JP2004028986A - Radiological image storage panel having specific layer arrangement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiological image storage panel giving long-term repetitive use in addition to excellent sharpness without speed loss even in a severe operational environment, but not showing any defect at all with respect to adhesiveness between a storage phosphor layer and an antihalation undercoat layer. <P>SOLUTION: This radiological image storage panel includes a supported layer of storage phosphor particles dispersed in a joining medium and a thereto-neighboring layer arrangement of an intermediate layer between the supported layer and a support body having a reflection characteristic. The layer arrangement comprises the antihalation undercoat layer containing dye of one or more kinds and positioned closer to the support body, and an improved adhesiveness layer positioned closer to the layer of the phosphor particles. The adhesiveness layer is hardened to such a degree as to be less than the undercoat layer. <P>COPYRIGHT: (C)2004,JPO

Description

Ｍｏｗｉｌｉｔｈ　ＣＴ５はビニルアセテート−クロトン酸共重合体である。
Ｃｙｍｅｌ　３００は変性メラミンホルムアルデヒド樹脂（ヘキサメトキシメチルメラミン）である。
【００８４】
熱硬化は９０℃の温度で少なくとも３０分間実施された。
ＡＨＵ着色剤の式は以下に与えられる。
【化１】

【００８５】
メチルシクロヘキサン／トルエン／ブチルアセテートの５０／３０／２０重量％の溶媒混合物において試料（５ｃｍ×５ｃｍ）の２５℃で１０分間の浸漬によって測定される、比較用ハレーション防止層（３０分間硬化）のハレーション防止染料の非移行百分率についての熱硬化温度の影響：
ＡＨＵ層において測定された、前記浸漬試験前後の６３３ｎｍの波長での濃度を比較するときの染料又は着色剤の光学濃度から非移行百分率が計算される。
【００８６】
【表２】

【００８７】
得られた結果から、高い硬化温度はＡＨＵ層の硬化を増大させ、ハレーション防止染料又はＡＨＵ着色剤のＡＩＬへの移行を減少することは明らかである。
【００８８】
【表３】

Ｄｅｓｍｏｄｕｒ　Ｎ　７５は脂肪族ポリイソシアネート（ヘキサメチレン−１，６−ジイソシアネート）である。
熱硬化は６０℃で１時間実施された。
【００８９】
【表４】

Ｋｒａｔｏｎ　ＦＧ１９０１Ｘは官能化スチレン−エチレン／ブチレン−スチレンブロックコポリマー（熱可塑性ゴム）である。
Ｋｒａｔｏｎ　ＥＫＰ−２０７は重合体の一端に第１ヒドロキシル官能を、他端にエポキシ化イソプレン官能からなるヘテロテレチェリックポリマーである。
熱硬化は６０℃で１時間実施された。
【００９０】
【表５】

熱硬化は９０℃で３０分間実施された。
【００９１】
【表６】

熱硬化は４０℃で４時間実施された。
【００９２】
結果の概要
単一層の硬化度
（試験は５０／３０／２０ｗｔ％の比率のメチルシクロヘキサン／トルエン／ブチルアセテートの溶媒混合物で実施され、浸漬時間は１０分である）
【表７】

【００９３】
本発明の前述の及び以下の好ましい例に詳細に記載されているように、与えられた実施例に続く特許請求の範囲に規定されたような本発明の範囲から逸脱せずに多数の変更をその中でなしうることが当業者に明らかであろう。
【００９４】
単一及び組合わされた二層システムに対するパラメータ
（非移行率％を決定するための試験は５０／３０／２０ｗｔ％の比率のメチルシクロヘキサン／トルエン／ブチルアセテートの溶媒混合物で実施された）
【表８】

【００９５】
Ｍｏｗｉｌｉｔｈ ／ Ｃｙｍｅｌ の影響−ハレーション防止層及び接着性改良層タイプ３の硬化度の比
層を９０℃で３０分間硬化した後、メチルシクロヘキサン／トルエン／ブチルアセテート（５０／３０／２０質量％）の混合物において１０分間浸漬することによって溶媒溶解性及び質量膨潤増加量を測定する
ＡＩＬ＝接着性改良層／／ＡＨＵ＝ハレーション防止（染料）層
【００９６】
【表９】

