EP0065877B1

EP0065877B1 - Industrial x-ray system

Info

Publication number: EP0065877B1
Application number: EP82302617A
Authority: EP
Inventors: Thomas D. Lyons; Peter B. Jamieson
Original assignee: Minnesota Mining and Manufacturing Co
Current assignee: 3M Co
Priority date: 1981-05-26
Filing date: 1982-05-21
Publication date: 1986-08-06
Also published as: AU8413882A; JPH0473136B2; AR241831A1; ES8308075A1; AU550866B2; MX157370A; BR8203024A; DE3272443D1; EP0065877A1; ZA823627B; CA1196733A; JPS57198456A; ES512479A0

Description

Field of the invention

This invention relates to a novel, high definition, industrial radiographic system. The system uniquely combines fine grain silver halide emulsion photographic film and a light-emitting phosphor screen.

Background of the art

Nondestructive testing of articles and materials has become an integral part of quality control in modern manufacturing industries. This type of testing enables on-line and intensive evaluation of the structural soundness of products. One of the most commonly used forms of nondestructive testing is radiographic images taken on industrial materials. Industrial X-rays have been used for many years in the testing of support beams used in the construction of buildings, bridges and the like. They are particularly useful in the evaluation of welds and in testing metal plates for minute flaws which could affect performance.
As industrial demands on materials become more stringent and the tolerance for flaws becomes reduced, more precise testing methods are required. In all imaging processes, including photography and radiography, there is an inherent limit in the resolution available through the process because of the physical elements used. In the practice of modern industrial X-ray procedures, the use of intensifying screens adds a further limit on the resolution available in radiographs. It has heretofore been generally accepted that the phosphor grains in intensifying screens and the screens themselves were the limiting factor in the graininess or resolution available in radiographs used in nondestructive testing (cf. Nondestructive Testing, 2d Ed. Warren J. McGonnagle, Science Publishers, 1971, .pages 119-123, Radiography in Modern Industry, 3d Ed., Eastman Kodak, 1969, pages 34-38, and Physics of Industrial Radiology, R. Halmshaw, London, Heywood Books, 1966, pp. 110 and 176). This limitation was believed to be a result of the fact that visible radiation emitted from the phospor grain is spread out rather than projected in a linear path like the incident X-rays.
Radiographic emulsions used in industrial screen/film X-ray procedures typically have emulsions where the average grain size is above 0.5 micrometers (e.g., U.S. Patent No. 3,922,545, col. 13, lines 25-46) and generally over 1 micrometer (e.g., U.S. Patent No. 3,753,714, col. 4, lines 34-40). U.S. Patent Nos. 4,177,071 and 4,130,428 discloses a range of 0.25 to 1.2 micrometers for the grain size, butthe examples are only of emulsions having average grain sizes of 0.5, 0.6, 0.7 and 0.8 micrometers.

