US3783299A

US3783299A - X-ray image intensifier input phosphor screen and method of manufacture thereof

Info

Publication number: US3783299A
Application number: US00254100A
Authority: US
Inventors: J Houston
Original assignee: General Electric Co
Current assignee: General Electric Co
Priority date: 1972-05-17
Filing date: 1972-05-17
Publication date: 1974-01-01
Anticipated expiration: 1991-01-01

Abstract

The surface of a waffle-like metal substrate forms an array of cells for the support for the input phosphor screen of an x-ray image intensifier tube. The hollow projecting walls of the metal surface substantially reduce degradation of image resolution due to lateral scattering of light in the phosphor and thereby permits use of a thicker phosphor screen for higher x-ray absorption and, or higher image resolution. The method of fabricating the phosphor screen includes the intermediate steps of forming rubber and plastic replicas of a metal master of the waffle surface. The plastic replicas are nickel plated to form low cost metal replicas with the plastic being dissolved whereby the projecting walls are hollow.

Description

United States Patent 1191 [1 1 3,783,299 Houston Jan. 1, 1974 [54] X-RAYIMAGEINTENSIFIER INPUT 3,584,216 6/197! Tinney 250/80 PHOSPHOR SCREEN AND METHOD OF MANUFACTURE THEREOF Primary Examiner-Archie R. Borchelt Arr J h F. Ah t a]. [75] Inventor: John M. Houston, Schenectady, omey O n em 57 ABSTRACT [73] Assignee: General Electric Company, The surface of a waffle-like metal substrate forms an Schenectady array of cells for the support for the input phosphor [22] Filed; May 17, 1972 screen of an x-ray image intensifier tube. The hollow projecting walls of the metal surface substantially re- [2]] Appl 254100 duce degradation of image resolution due to lateral scattering of light in the phosphor and thereby permits 521 US. Cl. 250/483, 250/213 VT, 250/486 use of a thicker p p Screen for higher y 51 Int. Cl. H01 j l/62 sorption and, or higher image resolution The method [58] Field of Search 250/80, 213 VT, 483, of fabricating the p p Screen includes the inter- 250/4 313 92 mediate steps of forming rubber and plastic replicas of a metal master of the waffle surface. The plastic repli- 5 R f r Cited cas are nickel plated to form low cost metal replicas UNITED STATES PATENTS with the plastic being dissolved whereby the projecting walls are hollow. 2,689,189 9/1954 Hushley 250/80 X 2,882,413 4/1959 Vingerhoets 250/80 20 Claims, 8 Drawing Figures 7 "I: 9 70 """llllll 'll,"

Pl/UJPl/OR 1" P. 6/ I i 1 i i i 1 5/1/00: 1 Pf 57/1 60 1 \i"" I 4/? /0a/ ////l //1 My invention relates to an x-ray image intensifier tube, and in particular, to the phosphor screen structure at the input end of the tube and method of manufacture thereof.

The x-ray image intensifier tube is especially useful in the medical field for obtaining brighter x-ray images, particularly the image of body organs which generally are of low contrast. Conventional xray image intensifiers employ in the input thereof a uniform layer of a dense high atomic number phosphor for absorbing the incident x-rays which have traversed through a patients body. The x.-ray photon is absorbed in the phosphor layer and light photons in the order of 1,000 light photons for each x-ray photon are generated in the phosphor layer and emitted in all directions from the point of x-ray photon absorption. A thin photoemitting coating deposited on the surface of the phosphor layer emits photoelectrons in response to light photons incident thereof. The photelectrons are accelerated and electron-optically focussed onto a second phosphor screen at the output end of the image intensifier resulting in a brighter image than at the input phosphor screen.

