EP0088820B1

EP0088820B1 - Radiographic image conversion screens

Info

Publication number: EP0088820B1
Application number: EP82104798A
Authority: EP
Inventors: Hidehiko Maeoka; Etsuo Shimizu; Yujiro Suzuki; Keiji Shimiya; Norio Miura
Original assignee: Kasei Optonix Ltd
Current assignee: Kasei Optonix Ltd
Priority date: 1982-03-15
Filing date: 1982-06-01
Publication date: 1987-02-04
Also published as: EP0088820A1; KR840000948A; DE3275420D1; KR900004329B1

Description

Background of the invention:

Field of the invention:

The present invention relates to a radiographic image conversion screen. More particularly, it relates to a radiographic image conversion screen, i.e. a radiographic intensifying screen (hereinafter referred to simply as "intensifying screen") or a fluorescent screen, which comprises double phosphor layers i.e. a green emitting rare earth phosphor layer and a blue emitting phosphor layer and which has a high speed and exhibits superior image forming characteristics (in this specification, the "radiographic image conversion screen" includes the intensifying screen and the fluorescent screen).

Description of the prior art:

As is well known, a radiographic image conversion screen is used for medical diagnosis and non-destructive inspection of industrial products, and it emits an ultraviolet ray or a visible ray upon absorption of radiation passed through an object, and thus converts a radiographic image to an ultraviolet image or a visible image.
When the radiographic image conversion screen is used as an intensifying screen for radiography, it is fit on a radiographic film (hereinafter referred to simply as "film") so that a radiation image will be converted on the fluorescent surface of the intensifying screen to an ultraviolet image or a visible image which will then be recorded on the film. On the other hand, when it is used as a fluorescent screen, the radiation image of the object converted on the fluorescent surface of the fluorescent screen to a visible image may be photographed by a photographic camera or may be projected on a television screen by means of a television camera tube, or the visible image thus formed may be observed by naked eyes.
Basically, the radiographic image conversion screen comprises a support made of e.g. paper or a plastic sheet and a fluorescent layer formed on the support. The fluorescent layer is composed of a binder and a phosphor dispersed in the binder and being capable of efficiently emitting light when excited by the radiation of e.g. X-rays, and the surface of the fluorescent layer is usually protected by a transparent protective layer.
For medical diagnosis by means of radiography, a high speed radiographic system (i.e. a combination of a film and an intensifying screen) is desired to minimize the patients' dosage of radioactivity. At the same time, a radiographic system is desired which is capable of providing good image quality (i.e. sharpness, granularity and contrast) suitable for diagnosis by clinical photography. Accordingly, the intensifying screen is desired to have a high speed and to provide superior sharpness, granularity and contrast. Likewise in the case of a fluorescent screen, it is desired to have a high speed and to provide particularly good contrast so that it is thereby possible to minimize the patients' dosage of radioactivity and at the same time to obtain an image having good image quality.
As high speed radiographic image conversion screens, there have been developed radiographic image conversion screens comprising a rare earth oxysulfide phosphor, such as one wherein a terbium-activated rare earth oxysulfide phosphor which is a green emitting phosphor and represented by the formula (Ln, Tb)₂0₂S where Ln is at least one selected from lanthanum, gadolinium and lutetium, is used (US Patent No. 3,725,704), and one wherein a terbium-activated yttrium oxysulfide which is a blue emitting phosphor and represented by the formula (Y, Tb)₂0₂S, is used (US Patent No. 3,738,856). Among them, intensifying screens using a green emitting rare earth phosphor, particularly, a rare earth oxysulfide phosphor such as a terbium-activated gadolinium oxysulfide phosphor represented by the formula (Gd, Tb)₂0₂S or a terbium-activated lanthanum oxysulfide phosphor represented by the formula (La, Tb)₂0₂S, have a speed several times higher than the speed of commonly used conventional intensifying screens using a calcium tungstate phosphor represented by the formula CaW0₄ and they have relatively good granularity as compared to other high speed intensifying screens. Therefore, they are utilized in high speed radiographic systems in combination with an orthochromatic-type (hereinafter referred to simply as "ortho-type") film having a wide spectral sensitivity ranging from a blue region to a green region. Meanwhile, in the recent high speed radiographic systems based on a combination of a green emitting rare earth intensifying screen and an ortho-type film, there is a tendency to use a low speed ortho-type film utilizing fine silver halide grains in order to minimize the amount of silver used for the film and to improve the image quality, particularly the granularity, at a high speed level. It is therefore strongly desired to further improve the speed of the intensifying screen with a view to reduction of the patients' dosage of radioactivity and at the same time to improve the sharpness of the intensifying screen, which tends to be reduced with an increase of the speed.
Among the green emitting phosphors, a gadolinium oxysulfide phosphor is particularly preferably used for a high speed intensifying screen. However, it has a K absorption edge at 50.2 KeV, and accordingly, the intensifying screen using it has drawbacks that the contrast thereby obtainable within the X-ray tube voltage range commonly used for medical diagnosis (i.e. from 60 to 140 KV) is inferior due to the X-ray absorbing characteristics of such a phosphor, and the change of the speed of the intensifying screen depending on a change of the tube voltage tends to be great, thus leading to difficulties in setting the condition of radiography. US-A-3738856 also teaches the possibility of using mixtures of different phosphors. The cases of an intermit mixture of the particles of both phosphors and of a separation of the particles of both phosphors in separate layers are treated as being equivalent.

