circumferential surface, that is, the rear surface, the fourth incident surface 312 is formed to have an area different from that of the second incident surface 112 . Here, the third and fourth incident surfaces 311 and 312 are provided to be orthogonal to each other and have different areas. At this time, the third incident surface 311 is formed to have an area corresponding to the first incident surface 111 of the scintillation crystal 110 , and the fourth incident surface 312 is the second incident surface of the scintillation crystal 110 . It is preferably formed to have an area smaller than (112).

That is, the sub-crystal 310 is formed of 3×3×1 mm ³ , the third incident surface 311 has an area of 3×3 mm ² , and the fourth incident surface 312 has an area of 3×1 mm ² have an area On the other hand, the sub-crystal 310 is formed with a reflector (not shown) so as to surround the outer peripheral surface except for the contact surface and the third and fourth incident surfaces 311 and 312 . Here, the reflector may improve the sensing efficiency of the photosensor by reflecting the flash signal generated by the sub-crystal 310 toward the photosensor. The operator grinds the outer peripheral surface of the sub-crystal 310 except for the contact surface and the third and fourth incident surfaces 311 and 312, and then wraps it with a reflector.

When the user wants to acquire a normal resolution image, the sub-crystal 310 and the flash crystal 110 are rotated so that the third incident surface 311 is located on the upper side through the rotation control unit. . At this time, radiation is incident through the first incident surface 111 having an area of 3×3 mm ² , and the scintillation crystal 110 emits a scintillation signal corresponding to the incident radiation. The optical sensor 120 converts the emitted flash signal into an electrical signal, and the optical sensor 120 transmits the converted electrical signal to the signal processing unit 200 .

When the user wants to acquire a high-resolution image, the driving member 133 is controlled to rotate the sub-crystal 310 so that the fourth incident surface 312 is located on the upper side through the rotation control unit. Here, radiation is incident on the fourth incident surface 312 of 3×1 mm ² having a smaller area than the second incident surface 112 , and the optical signal generated by the sub-crystals 310 is input to the photosensor 120 , and , the optical sensor 120 converts an electrical signal corresponding to the corresponding optical signal and transmits it to the signal processing unit 200 . Here, the LYSO-GAGG classification is applied to the conventional pulse shape discrimination method.

As described above, the rotational radiation detector 300 providing multiple resolution of the present invention scintillates the sub-crystal 310 having the fourth incident surface 312 with a smaller area than the second incident surface 112 . Since it is installed at 110, it is possible to acquire a higher-resolution image, and it is possible to determine the reaction depth even in the normal-resolution image acquisition mode.

Description of the presented embodiments is provided to enable any person skilled in the art to use or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

100: Rotating radiation detector with multiple resolutions
110: flash crystal
111: first incident surface
112: 2nd incident surface
120: optical sensor
121: adhesive layer
122: fixed block
130: rotation unit
131: frame
132: rotation bracket
133: driving member

Claims (17)

a scintillation crystal that detects radiation emitted from the radiation emitting unit and incident on the outer peripheral surface and converts it into a scintillation signal;
an optical sensor for converting the flash signal of the flash crystal into an electrical signal; and
a rotation unit installed on the flash crystal to rotate the flash crystal so that the incident surface of the flash crystal on which radiation is incident can be changed; and
The scintillation crystal is to which the radiation is incident, and a first incident surface is spaced apart from the first incident surface, and a second incident surface is formed to have an area different from the area of the first incident surface,
Rotating radiation detector with multiple resolutions.
delete According to claim 1,
The rotation unit rotates the scintillation crystal so that the radiation is incident on any one of the first and second incident surfaces.
Rotating radiation detector with multiple resolutions.
According to claim 1,
The scintillation crystal is formed in a hexahedral shape,
Rotating radiation detector with multiple resolutions.
5. The method of claim 4,
The scintillation crystal is formed such that the first and second incident surfaces are orthogonal to each other,
Rotating radiation detector with multiple resolutions.
According to claim 1,
The photosensor is installed in the scintillation crystal at a position spaced apart from the first and second incident surfaces,
Rotating radiation detector with multiple resolutions.
According to claim 1,
The optical sensor is installed on an outer peripheral surface opposite to the first incident surface with respect to the center of the scintillation crystal,
Rotating radiation detector with multiple resolutions.
8. The method of claim 7,
The photosensor is fixed to the outer peripheral surface of the scintillation crystal by an optical grease or adhesive,
Rotating radiation detector with multiple resolutions.
According to claim 1,
The first and second incident surfaces and a reflector installed to surround the outer circumferential surface of the flash crystal excluding the installation surface on which the photosensor is installed and reflecting the flash signal;
Rotating radiation detector with multiple resolutions.
According to claim 1,
Further comprising; a shielding sheet formed to surround the outer peripheral surface of the optical sensor to reduce radiation loss generated when the scintillation crystal is rotated to shield the radiation;
Rotating radiation detector with multiple resolutions.
4. The method of claim 3,
The rotating unit is
frame;
a rotation bracket that is rotatably installed on the frame and has the scintillation crystal or optical sensor installed on one side;
and a driving member installed on the rotation bracket to rotate the rotation bracket;
Rotating radiation detector with multiple resolutions.
12. The method of claim 11,
The rotation unit further includes a rotation control unit for controlling the driving member so that the scintillation crystal is set so that the incident surface selected by the user so that the radiation is incident among the first and second incident surfaces is opposite to the radiation emitting unit; ,
Rotating radiation detector with multiple resolutions.
According to claim 1,
The scintillation crystals are BGO (Bismuth Germanate), LSO (Lutetium Oxyorthosilicate), LYSO (Lutetium Yttrium Oxyorthosilicate), LuAP (Lutetium Aluminum Perovskite), LuYAP (Lutetium Yttrium Aluminum Perovskite), LaBr3 (Lanthanum Iodide), LuI3 (Lanthanum Bromide), GSO(Gadolinium oxyorthosilicate), LGSO(lutetium gadolinium oxyorthosilicate), LuAG(Lutetium aluminum garnet), GAGG(Gd3Al2Ga3 O123Al2Ga3O12), LFS(Lutetium Fine Silicate), NaI(Tl) (Thallium doped Sodium) (Thallium doped Sodium) activated Cesium Iodide) consisting of at least one of
Rotating radiation detector with multiple resolutions.
According to claim 1,
The optical sensor consists of at least one of a PN diode, a PIN diode, an Avalanche Photo Diode (APD), GAPD, and PMT,
Rotating radiation detector with multiple resolutions.
6. The method of claim 5,
Sub-crystals installed on the first incident surface of the scintillation crystal, the sub-crystal having an incident surface of a different area from the second incident surface; provided,
Rotating radiation detector with multiple resolutions.
16. The method of claim 15,
The sub-crystal is formed with a third incident surface opposite to the contact surface in contact with the first incident surface with respect to the center, and is adjacent to the second incident surface so that radiation incident to the second incident surface is incident. , a fourth incident surface is formed on an outer peripheral surface extending parallel to the second incident surface to have an area different from that of the second incident surface,
Rotating radiation detector with multiple resolutions.
17. The method of claim 16,
The sub-crystal is formed in a hexahedral shape, and the third incident surface is formed to have an area corresponding to the area of the first incident surface,
Rotating radiation detector with multiple resolutions.

Images