Description of the invention

According to a first aspect of the present invention there is provided an industrial radiographic system comprising two high energy particle radiation intensifying screens sandwiching a radiation sensitive element which comprises: a base, a decolorizable dye underlayer on at least one side of the base, a first silver halide emulsion layer over said dye underlayer, and a second silver halide emulsion layer on the other side of said base, wherein both of said silver halide emulsion layers are spectrally sensitized to the wavelength of radiation emitted by said screens when struck by high energy particle radiation characterized in that the average size of the silver halide grains in the emulsions are between 0.05 and 0.4 micrometers. The screens may be X-ray intensifying screens. Preferably the average size is between 0.075 and 0.35 micrometers and most preferably between 0.10 and 0.25 or even 0.20 micrometers. The silver halide grains must be sensitized to light emitted by the intensifying screens when struck by X-rays. Dye sensitization of the silver halide is well understood in the art. Upon determination of the emission spectrum of the particular phosphor selected, one can readily select sensitizing dyes which are known to sensitize silver halide crystals to the appropriate region of the spectrum, usually between 400 and 780 nanometers. Preferably the silver halide is sensitized to a spectral range within 25 nanometers of the maximum wavelength emission of the screen (Amax), more preferably within 15 nm, and most preferably within 10 nm.
According to a second aspect the invention also provides a process for the non-destructive testing of industrial materials which comprises placing an industrial material between a controlled X-ray source and the radiographic system, directing X-rays from the source through the industrial material and into said radiographic system at an angle approximately perpendicular to said intensifying screens to generate a latent image in said first and second silver halide imaging layers.
Conventional industrial radiographic processes and materials utilize emulsions having a high concentration of silver which is used to absorb X-rays. Some of the consequences of using these high concentrations of silver include long processing times (e.g., in the neighborhood of ten to twelve minutes), long drying times, and high material costs.
Radiographic emulsions used in the practice of the present invention should have silver coating. weights less than 10 g Ag/m² and preferably between 3 and 8 grams of silver per square meter. The most preferred range is between 3 and 7 g/m² of silver. These films have enabled complete processing times to be reduced to as little as ninety seconds.
The process would be performed by using a conventional X-ray projection source or other high energy particle radiation sources including gamma and neutron sources. As well known in the art, the particular phosphor used should have a high absorption coefficient for the radiation emitted from the source. Usually this radiation is high energy particle radiation which is defined as any of X-rays, newtrons and gamma radiation. The industrial material would be placed between the controllable source of X-rays and the industrial radiographic system of the present invention. A controlled exposure of X-rays would be directed from the source and through the industrial material so as to enter and impact the radiographic system at an angle approximately perpendicular to the plane or surface of the intensifying screen and the photographic film contiguous to the inside surface of the screen. The radiation absorbed by the phosphors of the screen would cause light to be emitted by the screen which in turn would generate a latent image in the two silver halide imaging layers. Conventional development processes including stop baths, washes, fixing, bleaching and the like would then be used on the exposed film.
The silver halide grains may be selected from amongst any of the known photographic silver halide materials such as silver chloride, silver bromide, silver iodide, silver bromoiodide, silver chlorobromoiodide, silver chlorobromide, and the like and mixtures thereof.
The vast list of known photographic adjuvants and processing aids may be used in the practice of the present invention. These materials include gelatin extenders, chemical sensitizers (including sulfur and gold compounds), development accelerators (e.g., onium and polyonium compounds), alkylene oxide polymer accelerators, antifoggant compounds, stabilizers (e.g., azaindenes especially the tetra- and pentaazaindenes), surface active agents (particularly fluorinated surfactants), antistatic agents (particularly fluorinated compounds), plasticizers, matting agents, hardening agents, hardening accelerators, and the like.
The base may be any one of the well known photographic support materials such as glass, polymeric films such as cellulose acetate (and triacetate), polyesters (particularly polyethyleneterephthalate), polycarbonates, polystyrene, and polyvinyl acetal film base. Many other materials may also be used.
The dye underlayer must contain a decolorizable dye. By the term "decolorizable", it is meant that the light absorbing ability of the dye must be substantially diminishable or capable of being completely removed. For example, the dye in the binder which forms the underlayer may be readily soluble in aqueous alkaline solutions used in the processing (developing) of the film element so that the dye would be washed out of the element. The dye could be alkaline solution bleachable, heat bleachable, sulfite bleachable, or removable in any other manner which would not require destruction of the image in the film. There are many ways of accomplishing removability known in the art, but the two preferred means are using dyes which are bleachable in conventional developing solutions, such as those disclosed in Photographic Chemistry, Vol. II, P. Glafkides, 1960, pages 703-704. Heat bleaching of the dyes may be accomplished by selecting dyes which are themselves thermolabile or by combining them with materials which can bleach the dyes when heated. The combination of bleachable dyes with nitrate salts capable of liberating HN0₃, or nitrogen oxides when heated to 160-200°C (as taught in U.S. Patent Application Serial No. 199,426 filed October 22, 1980) are particularly desirable.
The dye underlayer is particularly important because it prevents cross-talk within the radiographic element. Cross-talk occurs when light emitted from one screen passes through one silver halide emulsion and the base into the second silver halide emulsion and forms a latent image there. Because the second emulsion (i.e., the emulsion on the side of the base away from the emitting screen under consideration) is relatively far removed from the screen, the light image is greatly dispersed and the resolution would be greatly reduced. It is, therefore, essential that the dye underlayer absorb radiation of the wavelength emitted by the phosphors.