Summary of the invention:

It is an object of the present invention to overcome the above mentioned difficulties in the conventional radiographic diagnosis systems wherein radiographic image conversion screens are used, and to provide a radiographic image conversion screen which, when used as an intensifying screen in combination with an ortho-type film, has a speed at least equal to the speed of the conventional intensifying screens using a green emitting rare earth phosphor and is capable of providing an image having superior image quality, particularly superior sharpness and contrast without degradation of the granularity, and which is less dependent in its speed on the X-ray tube voltage as compared with the conventional intensifying screens.
Another object of the present invention is to provide a radiographic image conversion screen which, when used as a fluorescent screen in association with a photographic camera or an X-ray television system, has a speed at least equal to the speed of a conventional fluorescent screen using a green emitting rare earth phosphor and is capable of providing an image having an improved contrast over the conventional fluorescent screen.
As a result of extensive studies on various phosphors used for the fluorescent layers of the radiographic image conversion screens and various combinations thereof, the present inventors have found that the above objects can be accomplished by a radiographic image conversion screen with a green emitting rare earth phosphor and a blue emitting phosphor on a support, characterised in that a first fluorescent layer consisting essentially of the blue emitting phosphor is provided between the support and a second fluorescent layer consisting essentially of the green emitting rare earth phosphor.
Thus, the present invention provides a radiographic image conversion screen which comprises a support, a first fluorescent layer formed on the support and consisting essentially of a blue emitting phosphor and a second fluorescent layer formed on the first fluorescent layer and consisting essentially of a green emitting rare earth phosphor.
The radiographic image conversion screen of the present invention has a fluorescent layer composed essentially of a blue emitting phosphor interposed between the support and the fluorescent layer composed essentially of a green emitting rare earth phosphor, and thus is capable of emitting blue and green lights, and it has a speed at least equal to the speed of the conventional radiographic image conversion screens comprising only the green emitting rare earth phosphor layer. Further, it provides an image having superior image quality, particularly superior contrast, as compared with the conventional radiographic image conversion screens, and when used as an intensifying screen in combination with an ortho-type film, it provides improved sharpness over the conventional intensifying screens and the dependability of its speed against the X-ray tube voltage is thereby improved.

Brief description of the drawings:

Figures 1 and 2 are diagrammatic cross sectional views of the radiographic image conversion screens of the present invention.
Figure 3 is a graph illustrating an emission spectrum according to a conventional radiographic image conversion screen.
Figures 4 and 5 are graphs illustrating emission spectra according to the radiographic image conversion screens of the present invention.
Figures 6 and 7 are graphs illustrating the relative speed and relative sharpness, respectively, dependent on the proportion of the blue emitting phosphor in the radiographic image conversion screens of the present invention.
Figure 8 is a graph illustrating the relative speeds of the radiographic image conversion screens of the present invention and the conventional radiographic image conversion screen, dependent on the X-ray tube voltage.

Detailed description of the preferred embodiments:

Now, the present invention will be described in detail.
The radiographic image conversion screen of the present invention can be prepared in the following manner.
Firstly, suitable amounts of the blue emitting phosphor and a binder resin such as nitrocellulose are mixed, and a suitable amount of a solvent is added to the mixture to obtain a coating dispersion of the phosphor having an optimum viscosity. The coating dispersion of the phosphor is applied onto a support made of e.g. paper or plastic by means of a doctor blade, roll coater or knife coater. In some intensifying screens, a reflective layer such as a white pigment layer, an absorptive layer such as a black pigment layer or a metal foil layer is interposed between the fluorescent layer and the support. Likewise, when the radiographic image conversion screen of the present invention is to be used as an intensifying screen, a reflective layer, an absorptive layer or a metal foil layer may be preliminarily formed on a support and then a blue emitting phosphor layer may be formed thereon in the above mentioned manner. Then, a coating dispersion comprising a green emitting rare earth phosphor and a binder resin such as nitrocellulose, is prepared in the same manner as described above, and the coating dispersion thus prepared is applied onto the blue emitting phosphor layer to form a fluorescent layer composed essentially of the green emitting rare earth phosphor. The support thus coated with the two phosphor layers capable of emitting lights of different colours, is then subjected to drying to obtain a radiographic image conversion screen of the present invention. In most cases, radiographic image conversion screens are usually provided with a transparent protective layer on the fluorescent layer. It is preferred also in the radiographic image conversion screens of the present invention to provide a transparent protective layer on the fluorescent layer composed essentially of the green emitting phosphor.
In a case where the green emitting rare earth phosphor to be used has a mean grain size or specific gravity substantially greater than the mean grain size or specific gravity of the blue emitting phosphor to be used, the process may advantageously be modified in such a manner that firstly a protective layer is formed on a flat substrate such as a glass plate or a plastic sheet, and then a coating dispersion composed of a mixture comprising the green emitting rare earth phosphor, the blue emitting phosphor and a binder resin, is coated on the protective layer and gradually dried at room temperature while controlling the ambient atmosphere. During this step of drying the coating dispersion, the green emitting rare earth phosphor grains having a greater mean grain size or specific gravity will settle to form an under layer while the blue emitting phosphor grains having a smaller mean grain size or specific gravity are pushed upwardly to form a top layer, whereby two separate fluorescent layers, i.e. a top layer composed essentially of the blue emitting phosphor and an under layer composed essentially of the green emitting rare earth phosphor, are obtainable. Then, the integrally formed protective and fluorescent layers are peeled off from the substrate, and placed on a support so that the top layer composed essentially of the blue emitting phosphor is brought in contact with and fixed to the support, whereby a radiographic image conversion screen of the present invention, is obtainable. In this case, the separation between the green emitting rare earth phosphor grains and the blue emitting phosphor grains may not be complete, i.e. a certain minor amount of the green emitting rare earth phosphor grains may be present in the fluorescent layer composed essentially of the blue emitting phosphor and likewise a certain minor amount of the blue emitting phosphor grains may be present in the fluorescent layer composed essentially of the green emitting rare earth phosphor. It has been confirmed that so long as the first fluorescent layer, i.e. the layer adjacent to the support, is composed essentially of the blue emitting phosphor and the second fluorescent layer, i.e. the layer on the surface side (i.e. the emission output side) is composed essentially of the green emitting rare earth phosphor, the radiographic image conversion screen thereby obtainable has characteristics substantially equal to the characteristics of the above mentioned radiographic image conversion screen obtained by separately coating the blue emitting phosphor layer and the green emitting rare earth layer on the support.
Figure 1 shows a diagrammatic cross sectional view of a radiographic image conversion screen of the present invention prepared in the above mentioned manners. A first fluorescent layer 12 consisting essentially of a blue emitting phosphor is provided on a support 11, and a second fluorescent layer 13 consisting essentially of a green emitting rare earth phosphor is formed on the first fluorescent layer 12. Reference numeral 14 designates a transparent protective layer formed on the surface of the second fluorescent layer 13.
Further, the blue emitting phosphor layer of the radiographic image conversion screen of the present invention may be formed in such a manner that firstly the blue emitting phosphor grains are classified into a plurality of groups having different mean grain sizes by means of a proper phosphor grain separation means such as levigation, and the groups of the phosphor grains thus classified are respectively dispersed in a proper binder resin and sequentially applied onto the support and dried so that the phosphor grains having a smaller mean grains are coated first, whereby the blue emitting phosphor layer is formed to have a grain size distribution of the phosphor grains such that the grain size becomes smaller gradually from the side facing the green emitting rare earth phosphor layer to the side facing the support.
Figure 2 shows a diagrammatic cross sectional view of a radiographic image conversion screen of the present invention prepared in the above mentioned manner. A first fluorescent layer 22 composed essentially of a blue emitting phosphor, a second fluorescent layer 23 composed essentially of a green emitting rare earth phosphor and a transparent protective layer 24 are laminated in this order on a support 21. The blue emitting phosphor grains in the first layer 22 are arranged in such a manner that the phosphor grain size becomes smaller gradually from the side facing the green emitting phosphor layer 23 toward the side facing the support 21. Such a radiographic image conversion screen provides substantially improved sharpness over the radiographic image conversion screen illustrated in Figure 1.
