JP2001141897A - Stiumulable phosphor sheet and radiation image recording and regeneration method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stimulable phosphor sheet with high sensitivity, effectively preventable of scattered radiation, spreading of exposure spot and a radiation image recording and regeneration method. SOLUTION: A stimulable phosphor sheet used for radiation imag recording and regeneration method is composed of striped or grid radiation absorbing isolation wall 11 finely separating the stimulable phosphor sheet one- dimensionally or two-dimensionally along the plane direction and a stimulable phosphor charging region 13 separated by the isolation wall. The stimulable phosphor sheet is coated with an excited light reflection film 12 whose scattering length for excited light is within 0.05 μm and 20 μm and shorter than the scattering length of the stimulable phosphor charging region 13 and a radiation image recording and regeneration using it's method.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stimulable phosphor sheet used for a radiation image recording / reproducing method utilizing stimulable luminescence of a stimulable phosphor and a radiation image recording / reproducing method using the same.

[0002]

2. Description of the Related Art As an alternative to radiography using a combination of a radiographic film and an intensifying screen,
A radiation image recording / reproducing method using a stimulable phosphor (also referred to as a radiation image conversion method) is known. This method uses a stimulable phosphor sheet containing a stimulable phosphor (also referred to as a radiation image conversion panel), and irradiates radiation transmitted through an object or emitted from an object to the sheet. The stimulable phosphor is absorbed by the stimulable phosphor, and then the stimulable phosphor is irradiated with an electromagnetic wave (excitation light) such as visible light or infrared light to excite the stimulable phosphor. A method in which the stored radiation energy is emitted as fluorescence (stimulated emission light), the fluorescence is read photoelectrically and converted into an electric signal, and a radiation image of a subject or a subject is reproduced as a visible image from the electric signal. It is. The stimulable phosphor sheet that has been read is erased of radiation energy remaining in the stimulable phosphor, and is repeatedly used in a similar radiation image recording / reproducing method.

The stimulable phosphor sheet used in the above-described radiation image recording / reproducing method generally has a basic structure in which a support is provided on a lower surface and a protective film is provided on an upper surface. A stimulable phosphor sheet (referred to as a stimulable phosphor layer in a radiation image conversion panel) usually comprises stimulable phosphor particles and a binder containing and supporting the particles in a dispersed state. However, as the stimulable phosphor sheet, a sheet made of an aggregate of the stimulable phosphor without a binder formed by a vapor deposition method or a sintering method, or an aggregate of the stimulable phosphor is used. There is also known a material in which a polymer substance is permeated into a gap between the two. Any of these stimulable phosphor sheets can be used in the above-described radiation image recording / reproducing method.

It is desirable that the stimulable phosphor sheet has high sensitivity and can reproduce a high-quality radiation image. That is, as a typical application of the radiation image recording / reproducing method, there is formation of a radiation image for medical diagnosis using X-rays. In this application, particularly, high image quality (particularly high resolution This is because it is desired to obtain a radiation image having a high sharpness that leads to the following.

When recording (photographing) a radiation image in the radiation image recording / reproducing method, a part of radiation such as X-rays applied to the subject is scattered by the subject, and the scattered radiation is transmitted through the subject (directly). As in the case of (radiation), the radiation image is incident on the stimulable phosphor sheet and contributes to the formation of a latent image, so that the obtained radiation image tends to have low image quality such as resolution. In order to remove this scattered radiation, Japanese Patent Application Laid-Open No. 62-9 / 1987
Nos. 0599 and 62-90600 disclose Pb on the surface of a radiation image conversion panel or in a stimulable phosphor layer.
It is described that a mesh-like grid (grid) made of a radiation-absorbing substance, such as, is provided. However, in such a structure, the absorption of excitation light and stimulated emission light by the metal grid is not negligibly high. That is, even if the metal grid is mirror-finished, its light reflectance is 8
It is about 5%, and in the phosphor region surrounded by the metal grid, both the excitation light and the stimulated emission light travel while repeating multiple reflections. As a result, the light loss due to the absorption of the metal grid greatly exceeds 15%. become. Therefore, the installation of the metal grid causes a significant decrease in sensitivity.

When measuring the intensity of radiation radiated from a number of minute point sources close to each other as in autoradiography or imaging the radiation, the exposure spot depends on the range of the source. There is a problem in that the spots that are close to each other due to the spread are poorly separated from each other, and the resolution is reduced. Such a decrease in resolution can be prevented by providing the metal grid, but a decrease in sensitivity is inevitable.

On the other hand, Japanese Patent Application No. 11-689 filed by the present applicant
No. 66 describes sharpness due to the fact that excitation light applied to a stimulable phosphor sheet is diffused inside the sheet (particularly in the plane direction) during reproduction (reading) of a radiation image. In order to prevent the image quality from deteriorating, partition walls having a short scattering length with respect to excitation light (in the range of 0.05 μm to 20 μm) and a long absorption length with respect to stimulated emission light (not less than 1000 μm) are arranged in the plane of the stimulable phosphor sheet. It has been proposed to provide a subdivision along the line. According to this stimulable phosphor sheet, it is possible to improve the resolution while suppressing the decrease in sensitivity, but it is not possible to prevent the spread of the exposure spot due to scattered radiation or the range of the radiation source.

[0008]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stimulable phosphor sheet which provides a radiation image with high sensitivity and high image quality, particularly high resolution. In particular, the present invention provides a stimulable phosphor sheet capable of removing adverse effects due to scattered radiation and effectively preventing spread of an exposure spot without lowering sensitivity. Another object of the present invention is to provide a radiation image recording / reproducing method which provides a high-sensitivity, high-quality radiation image.

[0009]

The present inventor has studied a stimulable phosphor sheet provided with a grid (partition) made of a radiation absorbing substance for the purpose of removing scattered radiation. It has been found that by covering with an excitation light reflective thin film having a specific scattering length and absorption length, absorption of excitation light and stimulated emission light by a grid can be effectively prevented. In other words, by providing a thin film having a short scattering length for excitation light and a high reflectance for the excitation light and a long absorption length for the stimulated emission light and a low absorption rate on the partition wall surface, the excitation light and the emission light are provided. 95% reflectance
As described above, the absorption of the excitation light and the emission light by the partition walls can be suppressed as much as possible, and a decrease in the luminous efficiency can be prevented. As a result, a high-resolution radiographic image was obtained while suppressing a decrease in sensitivity due to the presence of the partition walls.

