JP2016128764A - Radiation detector module and radiation detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation detector module that allows for improving sensitivity characteristics and reducing the size thereof even if sloped portions of a scintillator layer are positioned in the vicinity of an effective pixel region, and to provide a radiation detector.SOLUTION: An embodiment of the radiation detector module includes; a substrate having a plurality of photoelectric conversion elements disposed thereon; a scintillator layer that is provided on top of an effective pixel region having the plurality of photoelectric conversion elements therein to convert radiation into fluorescence; and a reflective layer that is provided on top of the scintillator layer to reflect the fluorescence toward the effective pixels region. The scintillator layer comprises an aggregate of a plurality of columnar crystals. Each peripheral edge face of the scintillator layer is sloped in a direction away from the center of the scintillator layer with increasing distance toward outside. Peripheral edge portions of the reflective layer are located on top of the peripheral edge faces of the scintillator layer.SELECTED DRAWING: Figure 3

Description

  Embodiments described herein relate generally to a radiation detector module and a radiation detector.

The radiation detector module incorporated in the radiation detector includes a substrate formed of a light-transmitting material such as glass, a plurality of photoelectric conversion units provided in a matrix on the substrate, and a plurality of photoelectric conversion units. A scintillator layer that covers and converts radiation into visible light, that is, fluorescence, a reflective layer provided on the scintillator layer, a moisture barrier that covers the scintillator layer and the reflective layer, and the like are provided.
The scintillator layer is provided so as to cover an area (effective pixel area) where a plurality of photoelectric conversion units are provided.
Here, when the scintillator layer is formed using a vacuum deposition method, an inclined portion is formed in the peripheral portion of the scintillator layer. The thickness dimension of the inclined portion is gradually reduced toward the outside of the scintillator layer. Therefore, the inclined portion is thinner than the portion in the central region of the scintillator layer. Therefore, if there is an inclined portion above the effective pixel region or at a position close to the effective pixel region, the sensitivity characteristic may be deteriorated.
In this case, if the inclined portion is provided at a position away from the effective pixel region, it is possible to suppress deterioration of sensitivity characteristics. However, if the inclined portion is provided at a position away from the effective pixel region, the radiation detector module becomes large, and the radiation detector may not be miniaturized.
Further, if the reflective layer is provided so as to cover the entire scintillator layer, the reflective layer may be formed on the surface of the substrate beyond the inclined portion of the scintillator layer when the reflective layer is formed. When the reflective layer is formed even on the surface of the substrate, the adhesive strength when the moisture-proof body is bonded to the substrate may be reduced. In this case, if the adhesion position of the moisture-proof body is set to the outside in consideration of the formation of the reflective layer up to the surface of the substrate, the radiation detector module may become large and the radiation detector may not be miniaturized.
Therefore, even if there is an inclined portion of the scintillator layer at a position close to the effective pixel region, the sensitivity characteristic can be improved, and the radiation detector module can be downsized, and thus the radiation detector can be downsized. Development of a radiation detector module and a radiation detector has been desired.

Japanese Patent No. 5317675

  A problem to be solved by the present invention is a radiation detector module that can improve sensitivity characteristics even if there is an inclined portion of the scintillator layer at a position close to the effective pixel region, and can be downsized. And providing a radiation detector.

The radiation detector module according to the embodiment includes a substrate provided with a plurality of photoelectric conversion elements, a scintillator layer provided on the effective pixel region provided with the plurality of photoelectric conversion elements, and converts radiation into fluorescence. And a reflection layer provided on the scintillator layer and reflecting the fluorescence toward the effective pixel region.
The scintillator layer is an aggregate of a plurality of columnar crystals. The peripheral end surface of the scintillator layer is inclined in a direction away from the center of the scintillator layer as it goes to the outside of the scintillator layer. A peripheral end portion of the reflective layer is provided on the peripheral end surface of the scintillator layer.