【００９７】
上に与えられたデータから明らかなように、前記二つの層配置は燐光体層の改良された接着性とともにスクリーンにおけるハレーション防止染料の移行の防止を併せ持つ。[0001]
Field of the invention
The present invention relates to a radiation image storage panel having a specific interlayer configuration in addition to a fluorescent layer comprising a binder and a stimulable phosphor dispersed therein.
[0002]
Background of the Invention
In radiography, the interior of the subject is recreated by X-rays, gamma rays and high energy elementary particle radiation, for example beta rays, electron beams or transmitted radiation which is a high energy radiation belonging to the group of neutron radiation. To convert the transmitted radiation into visible and / or ultraviolet light, luminescent materials called phosphors are used.
[0003]
In a conventional radiographic system, an X-ray radiograph is obtained by X-rays transmitted through a subject according to an image and converted into light of a corresponding intensity in a so-called intensifying screen (X-ray conversion screen). In it, the phosphor particles absorb transmitted X-rays and convert them to visible and / or ultraviolet light (photographic films are more sensitive to direct X-ray impact). Indeed, the light emitted image-wise by the screen, irrespective of being provided with a fluorescent dye layer and / or a reflective layer, which is advantageous for reduced phosphor coverage or speed, for example as in EP-A 0 595 089 The photographic silver halide emulsion layer film in contact is illuminated and the film is developed after exposure to form a silver image therein that is consistent with the X-ray image.
[0004]
Another development, for example as described in US-A-38595527, is a photostimulation which has the property of temporarily storing most of the energy of the X-ray image in addition to its immediate emission upon X-ray irradiation (immediate emission). An X-ray recording system using a volatile storage phosphor is described. The energy in this case is emitted by the light stimulus in the form of light that differs in wavelength characteristics from the light used for the light stimulus. In the X-ray recording system, light emitted upon photostimulation is detected photo-electronically and is sequentially converted into an electrical signal.
[0005]
The basic components of such an X-ray imaging system operating with a storage phosphor are: an imaging sensor containing said phosphor, usually a plate or panel (which temporarily stores the X-ray energy pattern); A scanning laser beam for an opto-electronic photodetector that provides an analog signal (which is subsequently converted to a digital time series signal), usually a digital image processor (which digitally manipulates the image), a signal Recorders, such as magnetic disks or tapes, and image recorders or electronic signal displays, such as cathode ray tubes, for modulated exposure of photographic film. A search for lasers useful for reading photostimulable latent fluorescence images is provided by Research Disclosure Volume 308, No. 117, p. 991 (1989).
[0006]
From the foregoing description of the two x-ray recording systems operating with an x-ray converting phosphor screen in the form of a plate or panel, the plate or panel acts only as an intermediate imaging element and does not form a final record It is clear that. The final image is created or reproduced on another recording medium or display. The phosphor plate or sheet can be reused repeatedly. Prior to reuse of the photostimulable phosphor panel or sheet, the residual energy pattern is erased by flooding with light.
[0007]
In terms of image quality of the image storage panel, especially in terms of sharpness, said sharpness is not determined by the spread of light emitted by the stimulable phosphor in the panel, but rather by the stimulus lines in the panel. Determined by the degree of spreading: To reduce this light spreading, it can be made from a mixture of fine and coarse batches to fill the gaps between the coated coarse phosphor particles.
[0008]
A good bulk factor produces a mixture of coarse and fine phosphor particles that causes a loss in sensitivity if the coarse and fine phosphor particles differ only slightly in sensitivity. Can be obtained by: Due to intensifying screens, this problem has already been dealt with quite a while ago by Kali-Chemie and is patented in US-A 2,219,295; 2,129,296 and 2,144,040. Thus, a radiograph showing improved visualization including a blue light absorbing (yellow) dye is described in EP-A $ 0028521.
[0009]
In particular, the thickness of the phosphor layer can give rise to an increased unsharpness of the emitted light, which means that for the same coverage of said phosphor particles the amount of phosphor particles and the amount of binder The lower the weight ratio between is, the more disadvantageous.
[0010]
However, by increasing the weight ratio of phosphor to binder, for example by reducing the amount of binder, a means of producing a sharper image is due to the brittleness and insensitivity of the coated phosphor layer in the screen. Sufficient elasticity results in unacceptable operating characteristics of the screen.
[0011]
One method for obtaining a thinner coated phosphor layer without changing the pigment and binder coverage is to use at a temperature above the melting or softening point of the thermoplastic elastomer, as described in EP-A 0 393 662. A method of compressing a coating layer containing both components is used. Another method which does not use a compression manufacturing method is proposed in WO 94/0531, in which the binding medium comprises one or more rubbery and / or elastomeric polymers and the improved elastic modulus of the screen It offers high protection against mechanical damage, high operability, high pigment to binder ratio, and improved image quality, especially sharpness. Previous literature on improving the sharpness of radiation image storage panels relates to adding colorants to the panel. For example, in U.S. Pat. No. 4,394,581, a dye or colorant is added to the panel, so that the average reflectance of the panel in the wavelength range of the stimulus line for the stimulable phosphor is such that the stimulable phosphorescent light when stimulated The average reflectance of the panel in the wavelength range of the light emitted by the body is made smaller.
[0012]
U.S. Pat. No. 4,491,736 describes organic colorants which do not emit light at wavelengths longer than the wavelength of the stimulating rays, especially when exposed. EP-A 0 165 340 and the corresponding US Pat. No. 4,675,271 describe storage phosphor screens which exhibit better resolution by incorporating dyes. Similar effects provided by the introduction of dyes or colorants in the phosphor layer of the image storage panel are further described in EP-A 0 253 348 and the corresponding US Pat. No. 4,879,202 and EP-A 0 2888038.
[0013]
Radiation image storage panels dyed with dyes to further improve the resolution are disclosed in EP-A-0866469 and corresponding US Pat. No. 5,905,014, comprising triarylmethanes having at least one aqueous alkali-soluble group as colorant. Dye is present in at least one of the support, the phosphor layer or an intermediate layer between the support and the phosphor layer. It is preferred to apply the dye to the interlayer between the support and the phosphor layer and / or to the support only, since the presence of the colorant in the storage phosphor layer may burden the screen speed (sensitivity). . The presence in the interlayer (also referred to as an "antihalation undercoat" or "AHU") between the support (the support is a reflective support) and the phosphor layer is the best relationship for speed and sharpness. Give clearly. However, disadvantages arising from the (almost essential) use of different binder materials in both the storage phosphor and the AHU layer are the completeness of both layers, especially in light of the operation and repeated use (reuse) of the storage phosphor panel. Its lack for good adhesion.
[0014]
Summary of the Invention
Accordingly, an object of the present invention is to provide an adhesive between a storage phosphor layer and an intermediate AHU layer that provides long-term repetition in addition to excellent sharpness without speed loss, even in harsh operating environments. It is to provide a radiation image storage panel which shows no disadvantages. The above-mentioned desirable effect is that, as stated in claim 1, a supported layer of storage phosphor particles dispersed in a binding medium and, adjacent thereto, between said layer and a support having reflective properties A radiation image storage panel comprising: a layer arrangement of an intermediate layer between the layer and the support, wherein the layer arrangement is located closer to the support, the antihalation undercoat layer containing one or more dyes. A radiation image comprising: an adhesion improving layer positioned closer to the layer of storage phosphor particles, wherein the adhesion improving layer is cured to a lower extent than the antihalation undercoat layer. This is achieved by providing a storage panel.
[0015]
Particular features of preferred embodiments of the invention are set out in the dependent claims.
[0016]
Further advantages and embodiments of the present invention will become apparent from the following description.
[0017]
Detailed description of the invention
To prevent loss of screen speed, it is important that there be little or no colorant transfer from the interlayer to the storage phosphor layer, in addition to the presence of the reflective support. This is because migration of the dye (colorant) and the resulting presence of the colorant in the phosphor layer may result in a loss of speed when coated on a support having reflective properties. A significant degree of cure of the intermediate AHU layer provides less migration of the dye present in the AHU layer, but results in poor adhesion between the more cured AHU and the storage phosphor layer. According to the invention, a solution is provided by providing a layer arrangement of an intermediate layer between said phosphor layer and said reflective support, said layer arrangement comprising said support having reflective properties (preferably polyethylene terephthalate). An antihalation layer located closer to the substrate (also referred to as a "PET") and an adhesion improving layer located closer to the phosphor layer, both layers (together when combined) In a preferred embodiment of the present invention, it has a thickness of 0.5 μm to 20 μm, more preferably 1 μm to 10 μm. The system has an effect on the mechanical properties of the panel, such as bonding and cohesive strength, and on the non-migratory properties of the antihalation dye. The effect of improving the adhesion by the adhesion improving layer (also referred to as “AIL”) is due in particular to the difference in solvent solubility and / or swelling rate of the antihalation layer (“AHU”), It should be significantly lower than the solvent solubility and / or swelling ratio of the improved layer.
[0018]