[0010] Further, the present inventor, when taking and reading a radiation image using the above-mentioned stimulable phosphor sheet, makes the stimulable phosphor so that the radiation-absorbing partition wall is parallel to the incident radiation. Bending the body sheet into a curved surface,
Or, by irradiating radiation using a stimulable phosphor sheet with inclined partition walls, or by detecting stimulable luminescent light from both sides of the sheet, it is found that a high-resolution image can be obtained without reducing sensitivity. And a radiation image recording / reproducing method according to the present invention.

According to the present invention, after a radiation image is recorded as a latent image, stimulating light is emitted from the latent image by irradiating excitation light, and then the stimulating light is electrically processed. A stimulable phosphor sheet used in a radiation image recording / reproducing method comprising reproducing a radiation image by:
The stimulable phosphor sheet comprises a striped or lattice-shaped radiation-absorbing partition which subdivides the stimulable phosphor sheet in a one-dimensional or two-dimensional direction along a plane direction, and a stimulable phosphor-filled region partitioned by the partition. And the radiation-absorbing partition walls are coated with an excitation light-reflective thin film having a scattering length for excitation light in the range of 0.05 μm to 20 μm and shorter than the scattering length of the stimulable phosphor-filled region. A stimulable phosphor sheet.

In the present invention, the scattering length for the excitation light means an average distance that the excitation light travels straight before being scattered once, and the shorter the scattering length, the higher the light scattering property. Further, the absorption length for the stimulated emission light means an average free distance until the emission light is absorbed, and the longer the absorption length, the lower the light absorption. The light scattering length and the light absorption length were obtained from the measured values of the transmittance measured by the following method.
Is a value calculated by a calculation method based on the theory of.

First, three or more film samples having the same composition and different thicknesses are prepared for each of the partition walls and the stimulable phosphor-filled region of the stimulable phosphor sheet to be measured. The thickness (μm) and transmittance (%) of the film sample are measured. This transmittance can be measured by a usual spectrophotometer. The measurement wavelength needs to be the wavelength of the excitation light and the wavelength of the stimulating light of the stimulable phosphor contained in the stimulable phosphor sheet.

Next, using the measured values of the thickness (μm) and the transmittance (%) of the obtained film, the light scattering length and the light absorption length are calculated based on Kubelka's theory. The thickness of the film is d μm, the scattering length of the film is 1 / αμm, and the absorption length of the film is 1 / β μm. Consider a light intensity distribution I (Z) at a depth Z. The component i (Z) which goes from the front to the back of the film and the component j which goes from the back to the front of the film
(Z). That is, I (Z) = i
(Z) + j (Z). The increase / decrease of the light intensity due to the scattering and absorption in the film having a small thickness dz at an arbitrary depth Z may be obtained by solving the following simultaneous differential equations (1) and (2) according to Kubelka's theory.

Di / dz =-(β + α) i + αj (1) dj / dz = (β + α) j-αi (2)

Γ ² = β (β + 2α), ξ = (α + β−
Assuming that γ) / α, η = (α + β + γ) / α, and K and L are integration constants, general solutions for i and j in the above simultaneous differential equations are respectively as follows.

I (Z) = Ke- ^γZ + ^LeγZ j (Z) = Kξe- ^γZ + ^LηeγZ

The transmittance T of a film having a thickness d is given by T = i (d) / i (0). When the transmittance is measured by using the film alone, there is no return light (j (d) ) = 0), the transmittance T can be expressed by the following equation (3) as a function of the thickness d.

T (d) = (η−ξ) / ( ^{ηe γZ−} ξe− ^γZ ) (3) The data of the measured transmittance T and the thickness d of the film are put into the equation (3), and the least square method is used. By optimizing according to the above, the scattering length 1 / α and the absorption length 1 / β can be obtained.

The present invention also includes irradiating the stimulable phosphor sheet of the present invention with radiation transmitted through the subject or emitted from the subject, and irradiating the stimulable phosphor sheet with the subject or the subject. After recording the radiation image as a latent image,
Irradiating the radiation-irradiated surface of the stimulable phosphor sheet with excitation light, and photoelectrically reading the stimulable emission light emitted from the latent image from the surface or both surfaces of the stimulable phosphor sheet. There is also a radiation image recording / reproducing method comprising converting the image signal into an image signal and reproducing a radiation image from the image signal.

The present invention also includes irradiating the stimulable phosphor sheet of the present invention with radiation transmitted through the subject or emitted from the subject, and irradiating the stimulable phosphor sheet with the subject or the subject. After recording the radiation image as a latent image,
The back surface of the stimulable phosphor sheet opposite to the radiation-irradiated side is irradiated with excitation light, and the stimulable emission light emitted from the latent image is photoelectrically emitted from the back surface or both surfaces of the stimulable phosphor sheet. There is also a radiation image recording / reproducing method which comprises reading the image signal, converting the image signal into an image signal, and reproducing the radiation image from the image signal.

Preferred embodiments of the stimulable phosphor sheet of the present invention are described below. (1) A stimulable phosphor sheet in which the excitation light reflective thin film has an absorption length of 1000 μm or more for stimulating light. (2) A stimulable phosphor sheet in which the radiation-absorbing partition walls contain 50% or more of a metal having an atomic number of 82 or more. (3) A stimulable phosphor sheet having an inclination in the sheet thickness direction such that at least one-dimensional radiation absorbing partitions are substantially parallel to a line connecting the radiation source and the partitions. (4) A stimulable phosphor sheet in which the excitation light-reflective thin film is composed of low light-absorbing fine particles, voids and a polymer substance. (5) The thickness of the excitation light reflective thin film is 1 μm to 100 μm
Stimulable phosphor sheet in the range. (6) A stimulable phosphor sheet in which the height / opening diameter of the stimulable phosphor-filled region is in the range of 2/1 to 40/1. (7) A stimulable phosphor sheet provided with a support on one side. (8) A stimulable phosphor sheet provided with a support on one side and a transparent protective film on the other side. (9) A stimulable phosphor sheet in which a light reflecting layer is provided between a stimulable phosphor sheet and a support. (10) A stimulable phosphor sheet provided with a transparent support on one side and used for a double-sided condensing reading method.