1 is a schematic perspective view for illustrating an X-ray detector module 11 and an X-ray detector 1 according to the present embodiment. 2 is a block diagram of the X-ray detector 1. FIG. FIG. 3 is a schematic cross-sectional view for illustrating the vicinity of a peripheral end portion of an X-ray detector module 11 according to the present embodiment. 2 is a circuit diagram of an X-ray detector module 11. FIG. (A) is a schematic plan view for illustrating the moisture-proof body 7. (B) is a schematic side view for illustrating the moisture-proof body 7. It is a schematic cross section for illustrating the peripheral part vicinity of the module 110 for X-ray detectors concerning a comparative example.

Hereinafter, embodiments will be illustrated with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.
The radiation detector module and the radiation detector according to the present embodiment can be applied to various types of radiation such as γ rays in addition to X-rays. Here, as an example, a case of X-rays as a representative example of radiation will be described as an example. Therefore, by replacing “X-ray” in the following embodiments with “other radiation”, the present invention can be applied to other radiation.

The X-ray detector 1 that is a radiation detector can be used for general medical use, for example. However, the use is not limited as long as radiation detection (X-ray detection) is performed.
In addition, arrows X, Y, and Z in the drawings represent three directions orthogonal to each other. For example, the direction perpendicular to the main surface of the substrate 2a is taken as the Z direction. In addition, one direction in a plane parallel to the main surface of the substrate 2a is defined as a Y direction, and a direction perpendicular to the Z direction and the Y direction is defined as an X direction.

FIG. 1 is a schematic perspective view for illustrating an X-ray detector module 11 and an X-ray detector 1 according to the present embodiment.
In FIG. 1, the reflection layer 6 and the moisture-proof body 7 are omitted to avoid complication.
FIG. 2 is a block diagram of the X-ray detector 1.
FIG. 3 is a schematic cross-sectional view for illustrating the vicinity of the peripheral end of the X-ray detector module 11 according to the present embodiment.
FIG. 4 is a circuit diagram of the X-ray detector module 11.
FIG. 5A is a schematic plan view for illustrating the moisture-proof body 7. FIG. 5B is a schematic side view for illustrating the moisture-proof body 7.

First, the X-ray detector module 11 according to the present embodiment will be described.
As shown in FIG. 3, the X-ray detector module 11 is provided with an array substrate 2, a scintillator layer 5, a reflective layer 6, a moisture-proof body 7, and an adhesive portion 8.

The array substrate 2 converts the fluorescence (visible light) converted from the X-rays by the scintillator layer 5 into an electrical signal.
The array substrate 2 includes a substrate 2a, a photoelectric conversion unit 2b, a control line (or gate line) 2c1, a data line (or signal line) 2c2, a wiring pad 2d1, a wiring pad 2d2, and a protective layer 2f.

The substrate 2a has a plate shape and is made of a translucent material such as glass.
A plurality of photoelectric conversion units 2b are provided on one surface of the substrate 2a.
The photoelectric conversion unit 2b has a rectangular shape and is provided in each of a plurality of regions defined by a plurality of control lines 2c1 and a plurality of data lines 2c2. The plurality of photoelectric conversion units 2b are arranged in a matrix.
One photoelectric conversion unit 2b corresponds to one pixel.
An area where the plurality of photoelectric conversion units 2b are provided is an effective pixel area A. (See Figure 3)

Each of the plurality of photoelectric conversion units 2b is provided with a photoelectric conversion element 2b1 and a thin film transistor (TFT) 2b2 which is a switching element.
Further, as shown in FIG. 4, a storage capacitor 2b3 for storing the signal charge converted in the photoelectric conversion element 2b1 can be provided. The storage capacitor 2b3 has, for example, a rectangular flat plate shape and can be provided under each thin film transistor 2b2. However, depending on the capacitance of the photoelectric conversion element 2b1, the photoelectric conversion element 2b1 can also serve as the storage capacitor 2b3.

The photoelectric conversion element 2b1 can be, for example, a photodiode.
The thin film transistor 2b2 performs switching between accumulation and emission of electric charges generated when fluorescence enters the photoelectric conversion element 2b1. The thin film transistor 2b2 can include a semiconductor material such as amorphous silicon (a-Si) or polysilicon (P-Si). The thin film transistor 2b2 includes a gate electrode 2b2a, a source electrode 2b2b, and a drain electrode 2b2c. Gate electrode 2b2a of thin film transistor 2b2 is electrically connected to corresponding control line 2c1. The source electrode 2b2b of the thin film transistor 2b2 is electrically connected to the corresponding data line 2c2. The drain electrode 2b2c of the thin film transistor 2b2 is electrically connected to the corresponding photoelectric conversion element 2b1 and the storage capacitor 2b3.