The thickness of the phosphor layer in conventional image intensifiers is typically 5 to 12 mils and is a compromise between a thick layer necessary for high x-ray absorption and a thin layer necessary for high image resolution (a 12 mil thick layer yields a resolution of 40 to 50 line pairs per inch), resolution and contrast degraded due to lateral light scattering within the phosphor layer. As a result, the typical 5-l2 milv thickness phosphor layer in conventional x-ray image intensifier tubes has a relatively low x-ray absorption in the order of 15 to 40 percent of the incident rays. Obviously, it would be highly desirable to employ a thicker phosphor layer in the input end of the x-ray image intensifier tube to thereby increase the x-ray absorption (and thus the sensitivity) but with less loss in resolution and local contrast than occurs in conventional image intensifiers,

or alternatively, use aconventional thickness phosphor layer but with increased reoslution.

Therefore, one of the principal objects of my invention is to provide a new and improved x-ray image intensifier tube having an input phosphor screen which simultaneously can achieve both high x-ray absorption and high image resolution, and the method of manufacture thereof.

Another object of my invention is to providea relatively thick input phosphor screen with means to substantially reduce degradation of resolution and local image contrast due to lateral light scattering in the phosphor and the method of manufacture thereof.

A further object of my invention is to provide a low cost fabrication process for manufacturingiithe improved input phosphor screen.

Briefly stated, and in accordance with my invention, I provide an x-ray image intensifier input phosphor screen wherein a phosphor layer is deposited in the cells formed by hollow wall-like projections on the surface of a waffle-like reflective metal substrate. The cells form an array of equal size squares or hexagons and the phosphor layer extends outward slightly beyond the ends of the metal wall projections. The other side of the metallic substrate, which contains indentations corresponding to the opposite side wall projections, is bonded to the x-ray image intensifier tube face plate which may be formed of glass or a low atomic number metal such as aluminum. The outer surface of the phosphor layer, spaced from the metallic substrate, is smooth and substantially parallel to the majorsurface of the face plate and a thin film of a photoemitter material is deposited thereon. The phosphor layer can be relatively thick and thus obtain increased sensitivity and the metallic cell walls substantially reduce degradation of image resolution and contrast due to lateral scattering of light in the phosphor.

My x-ray image intensifier input phosphor screen is fabricated by the following method. Sheets of metal mesh are formed by photoetching thin metal sheets to produce an array of small holes in the mesh having a square or hexagonal shape. The sheets of metal mesh are superimposed in precise hole alignment and diffusion bonded to a heavy planar metal substrate to thereby obtain a waffle-like surface wherein the wall projections which define an array of cells are each approximately 1.5 to 2 mil wide and the cell width is about 4 to 5 mils. The walls of the cells are then thinned to approximately 0.5 mil width by chemical etching and this metal substrate having a waffle-like surface is used as a master from which silicone rubber replicas are made. Each silicone rubber replica has the wall indentation surface thereof coated with a suitable plastic material and such coated surface is drawn toward a support member having the concave-shape of the x-ray image intensifier face plate. Upon hardening of the plastic, the silicone rubber replica is removed, and the concave-shaped plastic structure has the wall-like projections of the metal master. The plastic replica is treated to be electrically conductive, and is electroplated to form a very thin, high light reflectivity, metal layer on the surface thereof. The plastic material is then dissolved leaving the metallic replica which is transferred to the face plate of the image intensifier tube and bonded to the inner surface thereof. The array of cells formed by the hollow wall projections of the metallic replica are then filledwith a phosphor material which extends slightly beyond the ends of the projecting walls and forms a smooth outer surface upon which a thin uniform coating of a photo-emitter material is deposited to form the photocathode of the x-ray image intensifier tube.