[0023]

BEST MODE FOR CARRYING OUT THE INVENTION The stimulable phosphor sheet of the present invention comprises:
A stimulable phosphor sheet used in the radiation image recording / reproducing method, wherein a striped or lattice-shaped radiation-absorbing partition which subdivides the sheet along a planar direction, and a stimulable partition defined by the partition. A phosphor-filled region, and the partition walls are coated with an excitation light reflective thin film having a specific light scattering length.

The structure of a stimulable phosphor sheet comprising a radiation absorbing partition wall covered with the above-mentioned thin film and a stimulable phosphor-filled region will be described with reference to the accompanying drawings. FIG. 1 is a schematic plan view of a stimulable phosphor sheet 10 of the present invention, and FIG. 2 is an enlarged cross-sectional view in which a part of the stimulable phosphor sheet 10 of FIG. 1 is enlarged. 1 and 2, the black portion is the radiation absorbing partition wall 11, the white portion surrounding the black portion is the excitation light reflective thin film 12, and the hatched portion is the stimulable phosphor-filled region 13. The thickness of the stimulable phosphor sheet is generally in the range of 50 μm to 1500 μm. In order to obtain suitable resolution characteristics and image quality, the width of the stimulable phosphor-filled region (the average value of the width in the planar direction) is 1
Desirably, it is in the range of 0 μm to 500 μm. Ratio between the thickness of the sheet and the width of the phosphor-filled area (ie, height / opening diameter of the phosphor-filled area, also referred to as grid ratio)
Is preferably 2/1 to 40/1.

The width of the radiation-absorbing partition wall is preferably in the range of 1 μm to 100 μm, and the thickness of the excitation light reflective thin film is preferably in the range of 1 μm to 100 μm. No. By setting the thickness of the thin film in this range, good reflection characteristics and a high aperture ratio of the stimulable phosphor-filled region can be maintained, and as a result, high sensitivity can be realized. In the stimulable phosphor sheets of FIGS. 1 and 2, both the top and bottom of the radiation-absorbing barrier ribs 11 are exposed on both surfaces of the sheet, but both the top and / or bottom are buried in the sheets. May be. However, the height of the partition is １ ／ to 1/1 of the thickness of the stimulable phosphor sheet.
It is desirable to be within the range.

FIGS. 3A to 3C are schematic sectional views showing examples of the constitution of the stimulable phosphor sheet of the present invention. FIG. 3A shows an embodiment in which the support 14 is provided on the lower surface of the stimulable phosphor sheet 10 of FIG. 2 and the protective film 15 is provided on the upper surface. () Shows an embodiment in which the support 14 and the light reflecting layer 16 are provided on the lower surface of the stimulable phosphor sheet 10. FIG. 3C shows that the support 14 is provided on the lower surface of the stimulable phosphor sheet 10, and the one-dimensional radiation-absorbing partitions 11 are located at the positions of the radiation source and the partition during radiation imaging. This is a mode in which the sheet is radially inclined in the thickness direction of the sheet so as to be substantially parallel to the line connecting.

The stimulable phosphor sheet of the present invention can be produced, for example, by a lamination slice method described below. The case where the stimulable phosphor-filled region is composed of stimulable phosphor particles and a binder will be described as an example.

The stimulable phosphor used in the stimulable phosphor-filled region may be a stimulable phosphor that emits stimulable light in a wavelength range of 300 to 500 nm upon irradiation with excitation light having a wavelength in the range of 400 to 900 nm. The body is preferred. Examples of such a stimulable phosphor are described in detail in JP-A-2-193100 and JP-A-4-310900. Preferred stimulable phosphors include alkaline earth metal halide phosphors activated by europium or cerium (eg, BaFBr: Eu, BaFBr).
(Br, I): Eu), and cerium-activated rare earth oxyhalide-based phosphors.

Of these, rare earth activated alkaline earth metal fluorinated halide stimulable phosphors represented by the basic composition formula (I): M ^II FX: zLn ‥‥ (I) are particularly preferred. However, M ^II is B
a, at least one alkaline earth metal selected from the group consisting of Sr and Ca, and Ln represents Ce, Pr, S
m, Eu, Tb, Dy, Ho, Nd, Er, Tm and Y
represents at least one rare earth element selected from the group consisting of b. X represents at least one halogen selected from the group consisting of Cl, Br and I. z is 0 <z ≦
Represents a numerical value within the range of 0.2.

In the above basic composition formula (I), M ^II represents
Ba preferably accounts for more than half. Ln is particularly preferably Eu or Ce. In the basic composition formula (I), F: X = 1: 1 appears in the notation, which indicates that it has a BaFX type crystal structure, and the stoichiometry of the final composition It does not indicate the composition. In general, a state in which many F ⁺ (X ⁻ ) centers, which are vacancies of X ⁻ ions, are generated in the BaFX crystal is preferable from the viewpoint of increasing the photostimulation efficiency with respect to light of 600 to 700 nm. At this time, F is often slightly more than X.

Although omitted in the basic composition formula (I), the following additives may be added to the basic composition formula (I) as necessary. bA, wN ^I , xN ^II , yN ^III where A represents a metal oxide such as Al ₂ O ₃ , SiO ₂ and ZrO ₂ . In preventing sintering between M ^II FX particles, it is preferable to use an average particle size of the primary particles has low reactivity with M ^II FX in the following ultrafine particles 0.1 [mu] m. N ^I represents at least one kind of alkali metal compound selected from the group consisting of Li, Na, K, Rb and Cs; N ^II represents an alkaline earth metal compound consisting of Mg and / or Be; ^III is Al, Ga, In,
It represents a compound of at least one trivalent metal selected from the group consisting of Tl, Sc, Y, La, Gd and Lu. As these metal compounds, it is preferable to use halides as described in JP-A-59-75200, but it is not limited thereto.

B, w, x and y are each M ^II
This is the charged addition amount when the number of moles of FX is 1, and 0
≦ b ≦ 0.5, 0 ≦ w ≦ 2, 0 ≦ x ≦ 0.3, 0 ≦ y ≦
Represents a numerical value within each range of 0.3. These figures do not represent the element ratios contained in the final composition for additives that are reduced by baking or subsequent washing. Some of the above compounds may remain as added in the final composition.
^Some react with ^II FX or are incorporated.