The green emitting rare earth phosphors which may be used in the radiographic image conversion screens of the present invention, include a phosphor composed of a terbium-activated rare earth oxysulfide of at least one rare earth element selected from yttrium, lanthanum, gadolinium and lutetium, a phosphor composed of an oxyhalide of the above rare earth elements (provided that the phosphor contains at least 0.01 mole of terbium per mole of the phosphor), a phosphor composed of a borate of the above rare earth elements, a phosphor composed of a phosphate of the above rare earth elements and a phosphor composed of a tantalate of the above rare earth elements. Thus, the green emitting rare earth phosphors contain at least one lanthanide element or yttrium as the host material of the phosphors and are capable of emitting green light with high efficiency when excited by the X-rays. Particularly preferred among them in view of the emission efficiency and granularity, are a terbium activated or terbium-thulium activated rare earth oxysulfide phosphor represented by the formula (Ln₁-a-_b, Tb_a, Tm_b)₂O₂S where Ln is at least one selected from lanthanum, gadolinium and lutetium, and a and b are numbers meeting the conditions of 0.0005≦a≦0.09 and 0≦b≦0.01, respectively, and a terbium activated or terbium-thulium activated rare earth oxysulfide phosphor represented by the formula (Y_1-i-a-b, Ln_i, Tb_a, Tm_b)₂O₂S where Ln is at least one selected from lanthanum, gadolinium and lutetium, and i, a and b are numbers meeting the conditions of 0.65≦i≦0.95, 0.0005≦a≦0.09 and 0≦b≦0.01.
Any blue emitting phosphor may be used for the radiographic image conversion screens of the present invention so long as it is a phosphor capable of emitting blue light with high efficiency when excited by radiation such as X-ray radiation. In practice, however, in view of the speed of the obtainable radiographic image conversion screen and the sharpness of the image thereby obtainable, it is preferred to use at least one selected from the group consisting of a yttrium or yttrium-gadolinium oxysulfide phosphor represented by the formula (Y_1-c-d-e, Gd_c, Tbd, Tm_e)₂O₂S where c, d and e are numbers meeting the conditions of 0≦c≦0.60, 0.0005≦d≦0.02 and 0≦e≦0.01, respectively; an alkaline earth metal complex halide phosphor represented by the formula MeF₂ · pMe'X₂ · qKX' · rMe"SO₄: mEu²⁺, nTb³⁺ where Me is at least one selected from magnesium, calcium, strontium and barium, each of Me' and Me" is at least one selected from calcium, strontium and barium, each of X and X' is at least one selected from chlorine and bromine, and p, q, r, m and n are numbers meeting the conditions of 0.80≦p≦1.5, 0≦q≦2.0, 0≦r≦1.0, 0.001≦m≦0.10 and 0≦n≦0.05, respectively; a rare earth oxyhalide phosphor represented by the formula (Ln'_1-x-y-z, Tb_x, Tmy, Yb_z)OX where Ln' is at least one selected from lanthanum and gadolinium, X is at least one selected from chlorine and bromine, and x, y and z are numbers meeting the conditions of 0≦x≦0.01, 0≦y≦₀.01, 0≦z≦0.005 and 0<x+y; a divalent metal tungstate phosphor represented by the formula M"W0₄ where M" is at least one selected from magnesium, calcium, zinc and cadmium; a zinc sulfide or zinc-cadmium sulfide phosphor represented by the formula (Zn₁-_j, Cd_j)S:Ag where j is a number meeting the condition of O≦j≦0.4; and a rare earth tantalate or tantalumniobate phosphor represented by the formula(Ln"_1-1, Tm_v)(Ta_1-w, Nb₂)O₄ where Ln" is at least one selected from lanthanum, yttrium, gadolinium and lutetium, and v and w are numbers meeting the conditions of 0≦v≦0.1 and 0≦w≦0.3, respectively.
In the radiographic image conversion screens of the present invention, in view of the speed of the obtainable radiographic image conversion screen and the sharpness of the image thereby obtainable, the phosphor to be used for the blue emitting phosphor layer, preferably has a mean grain size of from 2 to 10 µm more preferably from 3 to 6 µm, and a standard deviation of from 0.20 to 0.50, more preferably from 0.30 to 0.45, as represented by the quartile deviation, and the phosphor to be used for the green emitting phosphor layer preferably has a mean grain size of from 5 to 20 um, more preferably from 6 to 12 µm and a standard deviation of from 0.15 to 0.40, more preferably from 0.20 to 0.35, as represented by the quartile deviation. Likewise in view of the speed of the obtainable radiographic image conversion screen and the sharpness of the image thereby obtainable, the coating weight of the phosphor in the blue emitting phosphor layer and the coating weight of the phosphor in the green emitting phosphor layer are preferably from 2 to 100 mg/cm² and from 5 to 100 mg/cm², respectively and more preferably from 3 to 50 mg/cm² and from 20 to 80 mg/cm², respectively. In view of the sharpness of the image obtainable, it is preferred that the mean grain size of the phosphor grains in the blue emitting phosphor layer is smaller than the mean grain size of the phosphor grains in the green emitting rare earth phosphor layer.
Figure 3 shows an emission spectrum according to a conventional radiographic image conversion screen comprising a single fluorescent layer composed solely of (Gdo_0.995, Tb_0.005)₂O₂S phosphor as one of green emitting rare earth phosphors. Figures 4 and 5 show emission spectra obtained by the radiographic image conversion screens of the present invention. In the radiographic image conversion screen illustrated in Figure 4, the blue emitting phosphor layer (the coating weight of the phosphor: 20 mg/cm²) is composed of (Y_0.998, Tb_0,002)₂O₂S phosphor and the green emitting phosphor layer (the coating weight of the phosphor: 30 mg/cm²) is composed of (Gd_0.995, Tb_0,005)₂O₂S phosphor. Whereas, in the radiographic image conversion screen illustrated in Figure 5, the blue emitting phosphor layer (the coating weight of the phosphor: 15 mg/cm²) is composed of BaF₂ · BaCl₂ · 0.1 KCI . 0.1 BaS0₄: 0.06 Eu²⁺ phosphor, and the green emitting phosphor layer (the coating weight of the phosphor: 35 mg/cm²) is composed of (Gd_o.₉₉₅, Tb_O.005)₂O₂S phosphor. In each of Figures 3 to 5, the broken line and the alternate long and short dash line indicate a spectral sensitivity curve of an ortho-type film and a spectral sensitivity curve of an image tube, respectively. It is apparent from the comparison of Figure 3 with Figure 4 or 5, that the radiographic image conversion screen of the present invention has a wide emission distribution ranging from the green region to the blue region or the near ultraviolet region and better matches the spectral sensitivities of the ortho-type film and the photocathode of the image tube than the conventional radiographic image conversion screen comprising a single fluorescent layer composed solely of the green emitting rare earth phosphor, and it is advantageous particularly in view of its high speed.
Figure 6 illustrates a relation between the ratio (represented by percentage) of the coating weight of the phosphor in the blue emitting phosphor layer to the coating weight of the total phosphor in the entire fluorescent layers in the radiographic image conversion screens of the invention and the speed of the radiographic image conversion screens thereby obtained. The relative speed on the vertical axis indicates the speed obtained in combination with an ortho-type film, in a relative value based on the speed of the screen having no blue emitting phosphor layer (i.e. comprising only the green emitting rare earth phosphor layer) where the latter speed is set to be 100. The curves a, b, c, d, e and f represent the cases where the blue emitting phosphor layer is composed of (Y_0,998, Tb_0,002)₂O_sS phosphor, (Gdo.s, Y_0.495. Tb_0.003. Tm_0.002)₂O₂S phosphor, BaF_z- BaCl₂ · 0.1 KCI - 0.1 BaS0₄: 0.06 Eu²⁺ phosphor, (La_0.997, Tb_0.003)OBr phosphor, CdW0₄ phosphor, and CaW0₄ phosphor, respectively. In each case, the total coating weight of the fluorescent layers is 50 mg/cm², and the green emitting rare earth phosphor layer is composed of (Gd_0,995, Tb_0,005)₂O₂S phosphor.