The radiation image storage panel according to the invention preferably comprises a polyethylene terephthalate support having reflective properties as a support, wherein a light-reflecting layer is present between the support and the phosphor layer or light-reflecting particles are present in the support. Is mixed in. More preferably, a white pigment is incorporated into the support. In the case of a light-reflecting layer, said layer may be by deposition of a metal such as aluminum, lamination of a metal foil such as an aluminum foil, or by coating a binder solution containing a white powder such as titanium dioxide, barium sulfate, magnesium titanate. , But is not limited thereto. The white powder may be mixed in a PET support. Some of the light travels toward the interface between the phosphor layer and the support (in the opposite direction of the photosensor), while light other than passing through or absorbed by the support is reflected by the support. Into the optical sensor where it is converted to an electrical signal. Thus, the light that is converted to an electrical signal by the light sensor is the sum of the light that directly enters it and the light that enters it after being reflected by the support.
[0019]
The phenomenon that light emitted by the phosphor particles is absorbed by and / or passes through the support can be prevented by providing a light-reflective support as described above. Providing a light-reflective support has a detrimental effect on the stimulus line: a portion of the stimulus line passes through the phosphor layer without stimulating the phosphor particles in the phosphor layer and the light-reflective support When reaching, the stimulus rays are reflected by the support and are widely distributed within the phosphor layer. As a result, both the target phosphor particles and the phosphor particles present outside thereof are stimulated, thereby converting the light emitted by these phosphor particles into electrical signals and producing therefrom by regenerating therefrom. The sharpness of the image is reduced. However, the presence of the dye-loaded "AHU", carefully selected to absorb the stimulus rays as described above, avoids scattering of the stimulus rays and loss of resolution. The antihalation dye applied to the antihalation layer has a maximum absorption wavelength of 633 ± 35 nm (633 nm is the emission wavelength of the He-Ne laser); a molar extinction coefficient of at least 50,000; emission of a stimulable phosphor of 390-400 nm. It should have substantially no absorption at wavelength; and a negligible appearance of J-aggregation. Preferred dyes are from the group such as leukoindaniline, merostyrilazomethine, azoaniline and the like. Particularly preferred are the dyes or colorants in the AHU layer used in the following examples, the formulas of which are given in the examples but are not limited thereto.
[0020]
In a further preferred embodiment according to the invention, both layers forming the intermediate layer arrangement of at least two layers as described above have the same (polymer) binder material. The polymer binder of both layers is from the group consisting of polyester, acrylate, urethane modified polyester, urethane acrylate, vinyl acetate, melamine formaldehyde resin, polyisocyanate, thermoplastic rubber, epoxidized heteroterechelic polymer, polyvinyl alcohol and siloxane It preferably consists of a selected soluble polymer or curable monomer and oligomer.
[0021]
In the radiation image storage panel according to the present invention, the solvent solubility of the antihalation layer is less than 1%, while the increase in mass swell is less than 20% and the mass swell is in a ratio of 50/30/20 (see above). The ratio is expressed in weight percent (wt%)) and is measured after immersing a 5 cm × 5 cm sample of the panel in a solvent mixture of methylcyclohexane / toluene / butyl acetate at 25 ° C. for 10 minutes. The solvent solubility of the antihalation layer (AHU), expressed in%, is measured from a separate coating of the AHU on the support, where the AHU is cured to the same extent as the radiation panel.
[0022]
Otherwise, in the radiation image storage panel according to the invention, the solvent solubility of the adhesion-improving layer is greater than 3%, while the mass swell is greater than 20%, said mass swell being 50/30/20. Measured after immersing a sample of the panel in a solvent mixture of methylcyclohexane / toluene / butyl acetate present at a weight percent ratio for 10 minutes at 25 ° C. The solvent solubility of the adhesion improving layer (AIL), expressed in%, is again measured from a separate coating of the AIL on the support, where the AIL is cured to the same extent as the radiation panel.
[0023]
The radiation image storage panel according to the invention is characterized by a solvent solubility of the adhesion-improving layer (AIL) consequently greater than 3%, while the mass swell increase is greater than 20%, said increase being the same as above. It is measured in the same manner as for the solvent mixture.
[0024]
The aforementioned solvent combinations were chosen to carry out the tests of the examples below and to characterize the reflective properties of both sublayers (AIL and AHU) of the interlayer arrangement between the support and the storage phosphor layer. I have.
[0025]
According to the present invention, in said panel, the preferred ratio of said swelling ratio between AIL and AHU is at least from 11:10 to 10: 1, more preferably in the range of 2: 1 to 5: 1, Was immersed in a solvent mixture of methylcyclohexane / toluene / butyl acetate in a ratio of 50/30/20% by weight, i.e. a 5 cm x 5 cm sample of the storage phosphor panel for 10 minutes at 25 [deg.] C in the same solvent as the solubility test described above. It will be measured later. Calculation of the change in thickness of both layers as measured by microscopy can also give the ratio of swelling ratios, which should be understood as representing the relative increase in thickness of both sublayers. is there.
[0026]
In a further preferred embodiment, the radiation image storage panel according to the invention is characterized by a "cross-cut" value, which comprises only one layer between said reflective support and said storage phosphor layer. Image storage panels having a multilayer arrangement of intermediate layers are considerably better when compared to radiation image storage panels for use.
[0027]
For a radiation image storage panel according to the invention, when applied to the layer arrangement as described in DIN 53151, a "crosscut" value of less than 20% is obtained.
[0028]
As a further feature according to the invention, the radiation image storage panel is at least 95% for the antihalation layer and at least 90% for the middle two layer arrangement, measured after curing at 90 ° C. for 30 minutes, It is preferred to show the non-migration percentage of the antihalation dye or colorant, where the optical density of "AHU" and "AHU + AIL" is before and after immersion for 10 minutes in the same solvent combination as previously applied, respectively. Is measured and the percentage is calculated from the ratio of the optical densities thus measured.
[0029]
According to the present invention, there is provided a radiation image storage panel, wherein an antihalation undercoat layer (AHU) is higher in the wavelength range of the stimulating lines than in the wavelength range of the lines emitted by the stimulable phosphor upon stimulation. One or more dyes that provide an average absorption to the antihalation undercoat layer, wherein the non-migration percentage of the antihalation dye is at least 95% for the antihalation layer and at least 90% for the layer configuration (AHU + AIL). Both were cured at 90 ° C. for 30 minutes, the percentages being 10 minutes after immersing the panel samples in a solvent mixture of methylcyclohexane / toluene / butyl acetate at 25 ° C. present in a 50/30/20% by weight ratio. Measured.
[0030]
As a result, the radiation image storage panel comprises two layers (between the supported layer of storage phosphor particles dispersed in the binding medium and the adjacent polyethylene terephthalate support having storage properties and reflective properties). One is an antihalation layer (AHU) (which enhances sharpness) and the other is an adhesion improving layer (AIL)), said layers having a total thickness of 0.5 μm to 20 μm. Said layer provides an improved effect on the mechanical properties of the panel, such as bonding and cohesive strength, due to the non-migratory properties of the antihalation dye present in the fully cured AHU layer, and is therefore severe. Allows frequent reuse, even under conditions of operation and frequent use, and avoids speed loss.
[0031]
According to the present invention there is provided a method for manufacturing a radiation image storage panel as described above, wherein said layer arrangement (AHU + AIL) is selected from the group consisting of doctor blade or dip coating, screen printing and spraying. Coated by a coating technique, the curing of the layer arrangement is performed by a curing technique selected from the group consisting of thermal curing, UV / EB (electron beam) curing and solvent evaporation.
[0032]
A short description of the important parameters addressed above and applied in the following examples is given below.
[0033]
Anti-halation undercoat (AHU) and adhesion improving layer (AIL)Curing degreeDegree of curing is observed in the present invention by parameters such as "dye-migration", "swelling factor", and "solvent solubility".
[0034]
“Dye migration"" Is measured by comparing the optical density of the AHU layer or AHU + AIL layer arrangement before and after immersion of the layer in the solvent mixture described.
[0035]
“Swelling rate"Is measured by weight, or alternatively by surface area gain. The weight gain or mass swelling of the layer sample is measured after immersion in the solvent at a temperature of 25 ° C. for 10 minutes. Complete radiation image Layer "in storage panel layer configurationSwelling rate"Is determined by immersing a sample of the panel in a solvent at the constant temperature and time described above, and then measuring (microscopically) the increase in cross-sectional surface thickness for the layer to be measured.
[0036]
Panel mechanical propertiesIs “cross cutAfter further application of the "cross-cut" (using the test equipment 1542M0003 "Brave Instruments" Belgium), which is further measured by the "test" (defined as DIN 53151-ISO 2409-ASTM D 3359-NBN T22-107 standard). The tape (TESA tape # 4324) was applied and peeled to allow determination of bond and cohesive strength.
[0037]
In the phosphor layer of the storage panel according to the invention, an increase in the volume ratio of the phosphor to the binder further provides a reduction in the thickness of the coating layer for the same phosphor coverage and provides even better sharpness. Not only does it provide higher speed or sensitivity. Particular improvements in image sharpness can be achieved using the thermoplastic rubber binders cited in WO 94/0531. This is because a thin phosphor layer is possible with a large phosphor to binder ratio. A rubbery binder is preferably chosen. Because they enable a high pigment to binder volume ratio, provide excellent physical properties and image quality, and provide enhanced speed. In that case, small amounts of binder do not result in a layer that is too brittle, and the minimum amount of binder in the phosphor layer provides sufficient structural adhesion to the layer. Especially for storage phosphor members, this factor is very important in terms of the operation of exposing said members. Preferably, the weight ratio of phosphor to binder is from 80:20 to 99: 1. Preferably, the volume ratio of phosphor to binder medium is greater than 85/15. In this connection, a volume ratio of phosphor to binder greater than 92/8 is almost unacceptable and is almost the maximum of said volume ratio. Mixtures of one or more thermoplastic rubber binders can be used in the coated phosphor layer: preferably the binder medium is a rubber and / or elastomeric polymer, as described in WO 94/00530, with a saturated elastomeric center. It consists essentially of one or more block copolymers having blocks and thermoplastic styrene end blocks. A particularly suitable thermoplastic rubber used as a block copolymer binder in the phosphor screen according to the present invention is KRATON-G rubber (KRATON is SHELL, trade name of the Netherlands). Preferably, the phosphor layer has a binding polar functionality of at least 0.5%, a thickness in the range of 10-1000 μm, and a volume ratio of 92: 8 or less.