In addition, if necessary, the basic composition formula (I) may further include, as necessary, Z Z described in JP-A-55-12145.
n and Cd compounds; TiO ₂ , BeO, MgO, C which are metal oxides described in JP-A-55-160078.
aO, SrO, BaO, ZnO, Y 2 O 3, La 2 O 3, I
n ₂ O ₃ , GeO ₂ , SnO ₂ , Nb ₂ O ₅ , Ta ₂ O ₅ , Th
O ₂ ; Zr and Sc compounds described in JP-A-56-116777; B compounds described in JP-A-57-23673; As described in JP-A-57-23675.
And Si compounds; tetrafluoroboric acid compounds described in JP-A-59-27980; JP-A-59-4728.
No. 9, hexafluorosilicic acid, hexafluorotitanic acid, and hexafluorozirconic acid comprising a monovalent or divalent salt thereof; V, Cr described in JP-A-59-56480; Mn, F
e, a compound of a transition metal such as Co and Ni, or the like may be added. Further, the present invention is not limited to the phosphor containing the above-described additive, and any phosphor having a composition which is basically regarded as a rare earth activated alkaline earth metal fluorinated halide-based stimulable phosphor can be used. It may be.

The rare earth activated alkaline earth metal fluorohalide-based stimulable phosphor represented by the basic composition formula (I) usually has an aspect ratio in the range of 1.0 to 5.0. . The stimulable phosphor particles used in the stimulable phosphor sheet of the present invention generally have an aspect ratio in the range of 1.0 to 2.0 (preferably 1.0 to 1.5), and have a particle size of The median diameter (Dm) is in the range of 1 μm to 10 μm (preferably 2 μm to 7 μm), and σ / Dm is 50% when the standard deviation of the particle size distribution is σ.
Or less (preferably 40% or less). Also,
Examples of the shape of the particles include a rectangular parallelepiped, a regular hexahedron, a regular octahedron, a tetrahedron, an intermediate polyhedron and irregular shaped pulverized particles, and among them, the tetrahedron is preferred. However, the photostimulable phosphor particles satisfying the above aspect ratio, particle size and particle size distribution can be used in the present invention even if they are not necessarily tetrahedral.

The above-mentioned stimulable phosphor particles are dispersed and dissolved in a suitable organic solvent together with a binder to prepare a coating solution. The ratio between the binder and the phosphor in the coating solution is usually adjusted to a value in the range of 1: 1 to 1: 100 (weight ratio). This ratio is particularly preferably in the range of 1: 8 to 1:40 (weight ratio). Various types of resin materials are also known for the binder that disperses and supports the stimulable phosphor particles, and in the formation of the stimulable phosphor sheet of the present invention, these known binder resins are mainly used. Any of the above-mentioned arbitrary resin materials can be appropriately selected and used. This coating solution is applied and dried to obtain a large number of thin stimulable phosphor films. In order to further increase the density of the phosphor, it is preferable to heat and compress the obtained stimulable phosphor film by calendering.

The radiation-absorbing partition, which is another component of the present invention, is a partition made of a radiation-absorbing substance, and is generally a metal having an atomic number of 82 or more (for example, P
b, Bi) of 50% or more. By using such a metal as the radiation-absorbing substance, scattered radiation can be effectively removed, and a reduction in resolution due to the range of the point source when contact exposure is performed on the point source can be efficiently suppressed.
Specifically, a metal foil such as Pb or Bi or a foil made of an alloy with another metal such as Sn is prepared as the partition wall forming film.

In the present invention, a characteristic feature is
The excitation light reflective thin film for covering the radiation absorbing partition wall has a scattering length of 0.05 μm to 20 μm with respect to the excitation light.
m and shorter than the scattering length of the stimulable phosphor-filled region. Further, the absorption length for the stimulated emission light is preferably 1000 μm or more. The excitation light-reflective thin film is preferably composed of at least low light-absorbing fine particles and a polymer substance containing the same in a dispersed manner, and particularly preferably composed of low light-absorbing fine particles, voids and a high-molecular substance. Due to the difference in the refractive index between the low light-absorbing fine particles and the polymer substance, or between the low light-absorbing fine particles and the void, light scattering can be effectively caused. The light can have a long absorption length (that is, high reflectance and low absorption).

Examples of the fine particles having low light absorption include fine particles of inorganic substances such as aluminum oxide (alumina), titanium oxide, yttrium oxide, gadolinium oxide, tellurium oxide, and zircon oxide. Further, the stimulable phosphor particles (which may be spherical or plate-shaped) can also be used. Of these, alumina is particularly preferred. In order for the light scattering length of the thin film to fall within the above range, the particle diameter of the low light-absorbing fine particles is generally preferably in the range of 0.01 μm to 5.0 μm, and particularly preferably 0.4 μm to 0.8 μm. Range. The ratio of the refractive index of the low light-absorbing fine particles to the refractive index of the voids is 1.1 to 3.
It is desirably in the range of 0.

The polymer substance (binder resin) is not particularly limited, and can be arbitrarily selected from those usable as a binder in the stimulable phosphor-filled region. In order to shorten the light scattering length of the thin film, the ratio of the refractive index of the low light-absorbing fine particles to the refractive index of the polymer substance is preferably in the range of 1.1 to 3.0. Examples of preferred polymeric substances include polyurethane,
Examples include polyacryl, polyethylene, polystyrene, and fluororesins.

The above-mentioned low light-absorbing fine particles and a polymer substance are added to a solvent, and they are sufficiently mixed to prepare a coating liquid for forming a thin film. The ratio between the polymer substance and the low light-absorbing fine particles in the coating solution is generally selected from the range of 1:80 to 1: 3 (weight ratio), and especially 1:20 to 1: 1.
It is preferable to select from the range of 0 (weight ratio). The coating liquid for forming a thin film is sequentially applied to both surfaces of the film for forming a partition such as the metal foil and dried to obtain a large number of films for forming a partition having both surfaces coated with an excitation light reflective thin film.