It is apparent from Figure 6 that the optimum ratio of the coating weight of the blue emitting phosphor layer to the total coating weight of the phosphors varies depending upon the type of the blue emitting phosphor used. However, by providing a blue emitting phosphor layer beneath the green emitting phosphor layer composed of (Gd, Tb)₂0₂S phosphor, it is possible to obtain a radiographic image conversion screen having a speed at least equal to the speed of the conventional radiographic image conversion screen comprising a single fluorescent layer composed solely of (Gd, Tb)₂0₂S phosphor (i.e. comprising only the green emitting phosphor layer).
Figure 7 illustrates a relation between the ratio (represented by percentage) of the coating weight of the phosphor in the blue emitting phosphor layer to the total coating weight of the phosphors in the entire fluorescent layers of the radiographic image conversion screens of the present invention and the sharpness of the radiographic image conversion screen. In Figure 7, curves a, b, c, d, e and f represent the cases where the blue emitting phosphor layer is composed of (Y_0,998. Tb_o,_oo2)₂0₂S phosphor, (Gd_0,5, Y_0.495 Tbo.oos, Tm_0,002)₂O₂S phosphor, BaF2. BaCl₂ · 0.1 KC) · 0.1 BaS0₄: 0.06 Eu²⁺ phosphor, (La_0.997, Tb_0.003)OBr phosphor, CdW0₄ phosphor and CaW0₄ phosphor, respectively.
In each case, the total coating weight of the fluorescent layers is 50 mg/cm² and the green emitting rare earth phosphor layer is composed of (Gd_0.995, Tb_0.005)₂O₂S phosphor. The sharpness of each radiographic image conversion screen is determined by obtaining a MTF value at a film density of 1.5 and spatial frequency of 2 lines/mm, and the MTF value is indicated in a relative value based on the MTF value of the radiographic image conversion screen having no blue emitting phosphor layer (i.e. comprising only the green emitting rare earth phosphor layer) where the latter MTF value is set to be 100.
It is apparent from Figure 7 that the radiographic conversion screens of the present invention provided with a blue emitting phosphor layer beneath the green emitting phosphor layer have improved sharpness over the conventional screen having no such a blue emitting phosphor layer.
Figure 8 is a graph illustrating the dependency of the speeds of the radiographic image conversion screens of the present invention and the conventional radiographic image conversion screen, on the X-ray tube voltage. In Figure 8, curves a, b, c, d and e represent the speeds of the radiographic image conversion screens of the present invention in which the blue emitting phosphor layer is composed of (Y_0,998. Tb_0,002)₂O₂S phosphor, BaF₂- BaCl₂ · 0.1 KCI. 0.1 BaS0₄: 0.06 Eu²⁺ phosphor, (La_0.997, Tb_0.003)OBr phosphor, CdW0₄ phosphor and CaW0₄ phosphor, respectively, and the green emitting phosphor layer is (Gdo.₉₉₅, Tb_0.005)₂O₂S phosphor in each case. In each case, the coating weight of the green emitting phosphor is 30 mg/cm² and the coating weight of the blue emitting phosphor is 20 mg/cm². Curve f represents the speed of the conventional radiographic image conversion screen wherein the fluorescent layer is composed solely of (Gd_0,995. Tb_0.005)₂O₂S and the coating weight of the phosphor is 50 mg/cm². The vertical axis of Figure 8 indicates the speed obtained by a combination of each radiographic image conversion screen with an ortho-type film, as a relative value against the speed of the radiographic conversion screen comprising a single fluorescent layer of CaW0₄ phosphor (as combined with a regular-type film). The relative value is spotted for every X-ray tube voltage.
It is seen from Figure 8 that in the radiographic image conversion screens of the present invention, the change of the speed due to the variation of the X-ray tube voltage is less as compared with the conventional radiographic image conversion screen comprising a single fluorescent layer composed of (Gd, Tb)₂0₂S phosphor, within the X-ray tube voltage range of from 60 to 140 KV which is commonly used in the radiography for medical diagnosis.
Further, it has been confirmed that when green emitting rare earth phosphors other than (Gd_0.995. Tb_0.005)₂O₂S are used for the green emitting phosphor layer, or when blue emitting phosphors other than (Y_0.998. Tb_0.002)₂O₂S phosphor, BaF₂- BaCl₂· 0.1 KCI · 0.1 BaS0₄: 0.06 Eu²⁺ phosphor, (La_0.997, Tb_0.003)OBr phosphor, CdW0₄ phosphor and CaW0₄ phosphor are used for the blue emitting phosphor layer, the radiographic image conversion screens thereby obtainable have a speed at least equal to the speed of the conventional screen comprising a single fluorescent layer composed solely of the green emitting rare earth phosphor, so long as the ratio of the coating weight of the phosphor in the blue emitting phosphor layer to the total coating weight of the entire phosphors falls within the specific range, as in the case of the radiographic image conversion screens illustrated in Figure 6, and the sharpness can be improved and the dependency of the speed on the X-ray tube voltage can be reduced as compared with the conventional radiographic image conversion screen comprising a single fluorescent layer composed solely of the green emitting rare earth phosphor, as in the cases of the radiographic image conversion screens illustrated in Figures 7 and 8.
It has further been confirmed that the radiographic image conversion screens of the present invention provides improved contrast as compared with the conventional radiographic image conversion screen comprising only the green emitting rare earth phosphor layer. When used as fluorescent screens for X-ray television systems, they exhibit superior characteristics, especially in their speed and contrast, as compared with conventional fluorescent screens comprising only the green emitting rare earth phosphor layer.
Further, with respect of the granularity and sharpness of the obtainable radiographic image conversion screens, it has been confirmed that better characteristics are obtainable by providing a plurality of fluorescent layers so that the green emitting rare earth phosphor and the blue emitting phosphor constitute the respective separate fluorescent layers provided on the support in the sequences mentioned in the main claim as in the radiographic image conversion screens of the present invention rather than simply mixing the phosphors.
As mentioned in the foregoing, the radiographic image conversion screens of the present invention have a speed at least equal to the speed of the conventional radiographic image conversion screens comprising only a green emitting phosphor layer and they provide improved sharpness and contrast without degradation of the image quality, particularly the granularity, and their speed is less dependent on the X-ray tube voltage and thus provides an advantage that the condition for the operation of radiography can thereby be simplified. Thus, the radiographic image conversion screens of the present invention have a high speed and provide an image having superior image quality, and their industrial value is extremely high.
Now, the present invention will further be described with reference to Examples.
Examples 1 to 26:

Radiographic image conversion screens (1) to (26) were prepared in the following manner with use of the respective combinations of a green emitting rare earth phosphor and a blue emitting phosphor, as identified in Table 1 given hereinafter.

Eight parts by weight of the blue emitting phosphor and one part by weight of nitrocellulose were mixed with use of a solvent to obtain a coating dispersion of the phosphor. This coating dispersion of the phosphor was uniformly coated by means of a knife coater, on a polyethylene terephthalate support provided on its surface with an absorptive layer of carbon black and having a thickness of 250 11m so that the coating weight of the phosphor became as shown in Table 1 given hereinafter, whereby a blue emitting phosphor layer was formed.
Then, 8 parts by weight of a green emitting rare earth phosphor and one part by weight of nitrocellulose were mixed with use of a solvent to obtain a coating dispersion of the phosphor. This coating dispersion of the phosphor was uniformly coated by means of a knife coater on the above mentioned blue emitting phosphor layer so that the coating weight of the phosphor became as shown in Table 1 given hereinafter, whereby a green emitting rare earth phosphor layer was formed. Further, nitrocellulose was uniformly coated on the green emitting rare earth phosphor layer to form a transparent protective layer having a thickness of about 10 pm.

Example 27:

(Y_0.998, Tb_0.002)₂O₂S phosphor having a mean grain size of 5 µm and a standard deviation (i.e. quartile deviation) of 0.35 was preliminarily classified by levigation into four grain size groups, i.e. smaller than 3 um, from 3 to 5 pm, from 5 to 7 µm and larger than 7 µm. Eight parts by weight of each group of the phosphor and one part by weight of nitrocellulose were mixed with use of a solvent to obtain four different coating dispersions of the phosphor. The coating dispersions were sequentially uniformly coated by a knife coater and dried on a polyethylene terephthalate support provided on its surface with an absorptive layer of carbon black and having a thickness of 250 pm in such order that a group of the phosphor grains having smaller grain size was applied first, so that the coating weight of the phosphor of each group became 5 mg/cm², whereby a plurality of fluorescent layers composed of (Y_0.998, Tb_0.002)₂O₂S and having different phosphor grain sizes were formed.
Then 8 parts by weight of (Gd_0,0995, Tb_0.005)₂O₂S phosphor having a mean grain size of 8 µm and a standard deviation (i.e. quartile deviation) of 0.30 and one part by weight of nitrocellulose were mixed with use of a solvent to obtain a coating dispersion of the phosphor. This coating dispersion was uniformly coated by a knife coater on the above mentioned (V_0.998, Tb_0.002)₂O₂S phosphor layer so that the coating weight of the phosphor became 30 mg/cm², whereby a (Gd_o.₉₉₅, Tb_0.005)₂O₂S phosphor layer was formed. Further, nitrocellulose was uniformly coated on the (Gd_0.995. Tb_o._oo5)₂0₂S phosphor layer and dried to form a transparent protective layer having a thickness of about 10 pm. Thus, a radiographic image conversion screen (27) was prepared.
Examples 28 to 30:

Radiographic image conversion screens (28) to (30) were prepared in the following manner with use of the respective combinations of a green emitting rare earth phosphor and a blue emitting phosphor, as indicated in Table 1 given hereinafter.

The green emitting rare earth phosphor and the blue emitting phosphor were preliminarily mixed in the proportions corresponding to the respective coating weights of the green emitting rare earth phosphor layer and the blue emitting phosphor layer. Eight parts of the phosphor mixture and one part of nitrocellulose were mixed together with a solvent to obtain a coating dispersion of the phosphors.
On the other hand, a protective layer was coated on a smooth substrate and dried to have a thickness of 10 p, and the above coating dispersion of the phosphors was then coated on the protective layer so that the total coating weight of the phosphors became 50 mg/cm^2. The coated phosphqr layer was dried by leaving it to stand still at a constant temperature of 15°C for 10 hours while controlling the replacement of ambient air, whereby the green emitting phosphor grains and the blue emitting phosphor grains were settled to separate from one another.
Thereafter, the phosphor layer having the protective layer was peeled off from the flat substrate and heat laminated on a support coated with a thermoplastic binder, whereby a radiographic image conversion screen comprising a double phosphor layer structure, i.e. a first fluorescent layer composed essentially of the blue emitting phosphor and a second fluorescent layer composed essentially of the green emitting phosphor, was obtained.
Examples 31 to 33:

Fluorometallic radiographic image conversion screens (31) to (33) were prepared with use of the respective combinations of a green emitting rare earth phosphor and a blue emitting phosphor, as indicated in Table 2 given hereinafter, in the same manner as in Examples 1 to 26 except that a paper support having a thickness of 250 um and provided on its surface with a lead foil having a thickness of 30 pm was used.

Reference Example R:

As a reference example, a radiographic image conversion screen (R) was prepared in the same manner as in Examples 1 to 26 except that (Gd_o.₉₉₅, Tb_0.005)₂O₂S phosphor having a mean grain size of 8 pm, and a standard deviation (i.e. quartile deviation) of 0.30 was used and a single fluorescent layer having a coating weight of the phosphor of 50 mg/cm² was formed on the support.

Reference Example R':

A radiographic image conversion screen (R') was prepared in the same manner as in Examples 31 to 33 except that the same phosphor as used in Reference Example R was used.

With respect to 30 different kinds of the radiographic image conversion screens (1) to (30) of the present invention and the radiographic image conversion screen (R) prepared as a reference example, their speeds, sharpness, granularity and contrast were investigated as combined with an ortho-type film. The results thereby obtained are shown in Table 1.
It is seen that the radiographic image conversion screens of the present invention are superior to the conventional radiographic image conversion screen (R) in the speed, sharpness and contrast, and no substantial degradation in their granularity was observed.
The radiographic image conversion screens (31) to (33) of the present invention and the radiographic image conversion screen (R') prepared as a reference example, were used for industrial non-destructive inspection. The results thereby obtained are shown in Table 2. The radiographic image conversion screens of the invention were found to be superior to the conventional radiographic image conversion screen (R') in the speed and penetrameter sensitivity. Further, it has been confirmed that the radiographic image conversion screens (31) to (33) can effectively used also for high voltage radiography and cobaltgraphy in medical diagnosis.
With respect to the radiographic image conversion screens (1) to (30) and (R):

The speed, sharpness, granularity and contrast of each radiographic image conversion screen listed in the following Table 1 were obtained by radiography conducted with use of Ortho G Film (manufactured by Eastman Kodak Co.) and the X-rays generated at the X-ray tube voltage of 80 KV and passed through a water-phantom having a thickness of 80 mm. The respective values in the Tables indicate the following values.
- Speed: A relative value based on the speed of a radiographic image conversion screen comprising a fluorescent layer of CaW0₄ phosphor (KYOKKO FS, manufactured by Kasei Optonix, Ltd.) where the latter speed is set to be 100.
- Sharpness: A relative value of the MTF value obtained.
- Sharpness: A MTF value was obtained at a spatial frequency of 2 lines/mm, and it was represented by a relative value based on the MTF value of a radiographic image conversion screen comprising a single fluorescent layer composed solely of (Gd_o.₉₉₅, Tb_0.005)₂O₂S phosphor, obtained at the same spatial frequency, where the latter MTF value was set to be 100.
- Granularity: A RMS value at a film density of 1.0 and spatial frequency of 0.5 to 5.0 lines/mm. Contrast: Photographs were taken through AI having a thickness of 1 mm and Al having a thickness of 2 mm, and the respective contrasts were obtained from the differences of the film densities. Each contrast was represented by a relative value based on the contrast obtained by a radiographic image conversion screen comprising a fluorescent layer composed of CaW0₄ phosphor (KYOKKO FS, manufactured by Kasei Optonix, Ltd.) where the latter contrast was set to be 100.