[0038]
A storage panel as described above may, according to the present invention, be provided with at least one antioxidant which prevents yellowing of the screen. Preferably, an antioxidant is incorporated into the phosphor layer. The coating dispersion may further contain a filler (reflective or absorbent).
[0039]
As is well known, the sensitivity of a screen depends on the chemical composition of the phosphor, its crystal structure and grain size characteristics, and the weight of the phosphor coated in the phosphor layer. The image quality, in particular the sharpness, is determined in particular by the optical scattering phenomena in the phosphor layer, which mainly depends on the packing density, besides the phosphor layer thickness mentioned above. The packing density of the phosphor particles depends on the grain size distribution of the phosphor particles, their morphology and the amount of binder present in the phosphor layer.
[0040]
Another factor that determines the sensitivity of the screen is the thickness of the phosphor layer, which is proportional to the amount of phosphor coated. Said thickness may be in the range 10-1000 μm, preferably 50-500 μm, more preferably 100-300 μm.
[0041]
Present as the sole phosphor or as a mixture of phosphors, apart from different chemical compositions, the coverage of the phosphor present in one or more phosphor layers in the screen is 1 m²Is preferably in the range of about 50 g to 2500 g, more preferably 200 g to 1750 g, even more preferably 300 to 1500 g. The one or more phosphor layers can have the same or different layer thicknesses and / or different weight ratio amounts of pigment to binder, and / or different phosphor particle sizes or particle size distributions. It is common knowledge that sharper images with less noise are obtained using smaller average size phosphor particles, but the light emission efficiency decreases with decreasing particle size. Thus, the best average grain size for a given application is a compromise between the desired imaging speed and image sharpness. The preferred average particle size of the phosphor particles is in the range from 2 to 30 μm, more preferably in the range from 2 to 20 μm.
[0042]
In the phosphor layer, the phosphor or phosphor mixture can be covered by an object which has to be obtained with a manufactured storage phosphor screen. In addition to mixing fine particle phosphor with coarser particle phosphor to increase packing density, a grain size gradient may be created in the storage panel if necessary. In principle, this is possible by coating only one phosphor layer using gravity, but in terms of reproducibility, the phosphor layer comprising the phosphor or the phosphor mixture according to the invention. May be coated in the presence of a suitable binder. The layer closest to the support then consists essentially of small phosphor particles or a mixture of different batches thereof having an average particle size of about 5 μm or less, on which an average of 8-20 μm for coarse phosphor particles is present. It consists of a mixed particle layer having a particle size. The small phosphor particles are optionally present in the interstices of the large phosphor particles dispersed in a suitable binder. Depending on the requirements sought, the stimulable phosphors according to the invention or their mixtures can be arranged in various ways in these coating configurations.
[0043]
Obviously, within the scope of the present invention, the choice of phosphor or phosphor mixture is limited by the fact that the radiation image storage panel has a wavelength range of the stimulating radiation located between 500 and 700 nm. In a further preferred embodiment according to the invention, the radiation image storage panel has a wavelength range of light between 350 and 450 nm emitted by the stimulable phosphor when stimulated.
[0044]
The radiation image storage panel according to the invention can use, for example, a divalent europium-doped barium fluorohalide phosphor. In this case, the halogen-containing moiety
(1) it can be stoichiometrically equivalent to a fluorine moiety, such as in a phosphor described in US Pat. No. 4,239,968;
(2) it can be present in a stoichiometrically small amount relative to the fluorine moiety, as described, for example, in EP-A $ 0021342 or 0345904 and US Pat.
(3) As described in, for example, US Pat. No. 4,535,237, a large amount can be present stoichiometrically with respect to the fluorine moiety.
[0045]
According to U.S. Pat. No. 4,239,968,
(I) causing the visible or infrared stimulable phosphor to absorb the radiation that has passed through the subject,
(Ii) stimulating the phosphor with a stimulating ray selected from visible and infrared to release the energy of the radiation stored therein as fluorescence, wherein the phosphor is an alkaline earth metal A method for recording and reproducing a radiation image characterized by at least one phosphor selected from the group of fluorohalide phosphors is claimed.
[0046]
From the stimulation spectrum of the phosphor, it can be seen that this type of phosphor has high sensitivity to stimulating light of a He-Ne laser beam (633 nm), but has poor photostimulability below 500 nm. it can. The stimulated light (fluorescence) is in the wavelength range of 350-450 nm and has a peak at about 390 nm (see periodicals, Radiology, September 1983, p. 834).
[0047]
From U.S. Pat. No. 4,239,968, it is desirable to use a visible (e.g. red) stimulable phosphor rather than an infrared stimulable phosphor, because the trap of the infrared stimulable phosphor is a visible light stimulable phosphor. It can be seen that the radiation image storage panel, which is narrower than these and thus contains the infrared-stimulable phosphor, exhibits a relatively rapid dark decay (fading). To solve the problem, use a photostimulable storage phosphor having a trap as deep as possible to avoid fading, as described in US-A-4,239,968, and to substantially empty the trap, It is desirable to use a light beam having a relatively high photon energy (a short wavelength line).
[0048]
There have been plans to formulate phosphor compositions that exhibit a stimulation spectrum where the emission intensity at a stimulation wavelength of 500 nm is greater than the emission intensity at a stimulation wavelength of 600 nm. Phosphors suitable for the above purpose and suitable for use in the storage panel of the present invention are described in US-A 4,535,238 as divalent europium-activated fluorobromide having a stoichiometric bromine-containing moiety beyond fluorine. It is described in the form of a barium phosphor. According to U.S. Pat. No. 4,535,238, photostimulation of the phosphor can be effected efficiently with light, even in the wavelength range from 400 to 550 nm.
[0049]
BaFBr: Eu used in digital radiography²⁺Storage phosphors have relatively high X-ray absorption in the range of 30-120 keV (this is the range for general medical radiography), but the absorption is, for example, LaOBr: Tm, Gd₂O₂S: Tb and YTaO₄: Less than the X-ray absorption of most prompt emitting phosphors used in screen / film radiography, such as Nb. Thus, a screen containing the light emitting luminescent phosphor will absorb a larger fraction of the irradiated X-ray dose than a BaFBr: Eu screen of the same thickness. Since the signal-to-noise ratio (SNR) of the X-ray image is proportional to the square root of the absorbed X-ray dose, the image produced by the light emitting screen is consequently produced by a BaFBr: Eu screen having the same thickness. The noise will be less than the image. The higher fraction of the X-ray dose will be absorbed when using a thicker BaFBr: Eu screen. However, the use of a thick screen results in the diffusion of light at large distances in the screen, which results in a loss of resolution. For this reason, x-ray images made with a digital radiograph using a BaFBr screen, as described in US Pat. No. 4,239,968, give a more noisy impression than images made with a screen / film radiograph. A more suitable way to increase the X-ray absorption of the phosphor screen is by increasing the intrinsic absorption of the phosphor. In a BaFBr: Eu storage phosphor suitable for use in the present invention, this can be advantageously achieved by partially replacing bromine with iodine. BaFX: Eu phosphors containing high amounts of iodine, as described, for example, in EP-A 0142734, are suitable for use in the panels according to the invention. The relative brightness of the storage phosphor should be as high as possible. The reason is that the sensitivity of the storage phosphor system is proportional to the storage phosphor brightness, and apart from high X-ray absorption, the high sensitivity of the system thus developed is essential for reducing image noise. is there. Thus, in a phosphor such as described in EP-A-1 014 732, the improvement in image quality is offset by a decrease in relative brightness due to the high absorption of X-rays when more than 50% of iodine is contained. You.
[0050]
Suitable divalent europium-activated barium fluorobromide phosphors for use in the panels according to the invention are further described in EP-A 0 533 236 and the corresponding US Pat. Nos. 5,422,220 and 5,547,807. EP-A 0 533 236 claims a divalent europium-activated stimulable phosphor, in which the stimulated light is 550 nm light more than when the stimulation is performed at 600 nm light. When the stimulus is performed, the intensity is higher. In said phosphor it is stated that the "small part" of bromine is replaced by chlorine and / or iodine. This fraction must be understood to be less than 50 atomic%.
[0051]
Further divalent europium-activated barium fluorobromide phosphors suitable for use in the panel according to the invention are described in EP-A 0 533 234. EP-A 0 533 234 describes a method for preparing europium-doped alkaline earth metal fluorobromide phosphors, in which fluorine is present in a greater atomic% than bromine and clearly in the shorter wavelength region. With the stimulus spectrum shifted. Among them, the use of short wavelength light for photostimulation of a phosphor panel containing phosphor particles dispersed in a binder is advantageous for image sharpness. This is because the diffraction of the stimulating light in the phosphor-binder layer containing the dispersed phosphor particles acting as a grating decreases with decreasing wavelength. As is evident from the examples in this EP-A 0 533 234, the ultimately obtained phosphor composition determines the optimum wavelength for its photostimulation, and thus a special scanning system comprising a scanning light source which emits light in a narrow wavelength range. Determine the sensitivity of the phosphor at