The volume ratio of the low light-absorbing fine particles to the total volume of the excitation light reflective thin film is 30% to 90%.
The volume ratio of the voids is preferably in the range of 10% to 70%. The ratio of the voids in the thin film can be adjusted to a desired value by, for example, applying a coating solution, drying and then calendering and heating and compressing. The thin film may contain a room-temperature liquid organic substance such as silicone oil or a fluorine compound instead of the voids, or may absorb excitation light and absorb photostimulated light for the purpose of improving image sharpness. It may be colored with a coloring agent that does not. As the colorant, for example, a colorant described in JP-B-59-23400 can be arbitrarily selected from those known as colorants for the stimulable phosphor sheet.

Next, a large number of the stimulable phosphor films and the partition wall forming films covered with the excitation light reflective thin film are alternately laminated to form a laminate. Then, the obtained laminate is heated while applying pressure to bring the adjacent films into close contact with each other to form a laminate block.

Next, by slicing the laminate block along the lamination surface, the striped stripes of the present invention in which the strips of the stimulable phosphor film and the strips of the partition wall forming film are alternately arranged. Can be obtained.

Alternatively, the obtained striped phosphor film and the partition wall forming film covered with the above-mentioned thin film are alternately laminated in a large number, and then pressurized and heated to form the laminated block again. Form. By slicing this laminate block along the laminated surface where the end face of the stimulable phosphor film and the end face of the partition wall forming film appear, the lattice-shaped stimulable phosphor sheet of the present invention is obtained. be able to.

As shown in FIG. 3 (3), in order to incline the stripe-shaped or lattice-shaped radiation-absorbing partitions radially in the thickness direction, it is necessary to slice both of the above-mentioned laminate blocks when slicing them. Is sliced into a curved surface so that the cut surface has a curvature whose radius is the distance between the radiation source and the stimulable phosphor sheet at the time of photographing, and is then stretched and molded into a planar shape.

On the surface on one side of the stimulable phosphor sheet of the present invention, a light reflecting layer made of a material reflecting excitation light and / or stimulable light can be provided. When a support is provided on the stimulable phosphor sheet, the light reflecting layer is usually provided between the support and the stimulable phosphor sheet. By providing the light reflecting layer, it becomes possible to increase the rate of excitation light and the efficiency of taking out emitted light, and as a result, higher sensitivity and higher image quality can be achieved. However, when the stimulable phosphor sheet is used for the double-sided condensing reading method, it is not preferable to provide such a light reflecting layer.
As the light reflecting layer, for example, alumina, titanium dioxide,
It is possible to use a white pigment such as barium sulfate or a layer formed by dispersing and supporting phosphor particles which do not show stimulated emission with a binder.

The stimulable phosphor sheet of the present invention does not need to be provided with a support or a protective film. However, the stimulable phosphor sheet may be used for transportation and handling of the stimulable phosphor sheet or to avoid a change in characteristics. That is, a support and a protective film may be provided to improve durability, weather resistance, and stain resistance. Further, the support may be transparent. In this case, the support is suitable for a reading method using a double-sided condensing method in which the photostimulable emission light is extracted from both sides of the photostimulable phosphor sheet.

The support is usually a sheet or film made of a flexible resin material and having a thickness of 50 μm to 1 mm. The support may be transparent, or alternatively,
A light reflecting material (eg, alumina particles, titanium dioxide particles, barium sulfate particles) for reflecting the excitation light or the stimulated emission light may be filled, or a void may be provided. Alternatively, the support may be filled with a light-absorbing material (eg, carbon black) for absorbing excitation light or stimulated emission light. Examples of resin materials that can be used for forming the support include various resin materials such as polyethylene terephthalate, polyethylene naphthalate, aramid resin, and polyimide resin. If necessary, the support may be a metal sheet, a ceramic sheet, a glass sheet, a quartz sheet, or the like.

The protective film is desirably transparent so that it hardly affects the incidence of the excitation light and the emission of the stimulating light, and the protective film is stimulable from external physical shocks and chemical influences. It is desirable that the phosphor sheet is chemically stable and has high physical strength so that the phosphor sheet can be sufficiently protected. As the protective film, a solution prepared by dissolving a transparent organic polymer material such as a cellulose derivative, polymethyl methacrylate, or an organic solvent-soluble fluororesin in an appropriate solvent is applied onto the phosphor layer. Formed, or an organic polymer film such as polyethylene terephthalate, or a protective film forming sheet such as a transparent glass plate, separately formed and provided on the surface of the phosphor layer using a suitable adhesive, or inorganic What formed the compound on the fluorescent substance layer by vapor deposition etc. is used. Various additives such as light-scattering fine particles such as magnesium oxide, zinc oxide, titanium dioxide, and alumina, slip agents such as perfluoroolefin resin powder and silicone resin powder, and crosslinking agents such as polyisocyanate are contained in the protective film. May be dispersedly contained. The thickness of the protective film is generally in the range of about 0.1 μm to 20 μm.

A fluororesin coating layer may be further provided on the surface of the protective film in order to enhance the contamination resistance of the protective film. The fluororesin coating layer can be formed by applying a fluororesin solution prepared by dissolving (or dispersing) a fluororesin in an organic solvent on the surface of the protective film and drying.
The fluororesin may be used alone, but is usually used as a mixture of the fluororesin and a resin having a high film forming property. Further, an oligomer having a polysiloxane skeleton or an oligomer having a perfluoroalkyl group can be used in combination. The fluororesin coating layer may be filled with a particulate filler in order to reduce interference unevenness and further improve the quality of a radiographic image. The thickness of the fluororesin coating layer is usually in the range of 0.5 μm to 20 μm. In forming the fluororesin coating layer, additional components such as a crosslinking agent, a hardening agent, an anti-yellowing agent and the like can be used. In particular, the addition of a crosslinking agent is advantageous for improving the durability of the fluororesin coating layer.

Further, depending on the purpose of use, auxiliary functional layers such as a light absorbing layer, an adhesive layer and a conductive layer may be provided between the stimulable phosphor sheet and the support. May be formed with a large number of concave portions. On the other hand, a friction reducing layer or a scratch-resistant layer may be provided on the surface of the support on the side where the stimulable phosphor sheet is not provided, in order to improve the transportability or the scratch resistance.

In the radiation image recording / reproducing method using the stimulable phosphor sheet according to the present invention, a condensing method used for reading a recorded image is a conventional one-side condensing method (a method of condensing light from an excitation light incident surface). Alternatively, there is a method of condensing light from the surface on the side opposite to the excitation light incident surface) or a method of collecting light from both sides. It is particularly advantageous when the stimulable phosphor sheet of the invention is used.