With respect to the radiographic image conversion screens (31) to 33) and (R'):

The speed and penetrameter sensitivity were obtained by radiography conducted with use of Ortho G Film (manufactured by Eastman Kodak Co.) and a steel plate having a thickness of 20 mm as the object and with X-rays generated at the X-ray tube voltage of 200 KV.
- Speed: A relative value based on the speed of the fluorometalic radiographic image conversion screen (R') where the latter speed is set to be 100.
- Penetrameter sensitivity: Represented by the following formula.

Claims

1. A radiographic image conversion screen with a green emitting rare earth phosphor and a blue emitting phosphor on a support, characterized in that a first fluorescent layer consisting essentially of the blue emitting phosphor is provided between the support and a second fluorescent layer consisting essentially of the green emitting rare earth phosphor.

2. The radiographic image conversion screen according to Claim 1 wherein said green emitting rare earth phosphor is a rare earth oxysulfide phosphor represented by the formula

where Ln is at least one selected from lanthanum, gadolinium and lutetium, and a and b are numbers meeting the conditions of 0.0005≦a≦0.09 and 0≦b≦0.01, respectively, or the formula

where Ln is at least one selected from lanthanum, gadolinium and lutetium, and i, a and b are numbers meeting the conditions of 0.65≦i≦0.95, 0.0005≦a≦0.09 and 0≦b≦0.01, respectively.

3. The radiographic image conversion screen according to Claim 1 or 2 wherein said blue emitting phosphor is at least one selected from the group consisting of

(I) a yttrium or yttrium-gadolinium oxysulfide phosphor represented by the formula

where c, d and e are numbers meeting the conditions of 0≦c≦0.60, 0.0005≦d≦0.02 and 0≦e≦0.01, respectively,

(II) an alkaline earth metal complex halide phosphor represented by the formula

where Me is at least one selected from magnesium, calcium, strontium and barium, each of Me' and Me" is at least one selected from calcium, strontium and barium, each of X and X' is at least one selected from chlorine and bromine, and p, q, r, m and n are numbers meeting the conditions of 0.80≦p≦1.5, 0≦q≦2.0, 0≦r≦1.0, 0.001≦m≦0.10 and 0≦n≦0.05, respectively,

(III) a rare earth oxyhalide phosphor represented by the formula

where Ln' is at least one selected from lanthanum and gadolinium, X is at least one selected from chlorine and bromine, and x, y and z are numbers meeting the conditions of 0≦x≦0.01, 0≦y≦0.01, 0≦z≦0.005 and 0<x+y,

(IV) a divalent metal tungstate phosphor represented by the formula

where M" is at least one selected from magnesium, calcium, zinc and cadmium,

(V) a zinc sulfide or zinc-cadmium sulfide phosphor represented by the formula

where j is a number meeting the condition of 0≦j≦0.4, and

(VI) a rare earth tantalate or tantalum-niobate phosphor represented by the formula

where Ln" is at least one selected from lanthanum, yttrium, gadolinium and lutetium, and v and w are numbers meeting the conditions of 0≦v≦0.1 and 0≦w≦0.3, respectively.

4. The radiograhphic image conversion screen according to Claim 1, or 3 wherein the phosphor in the blue emitting phosphor layer has a mean grain size of from 2 to 10 um, a standard deviation (quartile deviation) of the grain size of from 0.20 to 0.50 and a coating weight of from 2 to 100 mg/cm², and the phosphor in the green emitting phosphor layer has a mean grain size of from 5 to 20 µm, a standard deviation (quartile deviation) of the grain size of from 0.15 to 0.40 and a coating weight of from 5 to 100 mg/_cm2,

5. The radiographic image conversion screen according to Claim 4 wherein the phosphor in the blue emitting phosphor layer has a mean grain size of from 3 to 6 pm, a standard deviation (quartile deviation) of the grain size of from 0.30 to 0.45 and a coating weight of from 3 to 50 mg/cm², and the phosphor in the green emitting phosphor layer has a mean grain size of from 6 to 12 pm, a standard deviation (quartile deviation) of the grain size of from 0.20 to 0.35 and a coating weight of from 20 to 80 mg/cm^2.

6. The radiographic image conversion screen according to any one of Claims 1 to 5 wherein the blue emitting phosphor layer has a grain size distribution of the phosphor grains such that the grain size becomes smaller gradually from the side facing the green emitting rare earth phosphor layer to the side facing the support.

7. The radiographic image conversion screen according to any one of Claims 1 to 6 wherein a reflective layer is interposed between the support and the first fluorescent layer.

8. The radiographic image conversion screen according to any one of Claims 1 to 6 wherein an absorptive layer is interposed between the support and the first fluorescent layer.

9. The radiographic image conversion screen according to any one of Claims 1 to 6 wherein a metal foil is interposed between the support and the first fluorescent layer.