A plurality of control lines 2c1 are provided in parallel with each other at a predetermined interval. The control line 2c1 extends in the X direction (for example, the row direction).
The plurality of control lines 2c1 are electrically connected to each of the plurality of wiring pads 2d1 provided near the periphery of the substrate 2a. One end of each of a plurality of wirings provided on the flexible printed circuit board 12a is electrically connected to each of the plurality of wiring pads 2d1. The other ends of the plurality of wirings provided on the flexible printed circuit board 12a are electrically connected to the control circuit 31 provided on the signal processing unit 3, respectively.

A plurality of data lines 2c2 are provided in parallel with each other at a predetermined interval. The data line 2c2 extends in the Y direction (for example, the column direction) orthogonal to the X direction.
The plurality of data lines 2c2 are electrically connected to the plurality of wiring pads 2d2 provided near the periphery of the substrate 2a. One end of each of a plurality of wirings provided on the flexible printed circuit board 12b is electrically connected to each of the plurality of wiring pads 2d2. The other ends of the plurality of wirings provided on the flexible printed circuit board 12b are electrically connected to the amplification / conversion circuit 32 provided on the signal processing unit 3, respectively.
The control line 2c1 and the data line 2c2 can be formed using a low resistance metal such as aluminum or chromium.

A bias line (not shown) that is electrically connected to the plurality of photoelectric conversion elements 2b1 can also be provided.
A bias line (not shown) can be extended in the same direction as the data line 2c2, for example.

The protective layer 2f covers the photoelectric conversion unit 2b, the control line 2c1, the data line 2c2, and the like.
The protective layer 2f includes, for example, at least one of an oxide insulating material, a nitride insulating material, an oxynitride insulating material, and a resin material.
Examples of the oxide insulating material include silicon oxide and aluminum oxide.
Examples of the nitride insulating material include silicon nitride and aluminum nitride.
The oxynitride insulating material is, for example, silicon oxynitride.
The resin material is, for example, an acrylic resin.

The scintillator layer 5 is provided on the plurality of photoelectric conversion units 2b (effective pixel areas A), and converts incident X-rays into fluorescence, that is, visible light.
The scintillator layer 5 can be formed using, for example, cesium iodide (CsI): thallium (Tl) or sodium iodide (NaI): thallium (Tl). In this case, if the scintillator layer 5 is formed using a vacuum deposition method or the like, the scintillator layer 5 made of an aggregate of a plurality of columnar crystals is formed.
Here, when the scintillator layer 5 is formed using a vacuum deposition method or the like, an inclined portion 5 a is formed at the peripheral portion of the scintillator layer 5 as shown in FIG. 3. The thickness dimension of the inclined portion 5 a is gradually reduced toward the outside of the scintillator layer 5. Therefore, the inclined portion 5 a is thinner than the portion in the central region of the scintillator layer 5.
A side surface of the inclined portion 5 a, that is, a peripheral end surface 5 a 1 of the scintillator layer 5 is inclined in a direction away from the center of the scintillator layer 5 toward the outside of the scintillator layer 5.
In plan view (as viewed from the Z direction), the peripheral end surface 5a1 of the scintillator layer 5 is provided outside the effective pixel region A.

The reflective layer 6 is provided in order to improve the use efficiency of fluorescence and improve sensitivity characteristics. In other words, the reflection layer 6 reflects the light emitted from the scintillator layer 5 toward the side opposite to the effective pixel region A side so as to go toward the effective pixel region A side.
The reflective layer 6 is provided on the surface side (X-ray incident surface side) of the scintillator layer 5.
In this case, the peripheral end 6 a of the reflective layer 6 is provided on the peripheral end surface 5 a 1 of the scintillator layer 5. The peripheral end 6a of the reflective layer 6 is provided between the end 5a1a on the substrate 2a side of the peripheral end surface 5a1 and the end 5a1b on the opposite side of the peripheral end surface 5a1 from the substrate 2a side.
Details regarding the positional relationship between the inclined portion 5a and the effective pixel region A and the positional relationship between the inclined portion 5a and the reflective layer 6 will be described later.