The excitation light may be incident from the surface on the radiation irradiation side during recording (radiation imaging) of the radiation image, or from the back surface opposite to the radiation irradiation. When the irradiation is performed from the radiation irradiation side surface, more radiation energy accumulated as a latent image can be emitted, and high sensitivity can be obtained. Further, if the operation is performed from the opposite back surface, since the back surface has a larger grid effect than the front surface having a large amount of scattered radiation and a small grid effect, an image with higher resolution can be obtained.

The radiation image recording / reproducing method of the present invention
FIG. 4 of the accompanying drawings shows an example in which excitation light is irradiated from the radiation irradiation side surface to obtain a radiation image of a subject and radiation image information is read by a double-sided focusing method.
This will be described with reference to FIG. FIG. 4 is a schematic cross-sectional view showing an example of the configuration of a double-sided condensing type radiation image reading apparatus of the present invention.

First, an object is placed between a radiation source such as an X-ray generator and a stimulable phosphor sheet using a radiation imaging apparatus (not shown) or the like, and then radiation emitted from the radiation source is emitted. By irradiating the subject with radiation transmitted through the subject and irradiating the stimulable phosphor sheet with the stimulable phosphor of the sheet to absorb and store the energy of the radiation, a radiation image of the subject is used as a latent image. Record. At this time, imaging may be performed while holding the stimulable phosphor sheet in a state where the sheet has a curvature whose radius is the distance from the radiation source to the sheet. Alternatively, when the radiation-absorbing partition walls of the stimulable phosphor sheet themselves have an inclination as shown in FIG. 3C, the stimulable phosphor sheet is set so that the partition walls are parallel to the incident radiation. Place and shoot. By doing so, the partition walls become parallel to the incident radiation, and only the scattered radiation can be efficiently shielded to enhance the grid effect.

Next, a radiation image of the subject is read from the stimulable phosphor sheet using the radiation image reading apparatus shown in FIG. The stimulable phosphor sheet 20 is moved and conveyed in the apparatus by a pair of nip rollers 22a and 22b. Excitation light 23 such as a laser beam is emitted from the upper surface (radiation-side surface) of the stimulable phosphor sheet 20. Sheet 20
Stimulated light emitted from inside travels to the upper and lower surfaces,
Of these, the stimulating light 24a that has proceeded to the lower surface side of the sheet 20
Is condensed by a condensing guide 25a provided below, is converted into an electric signal by a photoelectric conversion device (photomultiplier) 26a provided at a base of the condensing guide 25a, and is amplified by an amplifier 27a. It is sent to the processing device 28. On the other hand, the stimulated emission light 24b that has proceeded to the upper surface side of the sheet 20 is directly or reflected by the mirror 29 and is collected by the light collection guide 25b provided above, and is provided at the base of the light collection guide 25b. Is converted into an electric signal by the photoelectric conversion device (photomultiplier) 26b,
The signal is amplified by the amplifier 27b and sent to the signal processing device 28.
The signal processing device 28 performs an arithmetic process such as an addition process or a subtraction process, which is predetermined based on the type of the target radiographic image, on the electric signals sent from the amplifiers 27a and 27b. Is sent out as an image signal. In the case of a stimulable phosphor sheet in which radiation-absorbing partition walls are provided in a stripe pattern, irradiation with excitation light can be performed in a direction such that it crosses the partition walls and the phosphor-filled region during reading. It is advantageous.

Next, the sent image signal is reproduced as a visible image by an image reproducing device (not shown). The reproducing device may be a display device such as a CRT, a recording device that performs optical scanning recording on a photosensitive film, or for that purpose, temporarily stores an image signal in an image file such as an optical disk or a magnetic disk. It may be replaced by a device.

On the other hand, the stimulable phosphor sheet 20 is sequentially moved in the direction of the arrow by the nip rollers 22a and 22b, and the area subjected to the reading step is then moved to the erasing light source 30 such as a sodium lamp or a fluorescent lamp. It is subjected to an erasing process to be used. As a result, the radiation energy remaining on the sheet after the reading step is released and removed, and the latent image due to the remaining radiation energy is not adversely affected in the next radiation image recording (photographing) step. .

Alternatively, as a stimulable phosphor sheet, on the surface on the side of the excitation light irradiation, the reflectance for the excitation light increases as the incident angle increases, and on the other hand, the reflectance for the stimulable emission light increases at the incident angle. Using a stimulable phosphor sheet provided with a multilayer filter that does not depend on the stimulable phosphor sheet in which the radiation image information is accumulated and recorded as a latent image while being transferred in the plane direction, or While moving the excitation light irradiation device in the plane direction of the stimulable phosphor sheet,
The stimulable phosphor sheet is irradiated with excitation light linearly in a direction orthogonal to the transport direction using a fluorescent light guide sheet or the like, and emitted from the latent image of the excitation light irradiated portion of the stimulable phosphor sheet. The stimulated emission light is sequentially and one-dimensionally photoelectrically detected using a line sensor or the like in which a large number of solid-state photoelectric conversion elements are linearly arranged,
A radiation image information reading method for obtaining the radiation image information as an electric image signal can also be used.

[0060]

EXAMPLES Example 1 1) A coating liquid was prepared by dispersing stimulable phosphor particles (BaFBr: Eu) and a thermoplastic high molecular weight polyester resin in an organic solvent at a weight ratio of 5: 1. This coating solution was applied using a coating machine and dried to obtain a stimulable phosphor film. The obtained stimulable phosphor film was further heated and compressed by calendering to obtain a stimulable phosphor film having a thickness of about 100 μm.

2) A dispersion liquid was prepared by dispersing alumina particles having an average particle diameter of 0.6 μm and a high molecular weight acrylic resin in an organic solvent at a weight ratio of 15: 1. This dispersion was applied to the surface of a Pb foil having a thickness of 10 μm using a coating machine and dried to form a thin film having a thickness of about 10 μm. Further, a thin film was similarly formed on the surface on the opposite side of the Pb foil, to obtain a film for forming a partition having a thickness of about 30 μm, both surfaces of which were coated with the excitation light reflective thin film.