The features of my invention which I desire to protect herein are pointed out with particularity in the appended claims. The invention itsellf, however, both as to its organization and method of operation, together with further objects and advantages thereof may best be understood by reference to the following description taken in connection with the accompanying drawings wherein like parts in each of the several figures are identified by the same reference character, and wherein:

FIG. 1 is an elevation sectional view of a conventional x-ray image intensifier tube;

FIGS. 2a and 2b are top views of two geometries of an array of cells formed by the waffle-like surface on a metallic substrate utilized in fabricating a master in accordance with my invention;

FIG. 3 is an elevation sectional view of bonded sheets of metal mesh which form the waffle-like surface illustrated in FIGS. 2a, 2b, but to a larger scale, and also indicates the thinned walls of the cells occurring after a subsequent etching process;

FIG. 4 is an elevation sectional view, to the same scale of FIG. 1, of a silicone rubber replica of the master illustrated partially in FIG. 3, and also shows a concave support member onto which the silicone rubber replica is pressed to form a plastic replica;

FIG. 5 is an elevation sectional view of the plastic replica formed on the support member in FIG. 4, and also shows a thin metal layer plated on a first part of the plastic replica to form a metallic replica, and the silicone rubber replica being peeled from the plastic replica;

FIG. 6 is an elevation sectional view, to a larger scale than FIG. 5, of the metallic replica formed in FIG. 5 and bonded to the x-ray image intensifier tube face plate, and a phosphor layer deposited on the metallic replica waffle surface; and

FIG. 7 is an elevation sectional view, of the input end structure of my image intensifier tube as shown in FIG. 6 after the phosphor surface has been smoothed and a photoemitter coating deposited thereon.

Referring now in particular to FIG. 1, there is shown a conventional x-ray image intensifier tube comprised of a glass envelope 10 having an input end (face plate) 100 which has a uniform phosphor layer 11 of thickness in the range of 0.005 to 0.012 inch deposited on the inner surface thereof. The phosphor may be zinc cadmium sulfide or cesium iodide as typical materials onto which a thin film 12 of photoemitter material is deposited of thickness of approximately 100 Angstroms. The photoelectrons emitted by the photoemitter coating 12 are focussed by electrode 13a maintained at a potential of several hundred volts and are accelerated to approximately 25 kilovolts by means of electrode 13!; (connected to a suitable DC. voltage source) at the output end of the image intensifier tube, the electrodes being suitably shaped to provide electron-optical focussing of the accelerated photoelectrons onto a second uniform phosphor screen (layer) 14 deposited on the inner surface of the glass envelope at the output end 10b thereof. The image appearing on the second phosphor screen 14 is a brighter version of the image on the first phosphor screen 11 and can be viewed directly by the physician or be subjected to further processing. The paths of two photoelectrons between the photoemitter coating 12 and the second phosphor screen 14 are indicated by dashed line and arrowheads. As stated hereinabove, the thickness of the input phosphor screen 11 in conventional x-ray image intensifier tubes is a compromise between a thick screen for high x-ray absorption and thin screen for high resolution which is determined primarily by lateral light scatter in the phosphor.

My invention provides a new and improved high resolution x-ray image intensifier input phosphor screen which avoids the compromise between the thick and thin phosphor screen by the use of a waffle-like metallic surface wherein hollow wall projections thereof substantially prevent degradation of resolution and local image contrast due to lateral scattering of light in the phosphor. My invention-permits the use of a thicker phosphor screen for achieving higher x-ray absorption without the attendant degradation of resolution and contrast obtained in conventional image intensifiers, or a phosphor screen of conventional thickness but with a significantly higher resolution. The waffle-like metallic surface could be achieved by forming the wall projections which define an array of cells of the waffle pattern, by separation wire elements, however, since it is desired to obtain cells of very small size, in the order of 5 mil width, and have a plurality of such cells of identical size, the fabrication process to be described hereinafter is believed more suitable for providing the consistently equal size cells and projecting walls.

This invention is distinguished in at least the following five respects from a related invention described and claimed in my concurrently filed patent application Ser. No. 254,099 wherein wall-like projections of a waffle-like substrate are (1) solid, the entire substrate is (2) a relatively thick (3) layer having a completely smooth surface and is made of (4) a silicone resin and granular phosphor mixture, and (5) does not require an additional intermediate step in fabrication to produce a plastic replica on which the final replica is formed.