The reflective layer 6 can be formed, for example, by applying a resin containing light scattering particles such as titanium oxide (TiO ₂ ) on the scintillator layer 5.
In this case, the reflective layer 6 can be formed by applying a material prepared by mixing a submicron powder made of titanium oxide, a binder resin, and a solvent onto the scintillator layer 5 and drying it. .

The moisture-proof body 7 is provided in order to suppress deterioration of the characteristics of the scintillator layer 5 and the reflective layer 6 due to water vapor contained in the air.
As shown in FIGS. 5A and 5B, the moisture-proof body 7 has a hat shape and includes a surface portion 7 a, a peripheral surface portion 7 b, and a collar portion 7 c.
The moisture-proof body 7 can be formed by integrally forming a surface portion 7a, a peripheral surface portion 7b, and a collar portion 7c.

The moisture-proof body 7 can be formed from a material having a small moisture permeability coefficient.
The moisture-proof body 7 is made of, for example, a low moisture-permeable and moisture-proof material in which aluminum, an aluminum alloy, a resin layer and an inorganic material (light metal such as aluminum, ceramic material such as SiO ₂ , SiON, Al ₂ O ₃ ) layer are laminated. Can be formed.
Further, the thickness dimension of the moisture-proof body 7 can be determined in consideration of X-ray absorption and rigidity. In this case, if the thickness dimension of the moisture-proof body 7 is increased too much, the absorption of X-rays increases too much. If the thickness dimension of the moisture-proof body 7 is too small, the rigidity is lowered and it is easy to break.
The moisture-proof body 7 can be formed, for example, by press-molding an aluminum foil having a thickness dimension of 0.1 mm.

The surface portion 7 a faces the surface side (X-ray incident surface side) of the scintillator layer 5.
The peripheral surface portion 7b is provided so as to surround the periphery of the surface portion 7a. The peripheral surface portion 7b extends from the peripheral edge of the surface portion 7a to the substrate 2a side.
A scintillator layer 5 and a reflective layer 6 are provided inside the space formed by the surface portion 7a and the peripheral surface portion 7b. There may be a gap between the surface portion 7a and the peripheral surface portion 7b and the reflective layer 6 or the scintillator layer 5, or the surface portion 7a and the peripheral surface portion 7b and the reflective layer 6 or the scintillator layer 5 are in contact with each other. May be.

The collar part 7c is provided so that the edge part on the opposite side to the surface part 7a side of the surrounding surface part 7b may be enclosed. The collar part 7c is extended toward the outer side from the edge part of the surrounding surface part 7b. The collar portion 7c has an annular shape and is provided so as to be parallel to the surface of the substrate 2a on the side where the photoelectric conversion portion 2b is provided.
The collar portion 7 c is bonded to the peripheral area of the array substrate 2 (outside the effective pixel area A) via the adhesive layer 8.
If the hat-shaped moisture-proof body 7 is used, high moisture-proof performance can be obtained. In this case, since the moisture-proof body 7 is made of aluminum or the like, the permeation of water vapor is extremely small.

The adhesive layer 8 is provided between the collar portion 7 c and the array substrate 2. The adhesive layer 8 is formed by curing, for example, an ultraviolet curable adhesive.
Moreover, it is preferable to make the moisture permeability (water vapor permeability) of the adhesive layer 8 as small as possible. In this case, if 70 wt% or more of inorganic material talc (talc: Mg ₃ Si ₄ O ₁₀ (OH) ₂ ) is added to the ultraviolet curable resin, the moisture permeability coefficient of the adhesive layer 8 can be greatly reduced. it can.

Next, the positional relationship between the inclined portion 5a and the effective pixel area A and the positional relationship between the inclined portion 5a and the reflective layer 6 will be further described.
FIG. 6 is a schematic cross-sectional view for illustrating the vicinity of the peripheral end portion of the X-ray detector module 110 according to the comparative example.
As shown in FIG. 6, the X-ray detector module 110 according to the comparative example is also provided with the array substrate 2, the scintillator layer 115, the reflective layer 116, the moisture-proof body 7, and the bonding portion 8.