3) The stimulable phosphor film and the partition wall forming film are each cut into a size of 10 cm × 25 cm, and a total of 1600 layers are alternately laminated to obtain a laminate. Thus, a laminate block was produced. This laminate block was sliced at a thickness of 1000 μm along the lamination cross section using a wide-width microtome to obtain a stimulable phosphor sheet having radiation-reflective partition walls (grids) having a stripe structure.

4) The obtained stimulable phosphor sheet was coated on a polyethylene terephthalate sheet (support, thickness: 300 μm).
m) using an adhesive. On the other surface of the stimulable phosphor sheet, a transparent polyethylene terephthalate film having a thickness of 6 μm was provided via an adhesive layer (thickness: about 2 μm) made of a thermoplastic high molecular weight polyester resin. Thus, a stimulable phosphor sheet with a support and a transparent protective film (see (1) in FIG. 3) was obtained.

The excitation light reflective thin film (thickness: about 10 μm) used in the above-described stimulable phosphor sheet was measured using a spectrophotometer at a typical excitation wavelength of 600 nm and a typical photostimulated emission wavelength of 400 nm. Was measured. The obtained transmittance was substituted into the above-described formula (3) based on Kubelka's theory to calculate the light scattering length and the light absorption length. As a result, the light scattering length at the excitation wavelength was 4 μm, and the light at the emission wavelength was 4 μm. The absorption length was 10,000 μm or more. The light scattering length at the excitation wavelength of the stimulable phosphor film was 39 μm.

Further, while holding the stimulable phosphor sheet in a state of being bent to a curvature having a radius equal to the distance from the X-ray source, a chest phantom is photographed with X-rays having a tube voltage of 120 kVp, and then a radiation image is obtained. Using a reader (FCR9000, manufactured by Fuji Photo Film Co., Ltd.), the X-ray irradiation side surface was scanned with a laser beam to read a radiation image by a one-sided condensing method. As a result, compared to the conventional radiation image conversion panel (ST-VN), scattered radiation was removed, and an extremely clear image with no reduction in sensitivity was obtained.

Example 2 1) A laminate block was manufactured in the same manner as in Example 1. This laminate block is sliced to a thickness of 1000 μm along the lamination cross section with a blade having a radius of curvature equal to the distance between the X-ray source and the stimulable phosphor sheet, and a radiation reflection having a striped structure is obtained. A curved stimulable phosphor sheet having a conductive partition (grid) was obtained.

2) The obtained stimulable phosphor sheet was coated on a polyethylene terephthalate sheet (support, thickness: 300).
μm), and flattened while bonding using an adhesive so that the convex surface faces up. As a result, a stimulable phosphor sheet with a support in which the radiation-absorbing partition walls had an inclination (see (3) in FIG. 3) was obtained.

The above-described stimulable phosphor sheet with a support was arranged so that the sheet side surface thereof faces the X-ray source, and a chest phantom was photographed with X-rays having a tube voltage of 120 kVp. A radiation image was read in the same manner as described above. As a result, compared to the conventional radiation image conversion panel,
Scattered radiation was removed, and an extremely clear image without a decrease in sensitivity was obtained.

Example 3 1) A dispersion liquid for a light reflecting layer was prepared by dispersing alumina particles having an average particle diameter of 0.6 μm and a high molecular weight acrylic resin in an organic solvent at a weight ratio of 15: 1. This dispersion was applied on a polyethylene terephthalate sheet (support, thickness: 300 μm) with a thickness of 100 μm using a coating machine, and dried to form a light reflection layer on the support. 2) On this light reflecting layer, the stimulable phosphor sheet obtained in Example 1 was bonded by using an adhesive to form a support and a stimulable phosphor sheet with a light reflecting layer (see FIG. 3). (See (2)).

Using the stimulable phosphor sheet described above, X-ray photography and radiation image reading were performed in the same manner as in Example 1. As a result, compared with the conventional radiation image conversion panel, the scattered radiation was removed, and an image having higher emission intensity than the stimulable phosphor sheet of Example 1 was obtained.

Example 4 1) The stimulable phosphor sheet obtained in Example 1 was replaced with a transparent polyethylene terephthalate sheet (support, thickness: 10).
(0 μm) using an adhesive to obtain a stimulable phosphor sheet with a transparent support.

After performing X-ray photography in the same manner as in Example 1 using the above-described stimulable phosphor sheet, the X-ray irradiation side surface is scanned with laser light to read a radiation image by a double-side focusing method. And image information obtained from both sides was added to form an image. As a result, the emission intensity was higher than that of Example 1, and a high-quality image was obtained.

After X-ray photography was performed in the same manner as in Example 1 using the above-described stimulable phosphor sheet, the back surface opposite to the X-ray irradiation was scanned with a laser beam to collect both surfaces. A radiographic image was read by the method, and image information obtained from both sides was added to form an image. As a result, although the emission intensity was lower than that of Example 1, a clear image from which scattered radiation was further removed was obtained.

Example 5 1) A laminate block was manufactured in the same manner as in Example 1. This laminate block is placed along the lamination cross section by 10
Many slices were sliced to a thickness of 0 μm. 2) Each of the striped phosphor film and the film for forming a partition wall obtained in Example 1 was 10 cm × 25 cm.
, And a total of 1600 layers were alternately laminated to obtain a laminate, and the laminate was heated and adhered to produce a second laminate block. By slicing the second laminate block at a thickness of 1000 μm along a laminated cross section where a striped structure appears using a wide-width microtome, a stimulable fluorescent light having a radiation-reflective partition (grid) having a lattice-like structure. A body sheet was obtained.

Using the above stimulable phosphor sheet, X-ray photography and radiation image reading were performed in the same manner as in Example 1. As a result, compared with the conventional radiation image conversion panel, scattered radiation was removed, and an extremely clear image with less decrease in sensitivity was obtained.

From the results described above, the stimulable phosphor sheets of the present invention (Examples 1 to 5) do not cause any reduction in sensitivity due to the grid, and at the same time, efficiently remove scattered radiation by the grid to provide a clear image with high resolution. It is clear that it gives a nice image. In addition, the stimulable phosphor sheet having the light reflecting layer shows higher sensitivity, and the stimulable phosphor sheet for the double-sided condensing method having the transparent support has high sensitivity by reading in the method. It is clear that it gives a high quality image. Further, at the time of X-ray imaging, the stimulable phosphor sheet is bent into a curvature having a radius equal to the distance from the radiation source to perform imaging, or a stimulable phosphor provided with a radially inclined grid is provided. It is clear that the use of the sheet can further effectively remove only the scattered radiation.