The fabrication process is initiated by selecting sheets of metal suitable for photoetching such as nickel or stainless steel in the order of l or 2 mils thick. This relatively small thickness is chosen since it is easier and more precise to photoetch holes with a depth at least a factor of two smaller than-the hole diameter. An identical pattern (array) of holes is etched through each sheet. The etched holes in the metal mesh sheets preferably have a square or hexagonal shape as illustrated in FIGS. 2a and 2b, respectively, with a center-tocenter hole spacing of approximately 6 mils and separation (wall thickness) of approximately 1.5 to 2 mil as indicated on the drawing. The holes are of equal size and equally spaced from each other and form an array of identical rows and columns of holes to maximize the hole area in the mesh. Other shape holes, such as triangular or circular could be used, however, such shaped holes produce less open area in the mesh.

Upon completion of the photoetching step, the sheets of metal mesh are superposed in precise hole alignment to form an assembly of approximately 10 mils height as one example, the sheets of

metal mesh

30, 31, 32

and 39 being stacked on a heavy planar substrate 40 v of the same metal as the meshand subsequently being diffusion bonded thereto. The approximately 10 mil thick stack of metal mesh is diffusion bonded by bolting the mesh assembly between two massive planes of metal, the upper one of which is thinly coated with an oxide such as MgO to prevent sticking, and this assembly is heated to a suitable temperature (e.g., approximately 1,000C when bonding nickel or stainless steel) in a hydrogen atmosphere or vacuum to accomplish the diffusion bonding. The diffusion bonding results in a waffle-like structure having a surface illustrated by the heavy solid line in FIG. 3 wherein the projecting

walls

41, 42, 43 from the surface of substrate 40 are rectangular in the section taken vertically through the projecting walls. The space between the surrounding walls and substrate 40 will be hereinafter described as a cell and it is obvious that the diffusion bonding step results in a plurality of identical walls wherein FIG. 2a or FIG. 2b represent the top view of the cell structure shown in elevation sectional view in FIG. 3. The

walls

41, 42, 43 of the cells and then thinned to approximately 0.5 mil thickness by a chemical etching process to produce the master substrate structure indicated by dashed line in FIG. 3. The thinned walls are substantially thinner than the corresponding thinned walls described in my aforementioned concurrently filed application Ser. No. 254,099 since the metal that forms such hollow walls in the final structure is merely lightreflective and does not generate light photons whereas in Ser. No. 254,099 such walls are solid and the granular phosphor portion thereof is both light-reflective and generates its own light which contributes to the light generated in the adjacent phosphor laser.

The array of cells formed by the waffle-like surface of the metal master structure in FIG. 3 after the chemical etching process could be filled with a phosphor material to form a phosphor screen, however, the process hereinabove described is relatively expensive and in accordance with my invention, I fabricate many inexpensive metal replicas of such original master whereby the cost per x-ray intensifier tube will be small. Also, at some stage in the process it is necessary to sag the planar surface of substrate 40, that is, to obtain it in a concave-shaped conforming to the shape of the face plate a of the image intensifier tube.

In order to replicate the master illustrated in FIG. 3, an intermediate step of making one or more silicone rubber replicas is utilized. The silicone rubber replica is fabricated by vacuum impregnation wherein the master is convered with a layer of liquid silicon rubber (e.g., General Electric RTV-l l) to which a small amount of a suitable curing catalyst has been added. The coated master is then placed in a vacuum chamber for a few minutes in order to pump away all air bubbles and insure that the silicon rubber contacts all the crevices of the master. The rubber is then allowed to cure for an appropriate period, e.g., 24 hours, in order to form an elastic, rubbery solid. The silicone rubber replica is approximately 50 mils thick in order toregngin somewhat flexible so that it can be subsequently easily removed by peeling from a plastic replica to be described hereinafter.