However, a part of the inclined portion 115 a of the scintillator layer 115 is provided on the effective pixel region A.
The thickness of the inclined portion 115a is gradually reduced toward the outside of the scintillator layer 115. That is, the inclined portion 115a is thinner than the portion in the central region of the scintillator layer 115. As the scintillator layer 115 becomes thinner, the amount of fluorescence decreases.
For this reason, if there is the inclined portion 115a above the effective pixel area A or at a position close to the effective pixel area A, the sensitivity characteristic may be deteriorated.

  In this case, if the inclined portion 115a is provided at a position away from the effective pixel region A, it is possible to suppress deterioration of sensitivity characteristics. However, if the inclined portion 115a is provided at a position distant from the effective pixel region A, the X-ray detector module 110 becomes large and the X-ray detector may not be miniaturized.

Further, if the reflective layer 116 is provided so as to cover the entire scintillator layer 115, light directed toward the peripheral end surface of the inclined portion 115a can be reflected, so that deterioration of sensitivity characteristics can be suppressed.
However, the reflective layer 116 is formed by applying a material prepared by mixing light scattering particles, a binder resin, and a solvent onto the scintillator layer 115 and drying it. That is, the material of the reflective layer 116 has fluidity. Therefore, when the reflective layer 116 is formed, the material of the reflective layer 116 may flow out to the surface of the substrate 2a beyond the inclined portion 115a of the scintillator layer 115. When the reflective layer 116 is formed even on the surface of the substrate 2a, the adhesive layer 8 is formed on the reflective layer 116, so that the adhesive strength in the adhesive layer 8 may be reduced. In this case, considering that the material of the reflective layer 116 flows out to the surface of the substrate 2a, if the adhesion position of the moisture-proof body 7 is set to the outside, the substrate 2a, and consequently the X-ray detector module 110 becomes large, and X-ray detection is performed. There is a risk that it will not be possible to reduce the size of the vessel.

Therefore, in the X-ray detector module 11 according to the present embodiment, the peripheral end surface 5a1 of the scintillator layer 5 is provided outside the effective pixel region A, and the peripheral end portion 6a of the reflective layer 6 is disposed on the peripheral end surface 5a1. I am trying to provide it.
In order to reduce the size of the X-ray detector module 11, the peripheral end surface 5a1 of the scintillator layer 5 is close to the effective pixel region A, and the width dimension of the peripheral end surface 5a1 (the end portions 5a1b and 5a1a in plan view). It is desirable to reduce the distance between
As described above, the scintillator layer 5 is an aggregate of a plurality of columnar crystals. There is a gap between the columnar crystals. In this case, when the material of the reflective layer 6 having fluidity is applied on the peripheral end surface 5a1, a part of the applied material of the reflective layer 6 enters between the columnar crystals. Therefore, the reflective layer 6 is also provided between the columnar crystals on the peripheral end surface 5 a 1 of the scintillator layer 5.
Since the outflow resistance with respect to the material of the reflective layer 6 having fluidity is increased on the peripheral end surface 5a1 of the scintillator layer 5, even if the peripheral end portion 6a of the reflective layer 6 is provided on the peripheral end surface 5a1, it is applied. It is possible to suppress the material of the reflective layer 6 from flowing out to the surface of the substrate 2 a beyond the inclined portion 5 a of the scintillator layer 5.
As a result, an increase in the distance between the scintillator layer 5 and the adhesive layer 8 can be suppressed.

And if the peripheral edge part 6a of the reflection layer 6 is provided on the peripheral edge surface 5a1, the light which goes to the peripheral edge surface 5a1 can be reflected to the effective pixel area A side.
Therefore, even if there is the inclined portion 5a at a position close to the effective pixel region A, it is possible to suppress deterioration in sensitivity characteristics.
As a result, the sensitivity characteristic can be improved even if the inclined portion 5a of the scintillator layer 5 is located in the vicinity of the effective pixel region A, and the X-ray detector module 11 can be downsized, and thus the X-ray detector 1 can be improved. Can be miniaturized.