Examples 1-6

A series of silver halide emulsions with narrow grain size distribution was made in which the grain size was varied from 0.20 to 0.6 micrometers. The emulsions were made using a double jet procedure under controlled pAg conditions. The grains in all cases were iodobromide in composition containing 2.75 mole % iodide and were of cubic habit. The emulsions were handled in the normal manner for coagulating, washing and reconstituting them. The reconstituted emulsions were treated with conventional sulfur and gold sensitizers and were digested at 55°C to increase their sensitivity, cooled to 40°C, and treated with post sensitization additives and stabilizers (namely, tetraazaindines, additional halides, antifoggants, and a spectral sensitizer chosen to provide maximum sensitivity at 550 nm which matches the maximum emission characteristics of 3M's Trimax@ intensifying screen) as is common to the art.
The photographic films were prepared by separately coating the above emulsion onto both sides of a polyester film base which had previously been coated with an aqueous alkaline soluble dye in a gelatin layer. The film base was 1.8x 10-⁴ m. (7 mil) photograde polyester. The emulsions were applied using a precision photographic coating machine. The final coatings contained 5.1 g Ag/m².
These films were then exposed to 125 kVp X-rays at a distance of 122 cm (48 inches) in a cassette containing 3M Trimax@ intensifying screens which are gadolinium, terbium doped oxysulfide phosphor screens. After conventional development, various data were recorded and are shown below in the Table. The noise power was determined by taking a Weinerspectrum (cf. J. Optical Soc. Am. 45, 709-808 (1955)). The results recorded below are given at a frequency of 1 cycle per millimeter in units of microns density.
The dramatic and unexpected improvement in the reduction in graininess can be seen in the greatly reduced noise level achieved according to the practice of the present invention. Further measurement of the images by modulation transfer function (MTF) at 4 cycles/mm revealed that resolution was not sacrificed in the emulsions with reduced graininess. This means that the information content of the film has been substantially increased.

Example 7

This example shows the use of the materials of the present invention in commercial industrial radiographic situations.

Example 8

This is an example of field radiography using a radioactive isotope source.

Example 9

This is an example of aluminum radiography.

Example 10

This is an example of multiple film radiography.
The X-ray intensifying screens used in the practice of the present invention are phosphor screens well known in the art. These phosphors are materials which absorb incident X-rays and emit radiation in a different portion of the electromagnetic spectrum, particularly visible and ultraviolet radiation. Calcium tungstate and rare earth (gadolinium and lanthanum) oxysulfides and gadolinium or lanthanum oxybromides are particularly useful phosphors. The gadolinium oxysulfides and the lanthanum oxysulfides and the phosphates and arsenates can be doped to control the emussion wavelengths and improve their efficiency. Many of these phosphors are shown in U.S. Patent No. 3,725,704 and U.K. Patent No. 1,565,811. The phosphate and arsenate phosphors may be generally represented by the formula
wherein a is 0.01 to 0.50, b is 0 to 0.50, c is 0 to 0.02, d is 0 to 0.10, e is 0 to 0.02 and X represents phosphorous or arsenic atoms or mixtures thereof. Preferable, c is 0, a is 0.05 to 0.30 and d is 0 to 0.02.
The sum of b, c, d and e should be greater than zero and should most preferably be at least 0.005.
The oxysulfide rare earth phosphors may be represented by the formula
wherein Z is'the dopant element or elements,
g is 0 to 1.99, h is 0 to 1.99 and f is 0.0005 to 0.16. Preferably b is 0, a is 0.15 to 1.00, f is 0.0010 to 0.05 and Z is terbium.

Claims

1. An industrial radiographic system comprising two high energy particle radiation intensifying screens sandwiching a radiation sensitive element which comprises:

1) a base,

2) a decolorizable dye underlayer on at least one side of the base,

3) a first silver halide emulsion layer over said dye underlayer, and

4) a second silver halide emulsion layer-on the other side of said base, wherein both of said silver halide emulsion layers are spectrally sensitized to the wavelength of radiation emitted by said screens when struck by high energy particle radiation characterized in that the average size of the silver halide grains in the emulsions are between 0.05 and 0.4 micrometers.

2. The system of claim 1 wherein said screens are X-ray intensifying screens.

3. The system of. claim 2 wherein the average grain size is between 0.075 and 0.35 micrometers.

4. The system of claims 2 or 3 wherein the emulsions are sensitized by at least one sensitizing dye so that the maximum sensitivity of the emulsions is within 25 nanometers of the maximum intensity wavelength emission of the screens.

5. The system of claims 2 and 3 wherein the phosphors of said screens comprise gadolinium oxysulfides, lathanum oxysulfides, gadolinium-lanthanum oxysulfides, gadolinium oxybromides, lanthanum oxybromides, or lanthanum-gadolinium oxybromides.

6. A process for the non-destructive testing of industrial materials which comprises placing an industrial material between a controlled X-ray source and the radiographic system directing X-rays from the source through the industrial material and into said radiographic system at an angle approximately perpendicular to said intensifying screens to generate a latent image in said first and second silver halide imaging layers characterized in that the radiographic system accords to claim 2.