Referring now to FIG. 4, a support dish member 44 which has the same concave form as face plate 10a of the image intensifier tube is utilized as a form on which to fabricate a plastic replica of the FIG. 3 chemically etched waffle-like metal surface. The support form 44 may be made of virtually any material which is chemically inert to the plastic material and its solvent, glass or stainless steel being two typical materials. A suitable plastic material which readily hardens at room temperature, or at a slightly elevated temperature, such as polymethyl methacrylate (Lucite) or an epoxy resin such as Hysol R8-2038 in the molten state is coated along the wall indented side 45a of the rubber replica 45. The two margins 45b, 0 along the wall indented side 45a of the rubber replica are suitably retained against corresponding planar margins of the concave support dish 44 and the entire assembly is placed within a chamber wherein a vacuum is drawn between the rubber replica 45 and support dish 44 thereby pressing the rubber replica toward the concave form to produce a plastic replica 46 of the FIG. 3 master waffle-like surface except that the plastic replica is curved into the concave shape of the image intensifier tube face plate 10a rather than being planar, as shown in part in FIG. 4.

Upon hardening of the plastic, the silicone rubber replica 45 is removed therefrom by peeling it from the plastic replica 46 as shown in FIG. 5, and the rubber replica may be reused to form additional plastic replicas. The plastic replica 46 is made electrically conductive by evaporating an electrically conductive thin metal coating (of silver, gold or copper as three typical examples) onto the plastic surface. Alternatively, the plastic is rendered electrically conductive by mixing the metal or graphite in powder form into the liquid plastic such that the plastic has bulk conductivity. After the plastic replica has been rendered electrically conductive, a very thin layer 50 (of thickness in the range of 0.2 to 0.5 mil) of a suitable metal such as nickel or other metal having relatively high light reflectivity is electroplated onto the plastic surface.

The plastic material is then dissolved in a suitable solvent such as acetone for the Lucite or Hysol dissolver AC-4079 for the Hysol plastic and the remaining metallic replica 50 is carefully transferred to the inner surface of the concave-shaped face plate 10a of the x-ray image intensifier tube and positioned thereon. The face plate 10a is fabricated of glass or a low atomic number metal such as aluminum.

The metal replica 50 is bonded to the face plate 10a by means of a thin coating 60 of silicone resin as one example to form the structure illustrated in FIG. 6 wherein the hollow wall projections of the metal replica extend normal to the surface of face plate 10a. The array of cells formed by the metal waffle-like surface are filled with a suitable preferably transparent phosphor material using conventional techniques, the phosphor layer extending beyond the ends of the wall projections of the metal replica 50. The phosphor 61 can be a conventional granular phosphor (but of large grain size to obtain high light transmission characteristics) such as silver-activated zinc cadmium sulfide without, or in a silicone resin binder, or, more desirably is a transparent phosphor such as evaporated cesium iodiode (CsI) phosphor. Evaporation of the CsI from vertically above the metal replica 50 results in the outer surface of the phosphor layer 61 having the undulating form 61a shown in FIG. 6 due to the projecting walls of the metal replica. The uneven surface 61a of the phosphor outer surface is mechanically polished in a dry box, since CsI is a relatively soft material, to obtain the smooth surface 61b shown in dashed line. If the indulations are not so severe as to upset either the electron-optics or the formation, and or surface resistivity of the photocathode (to be described hereinafter), then it may not be necessary to smooth out such undulations. The phosphor layer is approximately 12 mils thick as one typical example, and obviously can be made thicker if higher x-ray absorption is desired. Large phosphor grain size herein is defined as particle diameter greater than 0.3 mil.

Referring now to FIG. 7, a thin uniform coating of a suitable photoemitter material is deposited on the smooth surface 61b of the phosphor layer 61 during the evacuation of the image intensifier tube to form the photocathode of such image intensifier tubeQThe photoemitter material may be of the common types known as 8-20 (a compound of antimony, cesium sodium and potassium) or 5-11 (a compound of cesium, antimony and oxygen) as two typical examples and is a very thin coating in the order of Angstroms. If desired, an isolating layer of transparent alumina, as one example, may be deposited between the phosphor 61 and photoemitter 70 layers in order to isolate the alkali metal of the photoemitter material from the phosphor, however, such isolating layer is not essential to the successful operation of my input phosphor screen.