Next, returning to FIGS. 1 and 2, the X-ray detector 1 according to the present embodiment will be described.
As shown in FIG. 1, the X-ray detector 1 is provided with an X-ray detector module 11, a signal processing unit 3, and an image transmission unit 4.
The signal processing unit 3 is provided on the side of the substrate 2a opposite to the side on which the photoelectric conversion unit 2b is provided.
The signal processing unit 3 converts image data signals from the plurality of photoelectric conversion elements 2b1 provided in the X-ray detector module 11 into digital signals.

The signal processing unit 3 is provided with a control circuit 31 and an amplification / conversion circuit 32.
As shown in FIG. 2, the control circuit 31 includes a plurality of gate drivers 31a and a row selection circuit 31b.
The gate driver 31a applies the control signal S1 to the corresponding control line 2c1.
The row selection circuit 31b sends an external control signal S1 to the corresponding gate driver 31a in accordance with the scanning direction of the X-ray image.
For example, the control circuit 31 sequentially applies the control signal S1 to each control line 2c1 via the flexible printed board 12a and the control line 2c1. The thin film transistor 2b2 is turned on by the control signal S1 applied to the control line 2c1, and the signal charge (image data signal S2) from the photoelectric conversion element 2b1 can be received.

The amplification / conversion circuit 32 includes a plurality of integrating amplifiers 32a and a plurality of A / D converters 32b.
The integrating amplifier 32a amplifies and outputs the image data signal S2 from each photoelectric conversion element 2b1 via the data line 2c2, the wiring pad 2d2, and the flexible printed board 12b. The image data signal S2 output from the integrating amplifier 32a is parallel / serial converted and input to the A / D converter 32b.
The A / D converter 32b converts the input image data signal S2 (analog signal) into a digital signal.

As shown in FIG. 1, the image transmission unit 4 is electrically connected to the amplification / conversion circuit 32 of the signal processing unit 3 via a wiring 4 a. The image transmission unit 4 may be integrated with the signal processing unit 3.
The image transmission unit 4 synthesizes an X-ray image based on the image data signal S2 converted into a digital signal by the plurality of A / D converters 32b. The combined X-ray image data is output from the image transmission unit 4 to an external device.
In addition, the X-ray detector 1 can include a housing (not shown) that houses the X-ray detector module 11, the signal processing unit 3, and the image transmission unit 4.

  As mentioned above, although several embodiment of this invention was illustrated, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, changes, and the like can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and equivalents thereof. Further, the above-described embodiments can be implemented in combination with each other.

1 X-ray detector, 2 array substrate, 2a substrate, 2b photoelectric conversion unit, 2b1 photoelectric conversion element, 2c1 control line, 2c2 data line, 2d1 wiring pad, 2d2 wiring pad, 3 signal processing unit, 4 image transmission unit, 5 Scintillator layer, 5a inclined part, 5a1 peripheral end face, 5a1a end part, 5a1b end part, 6 reflective layer, 6a peripheral end part, 7 moisture-proof body, 8 adhesive part, 11 X-ray detector module

Claims (4)

A substrate provided with a plurality of photoelectric conversion elements;
A scintillator layer that is provided on the effective pixel region provided with the plurality of photoelectric conversion elements and converts radiation into fluorescence;
A reflective layer that is provided on the scintillator layer and reflects the fluorescence toward the effective pixel region;
With
The scintillator layer is an aggregate of a plurality of columnar crystals,
The peripheral end surface of the scintillator layer is inclined in a direction away from the center of the scintillator layer as it goes to the outside of the scintillator layer,
The peripheral edge part of the said reflection layer is a module for radiation detectors provided on the said peripheral end surface of the said scintillator layer.   The radiation detector module according to claim 1, wherein the peripheral end surface of the scintillator layer is provided outside the effective pixel region in a plan view.   The radiation detector module according to claim 1, wherein the reflection layer is also provided between the plurality of columnar crystals on the peripheral end face of the scintillator layer. The module for radiation detectors according to any one of claims 1 to 3,
A signal processing unit for converting image data signals from a plurality of photoelectric conversion elements provided in the radiation detector module into digital signals;
An image transmission unit that synthesizes a radiographic image based on the digital signal;
Radiation detector equipped with.

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