[0052]
Another preferred photostimulable phosphor according to the aforementioned application is 10 to 10 Ba.^-1It contains an alkaline earth metal selected from the group consisting of Sr, Mg and Ca in atomic% in the range of ２０20 atomic%. Of the alkaline earth metals, Sr is most preferred for increasing the X-ray conversion efficiency of the phosphor. Thus, in a preferred embodiment, it is recommended that strontium be present in stoichiometric combination with barium and fluorine at a greater atomic percentage than bromine alone or bromine in combination with chlorine and / or iodine.
[0053]
Yet another preferred photostimulable phosphor suitable for use in a panel according to the invention is 10 to Ba.^-3-10^-1At atomic% in the atomic% range, it contains a rare earth metal selected from the group consisting of Ce, Pr, Nd, Gd, Tb, Dy, Ho, Er, Tm, Yb and Lu. Among the rare earth metals, Gd is preferred for obtaining the maximum shift of the photostimulation spectrum of the phosphor to short wavelengths. The preferred phosphors of the aforementioned application are also preferred for use in the present invention. However, as described above, the condition is that the wavelength range of the stimulating ray is between 500 and 700 nm.
[0054]
Yet another preferred photostimulable phosphor for use in the panel according to the invention is 10 to Ba.^-1It contains a trivalent metal selected from the group consisting of Al, Ga, In, Tl, Sb, Bi and Y in atomic% in the range of -10 atomic%. Of the trivalent metals, Bi is preferred for obtaining the highest shift of the photostimulation spectrum of the phosphor to short wavelengths. Preferred phosphors for use in accordance with the present invention are other phosphors in which fluorine is stoichiometrically present in greater than bromine alone or in combination with bromine in combination with chlorine and / or iodine. Phosphor which is present at 3-12 atomic% more than bromine or bromine combined with chlorine and / or iodine.
[0055]
Yet another particularly suitable barium fluorobromide phosphor for use in a panel according to the present invention is a primary dopant Eu.²⁺In addition, it contains at least Sm as a co-dopant as described in EP-A 0 533 233 and the corresponding US Pat. No. 5,629,125. Still other useful phosphors suitable for use in the panels of the present invention are those wherein Ba ions are partially replaced by Ca ions on the surface of the phosphor as described in EP-A-0 736 586. is there.
[0056]
In digital radiography, for the phosphors included for use in the storage panel according to the invention, it is advantageous to use photostimulable phosphors which can be stimulated very efficiently by light having a wavelength greater than 600 nm. Can be. Because then the choice of a small reliable laser that can be used for stimulation (e.g. He-Ne, semiconductor laser, solid state laser, etc.), the choice of laser type is to read (stimulate) the stimulable phosphor screen. This is because it becomes very large so as not to determine the size of the device. However, it is clear that the choice of dye present in the AHU layer should be adapted to the wavelength of the stimulus light source. More recent stimulable phosphors which give good signal-to-noise ratios, high speeds and can also be stimulated at wavelengths above 600 nm are described in EP-A-0 835 920 and corresponding US-A's 5853946 and 6045722. Among them, it provides high X-ray absorption combined with high intensity of light stimulated emission, thus via the reduced level of X-ray noise and the reduced level of fluorescence noise, at the same time high sharpness and low A group of storage phosphors is described which makes it possible to construct a storage phosphor system for radiography which produces an image with a noise content. Further, the photostimulable phosphors of the above group provide high X-ray absorption combined with the high intensity of the photostimulated luminescence, and the photostimulated luminescence of the photostimulated luminescence when stimulated with light having a wavelength above 600 nm. Shows the high strength. The photostimulable phosphor can be further used in a panel for medical diagnosis, whereby the amount of X-rays projected on the patient can be reduced and the image quality of the diagnostic image is enhanced: wavelength range above 600 nm In a panel containing the phosphor in a dispersed form when photostimulated with light at, an image with a very high signal-to-noise ratio is produced.
[0057]
A very useful and preferred method for the preparation of stimulable phosphors is described in Research {Disclosure} Vol. 358, February 1994, p. 93, $ item $ 35841. This is incorporated herein by reference. Even in the presence of co-dopants that affect the location of the stimulus spectrum, for example samarium or alkali metals, which are added in small amounts to the raw material mixture of the substrate material as described in EP-A 0 533 234, A solution has been proposed in US Pat. No. 5,551,034 for making phosphors having a given stimulation spectrum for use in storage phosphor panels.
[0058]
Among them, a method for recording and reproducing a transmitted radiation image including the following steps has been proposed:
(I) causing the stimulable storage phosphor to absorb the transmitted radiation passed through or emitted by the subject and store the energy of the transmitted radiation;
(Ii) stimulating the phosphor with stimulating light to release at least a portion of the stored energy as fluorescence;
(Iii) detecting the stimulus light,
And wherein the phosphor comprises a mixture of two or more individually prepared divalent europium-doped barium fluorohalide phosphors, at least one of which is characterized by a stimulation spectrum characteristic of the co-doped phosphor. Is characterized by containing a co-dopant which is determined jointly. In practice, for example, the highest in the stimulation spectrum for the lithium-melted stimulable europium-activated barium fluorohalide phosphor can be found between 520 and 550 nm, while for the cesium-melted phosphor the highest. Is located between 570 and 630 nm. The highest for the stimulation spectrum of the phosphor can be found at intermediate wavelengths after making the mixture. The stimulus spectrum of the mixture is further characterized in that the emission intensity at 500 nm stimulation is always lower than the emission intensity at 600 nm. The resulting broadening of the stimulation spectrum is another advantage resulting from the method of making the mixture, in that storage panels incorporating the stimulable phosphor are sensitive to a wide range of stimulation wavelengths in the visible range of the wavelength spectrum. As a result, a storage panel comprising a layer having a phosphor mixture as described above can offer universal applicability in terms of stimulation with different stimulus light sources. Different stimulus light sources that can be applied include Research {Disclosure} No. 308117 (December 1989).
[0059]
The radiographic screen according to the present invention can be manufactured by the following manufacturing method.
[0060]
Obviously, the choice of the stimulus light source is crucial to the choice of the AHU colorant. This is because the coloring agent or the dye promotes the maximum absorption of the stimulating light in the AHU.
[0061]
The phosphor layers in the panels used in the present invention can be used as well as the use of useful dispersants, useful plasticizers, useful fillers and primers or interlayer compositions as described extensively in EP-A-0510753. The support can be applied to the support by any coating method that employs a solvent for the binder of the phosphor-containing layer.
[0062]
The phosphor particles may be mixed with the dissolved rubber and / or elastomeric polymer at a suitable mixing ratio to form a dispersion. The dispersion is uniformly applied to the substrate by known coating methods such as, for example, doctor blade coating, roll coating, gravure coating or wire bar coating, and then dried and fluoresced by X-ray irradiation (hereinafter referred to as luminescent layer). ). Another mechanical action, such as compression, to reduce the void ratio is not required within the scope of the present invention.
[0063]
Dispersants useful for improving the dispersibility of the phosphor particles dispersed in the coating dispersion include various additives that can be added to the phosphor layer, such as the phosphor particles and the binder in the phosphor layer. EP-A 0 510 753, together with a plasticizer to increase the bond between them, which may be provided with the same or another colorant. Useful plasticizers include phosphates such as triphenyl phosphate, tricresyl phosphate and diphenyl phosphate; phthalates such as diethyl phthalate and dimethoxyethyl phthalate; glycolates such as ethyl phthalyl ethyl glycolate and butyl phthalyl butyl glycolate; Polymeric plasticizers include polyesters of aliphatic dicarboxylic acids and polyethylene glycols such as polyesters of succinic acid and diethylene glycol and polyesters of adipic acid and triethylene glycol.
[0064]
The stimulable phosphor preferably protects against the effects of moisture by chemically or physically attaching a hydrophobic or hydrophobizing substance thereto. Suitable substances for this purpose are described, for example, in U.S. Pat. No. 4,138,361, and more recently in EP-A 1 286 364 and 1 286 365. It describes the protection by a p-xylylene polymer film against highly moisture-sensitive alkali metal halide phosphors as described in EP-A-111458 and PCT application WO 01/3156. When present in the storage panel of the present invention, a powdered or ground phosphor having the same composition as described therein is advantageously protected against moisture. Preference is given to the powdered or pulverized phosphor CsX: Eu stimulable phosphor, wherein X represents a halide selected from the group consisting of Br and Cl. Such a phosphor is EuX '², EuX '³And EuOX '(X' is an element selected from the group consisting of F, Cl, Br and I), and 10 to 5 mol% of a europium compound selected from the group consisting of CsX and CsX, and the mixture is heated at 450 ° C. It is preferably made by burning at the above temperatures, cooling the mixture and recovering the CsX: Eu phosphor. Most preferably, CsBr: Eu is considered as a stimulable phosphor within this group of phosphors.
[0065]
Additional layers can be coated on the support as a backing layer or as a layer interposed between the support and the intermediate layer, between the intermediate layer and the phosphor-containing layer. Some of the additional layers may be applied in combination.
[0066]
In the preparation of a phosphor screen having a subbing layer between the support or substrate and the phosphor-containing layer, the subbing layer is pre-applied on a substrate and coated with another layer by the method according to the invention described above.
[0067]