The light reflectivity of the metal replica surface is generally sufficiently high, but can be increased, if desired, by bright-dipping the metal replica (i.e., immersing the replica for a moment in a solution of nitric acide, sulfuric acid and NaCl or by coating it with MgO smoke obtained by burning magnesium. The reflectivity of the metal replica wall projections is not too critical since the height to diameter ratio of each cell is only slightly greater than unity.

The wall-like projections of the metal replica 50 extend normally through at least 50 percent of the phosphor layer 61 thickness, and as shown in FIGS. 6 and 7, typically extend through approximately 80 percent of the phosphor layer. The effect of the relatively high light-reflective wall projection surfaces is to substantially reduce lateral scattering of light in the phosphor and thereby substantially reduce degradation of image resolution and contrast due to such cause. Obviously, the metal master can be made with more sheets of the metal mesh to thereby obtain a metal replica having wall projections of greater height whereby a thicker phosphor layer can be utilized for increased x-ray absorption, and thus increased sensitivity, or, the same thickness phosphor layer can be used and the further extending wall projections further improve the resolution. It should also be noted that the base portion of the metal replica (i.e., the floor portion of each cell which interconnects the hollow wall projections), being fabricated of a light-reflective metal, provides a means for reflecting light photons which are originally emitted toward the face plate 10a, back toward the photoemitter layer 70. Thus, a separate light-reflective coating between the face-plate 10a and phosphor layer 61 is not required in my invention, although it is generally utilized in conventional x-ray image intensifiers.

As stated hereinabove, the silicone rubber replica 45 is changed from its original planar shape (on the nonindented major surface 45d thereof) into the desired concave shape conforming to the face plate surface. Alternatively, the final electroplated metal replica 50 is relatively flexible due to its thinness and corrugated (hollow wall projections) form and therefore all of the replication including the electroplated metal replica) can be accomplished using planar geometry and the final metal replica can then be sagged into the desired concave shape while bonding such replica to the face plate thereby simplifying the process of fabricating the plastic replica.

From the foregoing description, it is apparent that my invention attains the objectives set forth and makes available a new and improved x-ray image intensifier tube which has an input phosphor screen that simultaneously achieves both high x-ray absorption (and thus high sensitivity) and high image resolution as well as providing a method of manufacturing such input phosphor screen. The method of manufacturing the input phosphor screen is a low cost fabrication process due to the use of a silicone rubber replica which permits fabrication of many inexpensive metal replicas of the original master. The light-reflective surfaces of the hollow projecting walls of the metal replica prevent degradation of image resolution and contrast due to lateral scattering of light in the phosphor layer and thereby avoid phosphor layer thickness compromise in conventional x-ray image intensifier tubes between high x-ray absorption and high imageresolution. It will be apparent to those skilled in the art that the waffle-like surface on the metal replica which constitutes the essence of my invention may take other forms than that specifically illustrated and described above. Also, the support for the input phosphor screen, herein described as the face plate, may be slightly spaced from the input window of the tube glass envelope. Thus, it is to be understood that changes may be made in the particular embodiment of my invention as described which are within the full intended scope of the invention as defined by the appended claims.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. An improved x-ray image intensifier input phosphor screen comprising a concave-shaped face plate of uniform thickness forming a support for the input phosphor screen of an x-ray image intensifier tube, a metallic substrate member having hollow wall-like projections extending normal to the inner surface of said face plate and outward in a direction away therefrom to form a waffle-like surface on a first major side thereof, a second major side of said metallic substrate member having a major portion of its surface parallel to the inner surface of said face plate and connected thereto, the remaining portion of said second side having indentations corresponding to the hollow wall-like projections on said first side, the first side of said metallic substrate member having floor portions interconnecting the wall-like projections to define the waffle-like surface, the floor portions being parallel to the major portion of the second side such that the metallic wubstrate member is a single layer of the metal, phosphor layer deposited in cells formed by the waffle-like surface on the first side of said metallic substrate member and being of sufficient thickness to extend slightly beyond the outer ends of the wall-like projections thereof to form a second surface concave-shaped and substantially parallel to the inner surface of said face plate, and means deposited on the second surface of said phosphor layer for producing emission of photoelectrons therefrom in response to x-ray photons passing through said face plate and being converted to light photons in the phosphor layer, the waffle-like surface of said metallic substrate member having a relatively high light reflectivity for directing the light photons generated in the phosphor layer toward the photoelectron producing means, the wall-like projections substantially reducing degradation of image resolution and contrast due to lat eral scattering of the light in the phosphor layer thereby permitting use of a thicker phosphor layer for higher x-ray absorption and resultant higher sensitivity and, or, for obtaining higher image resolution.