[0077]

According to the stimulable phosphor sheet of the present invention in which the radiation-absorbing partition walls (grids) covered with the excitation light-reflective thin film are provided in stripes or grids, scattered radiation is removed by the grids. In this way, an image with high resolution can be obtained, or an adjacent point source having a long range can be separated and detected, and at the same time, absorption of excitation light and emission light can be suppressed by a thin film to achieve high sensitivity. Further, according to the radiation image recording / reproducing method of the present invention, in particular, by holding the stimulable phosphor sheet in a curved shape, or by performing radiation imaging using a stimulable phosphor sheet having an inclined grid. It is possible to more efficiently remove scattered radiation and obtain a high-quality image. Therefore, especially when used as a recording medium for medical radiography and autoradiography, an electron microscope, or another radiation recording medium, the stimulable phosphor sheet and the radiation image recording / reproducing method of the present invention are advantageous. Become.

[Brief description of the drawings]

FIG. 1 is a schematic plan view showing an example of a stimulable phosphor sheet of the present invention.

FIG. 2 is an enlarged sectional view in which a part of FIG. 1 is enlarged.

FIGS. 3A to 3C are schematic cross-sectional views showing examples of the configuration of a stimulable phosphor sheet of the present invention.

FIG. 4 is a schematic cross-sectional view showing an example of the configuration of a radiation image reading apparatus of a double-sided focusing system used in the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 stimulable phosphor sheet 11 radiation absorbing partition wall (grid) 12 excitation light reflective thin film 13 stimulable phosphor filled area 14 support 15 protective film 16 light reflection layer 20 stimulable phosphor sheet 22 a, 22 b nip roller 23 Excitation light 24a, 24b Stimulated emission light 25a, 25b Condensing guide 26a, 26b Photoelectric conversion device 27a, 27b Amplifier 28 Signal processing device 29 Mirror 30 Erase light source

Claims (17)

[Claims] After recording a radiation image as a latent image,
Irradiation with excitation light emits photostimulated light from the latent image, and then electrically processes the photostimulated light to reproduce a radiation image. A phosphorescent phosphor sheet, wherein the stimulable phosphor sheet is subdivided in a one-dimensional or two-dimensional direction along a plane direction in a striped or lattice-shaped radiation-absorbing partition, and the stimulable partition defined by the partition. And the radiation-absorbing partition wall has a scattering length for excitation light in the range of 0.05 μm to 20 μm,
And a stimulable phosphor sheet which is covered with an excitation light reflective thin film shorter than the scattering length of the stimulable phosphor-filled region. 2. The stimulable phosphor sheet according to claim 1, wherein the excitation light reflective thin film has an absorption length of 1000 μm or more for stimulating light. 3. The stimulable phosphor sheet according to claim 1, wherein the radiation-absorbing partition contains 50% or more of a metal having an atomic number of 82 or more. 4. The sheet according to claim 1, wherein each of the at least one-dimensional radiation absorbing partitions has an inclination in a thickness direction of the sheet so as to be substantially parallel to a line connecting the radiation source and the partition. 3. The stimulable phosphor sheet according to any one of the above items. 5. The method according to claim 5, wherein the excitation light-reflective thin film has low light-absorbing fine particles,
The stimulable phosphor sheet according to any one of claims 1 to 4, comprising a void and a polymer substance. 6. The excitation light reflective thin film has a thickness of 1 μm to 1 μm.
The stimulable phosphor sheet according to any one of claims 1 to 5, which is in a range of 00 µm. 7. The stimulable phosphor according to claim 1, wherein the height / opening diameter of the stimulable phosphor-filled region is in the range of 2/1 to 40/1. Sheet. 8. The stimulable phosphor sheet according to claim 1, wherein a support is provided on one side. 9. The stimulable phosphor sheet according to claim 8, wherein a transparent protective film is provided on a side opposite to the support. 10. The stimulable phosphor sheet according to claim 8, wherein a light reflecting layer is provided between the stimulable phosphor sheet and the support. 11. The stimulable phosphor sheet according to claim 8, wherein the support is a transparent support and is used for a double-sided condensing reading method. 12. A stimulable phosphor sheet according to claim 1, wherein the stimulable phosphor sheet transmits an object.
Alternatively, by irradiating radiation emitted from the subject, and recording a radiation image of the subject or the subject as a latent image on the stimulable phosphor sheet, the radiation-irradiated surface of the stimulable phosphor sheet Irradiating the excitation light to the stimulable phosphor sheet, photoelectrically reading the stimulable luminescent light emitted from the latent image from the surface or both surfaces of the stimulable phosphor sheet, and converting the stimulable phosphor sheet into an image signal. A method for recording and reproducing a radiation image. 13. The radiation image recording / reproducing method according to claim 12, wherein the radiation is applied while the stimulable phosphor sheet is bent to have a radius of curvature equal to the distance from the radiation source to the sheet. 14. The radiation image recording / reproducing method according to claim 12, wherein a stimulable phosphor sheet whose radiation-absorbing partition walls have an inclination is arranged so that the partition walls are substantially parallel to the radiation, and the radiation is irradiated. . 15. A stimulable phosphor sheet according to any one of claims 1 to 11, wherein the stimulable phosphor sheet transmits an object.
Or, by irradiating radiation emitted from the subject, and recording a radiation image of the subject or the subject as a latent image on the stimulable phosphor sheet, and the radiation-irradiated side of the stimulable phosphor sheet The opposite back surface is irradiated with excitation light, and photostimulated light emitted from the latent image is photoelectrically read from the back surface or both surfaces of the photostimulable phosphor sheet to be converted into an image signal. A radiation image recording / reproducing method comprising reproducing a radiation image from a signal. 16. The radiation image recording / reproducing method according to claim 15, wherein the radiation is applied while the stimulable phosphor sheet is bent to a curvature having a radius equal to the distance from the radiation source to the sheet. 17. The radiation image recording / reproducing method according to claim 15, wherein a stimulable phosphor sheet whose radiation-absorbing partition walls have an inclination is disposed so that the partition walls are substantially parallel to the radiation, and the radiation is irradiated. .