Sonication can be applied to improve packing density and to degas the phosphor-binder combination. Prior to application of the protective coating, the phosphor-binder layer was calendered to a packing density (i.e. 1 cm dry coating).³(Grams of phosphor for). After applying the coating dispersion on the underlying interlayer arrangement as applied to the panel according to the invention, the coating dispersion is gradually heated and dried to complete the formation of the phosphor layer. To remove as much air entrained in the phosphor coating composition as possible, it can be subjected to sonication prior to coating. After formation of the phosphor layer, a protective layer is generally provided on top of the fluorescent layer.
[0068]
The relative features of roughness and thickness of the protective coating provided on the screens of the present invention, having desirable and surprising properties of excellent image sharpness and ease of operation, are described in EP-A-0 510 754. According to a preferred embodiment, the coating of the protective layer is effected here by screen printing (silk screen printing or rotary screen printing as described in EP-A No. 0510753).
[0069]
Radiation-curable compositions that are very useful for forming protective coatings are as major components:
(1) a crosslinkable prepolymer or oligomer,
(2) reactive diluent monomers,
(3) combined with a polymer soluble in diluent monomer
And in the case of UV curable,
(4) Photo initiator
It contains.
[0070]
Examples of suitable prepolymers for use in the radiation-curable composition applied to the storage panel according to the invention include: unsaturated polyesters, such as polyester acrylates; urethane-modified unsaturated polyesters, such as urethane- Polyester acrylate. Liquid polyesters having an acrylic end group, such as unsaturated copolyesters having an acrylic end group, are disclosed in published EP-A 0207257 and in Radiat. {Phys. {Chem. {Vol. 33, no. 5,443-450 (1989). The latter liquid copolyester is substantially free of low molecular weight unsaturated monomers and other volatiles and is of very low toxicity (see Adhasion 1990 1990 Heft 12, page 12). A wide variety of methods for producing radiation-curable acrylic polyesters are given in DE-A 28 38 691. Mixtures of two or more of the above prepolymers may be used. A survey of UV curable coating compositions is described, for example, in "Coating" 9/88, p. 348-353.
[0071]
When the radiation curing is carried out with ultraviolet radiation (UV), the presence of a photoinitiator in the coating composition allows the prepolymers and their desired cross-linking to effect the polymerization of the monomers and the curing of the coated protective layer composition. It acts as a catalyst to start. A photosensitizer can be present to enhance the effect of the photoinitiator. Suitable photoinitiators for use in the UV curable coating composition are organic carbonyl compounds such as benzoin ether compounds such as benzoin isopropyl, isobutyl ether; benzyl ketal compounds; ketoxime esters; benzophenone compounds such as benzophenone. Acetophenone compounds, such as acetophenone, trichloroacetophenone, 1,1-dichloroacetophenone, 2,2-diethoxyacetophenone, 2,2-dimethoxy-2-phenylacetophenone; thioxanthone compounds, such as 2-benzoylmethylbenzoate; Chlorothioxanthone, 2-ethylthioxanthone; and 2-hydroxy-2-methyl-propiophenone, 2-hydroxy-4'-isopropyl-2-methylpropiophenone, - belonging to the group of such hydroxycyclohexyl phenyl ketone. A particularly preferred photoinitiator is 2-hydroxy-2-methyl-1-phenyl-propan-1-one, a product of the trade name DAROCUR {1173, E. M., Darmstadt, Germany. Commercially available from MERCK. The above-mentioned photopolymerization initiators can be used alone or as a mixture of two or more. Examples of suitable photosensitizers include, for example, certain aromatic amino compounds as described in GB-A 131456, 1486911, US-A-4255513 and merocyanines and carbostyryl compounds as described in US-A 4282309. is there. When using ultraviolet radiation as a curing source, the photoinitiator to be added to the coating solution also absorbs, to a lesser or greater extent, the light emitted by the phosphor, thereby emitting in particular UV or blue light When a phosphor is used, the sensitivity of the radiographic screen will be impaired. Therefore, electron beam curing can be more effective.
[0072]
The protective coating of the storage panel of the present invention, following the coating step, provides an embossed structure by passing the uncured or slightly cured coating through a nip of a pressure roller. The roller in contact with the coating in this case has, for example, a micro-relief structure which gives the coating an embossed structure so as to obtain a relief part as described in EP-A-455309 and 456318, for example. Another suitable method for forming a patterned structure in a plastic coating by means of an engraved chill roll is described in U.S. Pat. No. 3,959,546.
[0073]
According to another example, the patterned or embossed structure is a gravure roller operated with a radiation-curable liquid coating composition (Hepler viscosity at a coating temperature of 25 ° C. is 450-20,000 mPa.s.). Alternatively, it can be obtained in advance in the coating stage by applying the paste-like coating composition with a screen printing device.
[0074]
Radiation curing takes place immediately or almost immediately after application of the liquid coating to avoid flattening of the embossed structure under the influence of gravity, viscosity and surface shear. The rheological behavior or flow properties of the radiation-curable coating composition can be controlled by so-called flow agents. For that purpose, alkyl acrylate ester copolymers containing lower alkyl (C1-C2) and higher alkyl (C6-C18) ester groups can be used as shear control agents to reduce viscosity. The addition of a pigment, such as colloidal silica, increases the viscosity.
[0075]
The radiation-curable coating composition of the radiographic product of the present invention may contain various other optional compounds, such as compounds for reducing electrostatic charge accumulation, plasticizers, matting agents, lubricants, antifoaming agents and the like. Can be contained as described in (1). The literature gives a non-limiting investigation of X-ray conversion screen phosphors, photostimulable phosphors and binders of phosphor-containing layers, as well as devices and methods for curing.
[0076]
The edges of the screen, which can be particularly damaged by many operations, are covered with a polymer material essentially formed from the moisture-cured polymer composition made according to EP-A 0 541 146. Can be enhanced by
[0077]
Support materials for radiographic screens according to specific examples of the present invention include plastic films, such as cellulose acetate, polyvinyl chloride, polyvinyl acetate, polyacrylonitrile, polystyrene, polyester, polyethylene terephthalate, polyethylene naphthalate, polyamide, polyimide, cellulose. Triacetate and polycarbonate films; metal sheets such as aluminum foil and aluminum alloy foil; plain paper; baryta paper; resin-coated paper; pigment paper containing titanium dioxide and the like; and paper sized with polyvinyl alcohol and the like. As already mentioned, examples of preferred supports include transparent or blue- or black-colored polyethylene terephthalate (eg LUMIRROR {C, type {X30}, supplied by Toray Industries, Tokyo, Japan), TiO.₂Or BaSO₄Including polyethylene terephthalate filled with. Metals such as, for example, aluminum, bismuth, etc., may be applied, for example, by vapor deposition to obtain a polyester support having the desired radiation reflection properties required for a support having reflection properties that are advantageous for speed. These supports can have different thicknesses depending on the material of the support, and can generally have a thickness of 50 to 1000 μm, more preferably 80 to 500 μm, depending on the handling characteristics. Further, a glass support may be used.
[0078]
Usually, the screens described above are used for medical X-ray diagnostic applications, but according to a specific example, the radiographic screens of the present invention provide higher energy X-rays or γ-rays than for medical X-rays. It can also be used in nondestructive inspection (NDT) of metal objects to be used. Particularly in such applications, glass and metal supports are further used, the latter being preferably of high atomic weight, as described, for example, in US Pat. Nos. 3,872,309 and 3,389,255. According to a specific example for industrial radiography, the image sharpness of the phosphor screen is determined by the method of {Research} Disclosure {1979} in the phosphor screen between the phosphor-containing layer and the support and / or on the back side of the support. Improved by incorporating an additional pigment-binder layer containing a non-fluorescent pigment which is a metal compound, for example a lead salt or oxide, as described in September, {item # 18502}.
[0079]
To obtain a reasonable signal-to-noise ratio (S / N), the stimulating light should be prevented from being detected with the fluorescence emitted upon photostimulation of the storage phosphor. Accordingly, a suitable filter means is used to prevent stimulating light from entering the detection means, such as a photomultiplier tube. Because the intensity ratio of the stimulating light is significantly greater than that of the stimulated emission light, ie, 10⁴: 1-10⁶: 1 (see column 5 of published EP-A No. 0007105), a highly selective filter should be used. Suitable filter means or filter combinations can be selected from the group of cut-off filters, transmission band-pass filters and band-reject filters. A survey by filter type and spectral transmission grade was published by A. Wiley-Interscience, Publication-John, Wiley, & Sons (1973), New York, edited by Woodlief Thomas, Jr., SPSE Handbook, on August 26, 2006 ing.
[0080]
The fluorescence emitted by the light stimulus is preferably detected optoelectronically with a converter that converts light energy into electrical energy, for example a phototube (photomultiplier) that provides a sequential electrical signal that can be digitized and stored. After storage, these signals can be subjected to digital processing. Digital processing includes, for example, image contrast enhancement, spatial frequency enhancement, image subtraction, image addition, and contour definition of specific image portions.
[0081]
According to one example for the reproduction of a recorded X-ray image, the optionally processed digital signal is converted into an analog signal, which is used, for example, by an acousto-optic modulator to modulate a writing laser beam. The modulated laser beam is then used to scan a photographic material, for example, a silver halide emulsion film that reproduces an X-ray image in an optionally imaged state. According to another example, a digital signal obtained from an analog-to-digital conversion of an electrical signal corresponding to light obtained via light stimulation is displayed on a cathode ray tube. Before display, the signal may be processed by a computer. Conventional image processing techniques can be applied to reduce the signal-to-noise ratio of the image and to enhance the image quality of the radiographic coarse or fine image features.
[0082]
【Example】
While the invention will be described in connection with preferred embodiments thereof, it will be understood that it is not intended to limit the invention to those embodiments.
[0083]
[Table 1]

Mowilith @ CT5 is a vinyl acetate-crotonic acid copolymer.
Cymel # 300 is a modified melamine formaldehyde resin (hexamethoxymethylmelamine).
[0084]
Thermal curing was performed at a temperature of 90 ° C. for at least 30 minutes.
The formula for the AHU colorant is given below.
Embedded image

[0085]
Of a comparative antihalation layer (cured for 30 minutes) as determined by immersing a sample (5 cm x 5 cm) in a 50/30/20 wt% solvent mixture of methylcyclohexane / toluene / butyl acetate at 25 ° C for 10 minutes.Non-migration percentage of antihalation dyeEffect of thermosetting temperature on:
The percent non-migration is calculated from the optical density of the dye or colorant when comparing the densities measured at the AHU layer at a wavelength of 633 nm before and after the immersion test.
[0086]
[Table 2]

[0087]
It is clear from the results obtained that higher curing temperatures increase the curing of the AHU layer and reduce the transfer of antihalation dyes or AHU colorants to AIL.
[0088]
[Table 3]

Desmodur {N} 75 is an aliphatic polyisocyanate (hexamethylene-1,6-diisocyanate).
Thermal curing was performed at 60 ° C. for 1 hour.
[0089]
[Table 4]

Kraton @ FG1901X is a functionalized styrene-ethylene / butylene-styrene block copolymer (thermoplastic rubber).
Kraton @ EKP-207 is a heterotelechelic polymer comprising a primary hydroxyl function at one end of the polymer and an epoxidized isoprene function at the other end.
Thermal curing was performed at 60 ° C. for 1 hour.
[0090]
[Table 5]

Thermal curing was performed at 90 ° C. for 30 minutes.
[0091]
[Table 6]

Thermal curing was performed at 40 ° C. for 4 hours.
[0092]
Summary of results
Single layer cure
(The test is carried out with a solvent mixture of methylcyclohexane / toluene / butyl acetate in a ratio of 50/30/20 wt%, immersion time is 10 minutes)
[Table 7]

[0093]
As will be described in detail in the foregoing and following preferred embodiments of the invention, numerous modifications may be made without departing from the scope of the invention as defined in the claims that follow a given embodiment. It will be apparent to those skilled in the art what can be done therein.
[0094]
Parameters for single and combined two-layer systems
(The test for determining the% non-migration was carried out with a solvent mixture of methylcyclohexane / toluene / butyl acetate in a ratio of 50/30/20 wt%).
[Table 8]

[0095]
Mowilith / Cymel Effect-ratio of curing degree of antihalation layer and adhesion improving layer type 3
After the layer is cured at 90 ° C. for 30 minutes, the solvent solubility and the amount of increase in mass swelling are measured by immersing in a mixture of methylcyclohexane / toluene / butyl acetate (50/30/20% by mass) for 10 minutes.
AIL= Adhesion improving layer //AHU= Antihalation (dye) layer
[0096]
[Table 9]

[0097]
As is evident from the data given above, the two layer arrangement combines the improved adhesion of the phosphor layer with the prevention of migration of the antihalation dye on the screen.

Claims (8)

A radiation image storage panel comprising: a supported layer of storage phosphor particles dispersed in a binding medium; and, adjacent thereto, a layer arrangement of an intermediate layer between the layer and a support having reflective properties. An antihalation undercoat layer containing one or more dyes, wherein the arrangement is located closer to the support, and an adhesion improving layer located closer to the layer of storage phosphor particles; A radiation image storage panel, wherein the improvement layer is cured to a lower degree than the antihalation undercoat layer. The radiation image storage panel according to claim 1, wherein in the layer arrangement, the antihalation undercoat layer and the adhesion improving layer together have a thickness of 0.5 μm to 20 μm. 3. The support according to claim 1, wherein the support is a polyethylene terephthalate support having reflective properties, and a light reflecting layer is present between the support and the phosphor layer or light reflecting particles are mixed in the support. 3. A radiation image storage panel according to item 1. A radiation image storage panel according to any of the preceding claims, wherein a "crosscut" value of less than or equal to 20% is obtained when applied to the layer arrangement as described in DIN # 53151. The undercoat layer includes one or more dyes that provide a higher average absorption in the antihalation undercoat layer in the wavelength range of the stimulus line than in the wavelength range of the line emitted by the stimulable phosphor upon stimulation. The non-migration percentage of the antihalation dye is at least 95% for the antihalation layer and at least 90% for the layer arrangement, both are cured at 90 ° C. for 30 minutes, said percentage being 50/30 / 5. A radiation image storage panel according to any of the preceding claims, measured after immersing a sample of the panel for 10 minutes in a solvent mixture of methylcyclohexane / toluene / butyl acetate at 25 [deg.] C present in a ratio of 20% by weight. . A solvent of methylcyclohexane / toluene / butyl acetate wherein the solvent solubility of the antihalation layer is less than 1%, the mass swelling ratio is less than 20%, and the mass swelling ratio is 50/30/20% by weight. The radiation image storage panel according to any one of claims 1 to 4, which is measured after immersing a 5 cm x 5 cm sample of the panel in the mixture at 25C for 10 minutes. The solvent solubility of the adhesion improving layer is greater than 3%, while the increase in mass swell is greater than 20%, and the mass swell is 50/30/20% by weight of methylcyclohexane / toluene / butyl acetate. The radiation image storage panel according to any one of claims 1 to 4, which is measured after immersing a sample of the panel in a solvent mixture at 25C for 10 minutes. The ratio of the mass swelling ratio of the antihalation undercoat layer to the adhesion improving layer is at least in the range of 11:10 to 10: 1, and the mass swelling ratio is 50/30/20% by weight of methylcyclohexane / toluene / 5. A radiation image storage panel according to any of the preceding claims, measured after immersing a 5 cm x 5 cm sample of the storage phosphor panel in a solvent mixture of butyl acetate at 25 [deg.] C for 10 minutes.