2. The x-ray image intensifier phosphor screen set forth in claim 1 wherein the metallic substrate member layer is of thickness in the range of 0.0002 to 0.0005 inch.

3. The xray image intensifier input phosphor screen set forth in claim 1 wherein said metallic layer is formed of nickel.

4. The x-ray image intensifier input phosphor screen set forth in claim 3 wherein the major portion of the second side of said metallic substrate member is connected to the inner surface of said face plate by means of a thin uniform thickness layer of silicone resin for bonding the adjoining surfaces. 5. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of aluminum. 6. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of glass. 7. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of a low atomic number metal. 8. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises cesium iodide. 9. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises a transparent phosphor material. 10. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises a granular phosphor of large grain size of particle diameter greater than 0.3 mil to thereby obtain high light transmission characteristics. 1 l. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each being square shaped. 12. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member form equal size squares separated by equal size said wall-like projections. 13. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each being hexagon shaped. 14. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein Y the floor portions on the first side of said metallic substrate member form equal size hexagons separated by equal size said wall-llike projections. 15. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections each extend outward approximately lO mils. 16. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections each have an outer width di mension of approximately 0.5 mils. 17. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each have a width dimension of approximately 5 to 6 mils. 18. The x-ray image intensifier input phosphor screen set forth in claim 14 wherein the hexagon shaped floor portions each having a width dimension of approximately 5 to 6 mils. 19. The x-ray image intensifier input phosphor screen set forth in claim [wherein the wall-like projections of said metallic substrate member extend into the phosphor layer at least halfway therethrough. 20. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections of said metallic substrate msm sr ts th qushaiaprqximatsl %.9f h phosphor layer.

Claims

2. The x-ray image intensifier phosphor screen set forth in claim 1 wherein the metallic substrate member layer is of thickness in the range of 0.0002 to 0.0005 inch.
3. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said metallic layer is formed of nickel.
4. The x-ray image intensifier input phosphor screen set forth in claim 3 wherein the major portion of the second side of said metallic substrate member is connected to the inner surface of said face plate by means of a thin uniform thickness layer of silicone resin for bonding the adjoining surfaces.
5. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of aluminum.
6. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of glass.
7. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said face plate is fabricated of a low atomic number metal.
8. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises cesium iodide.
9. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises a transparent phosphor material.
10. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein said phosphor layer comprises a granular phosphor of large grain size of particle diameter greater than 0.3 mil to thereby obtain high light transmission characteristics.
11. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each being square shaped.
12. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member form equal size squares separated by equal size said wall-like projections.
13. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each being hexagon shaped.
14. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member form equal size hexagons separated by equal size said wall-like projections.
15. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections each extend outward approximately 10 mils.
16. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections each have an outer width dimension of approximately 0.5 mils.
17. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the floor portions on the first side of said metallic substrate member each have a width dimension of approximately 5 to 6 mils.
18. The x-ray image intensifier input phosphor screen set forth in claim 14 wherein the hexagon shaped floor portions each having a width dimension of approximately 5 to 6 mils.
19. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections of said metallic substrate member extend into the phosphor layer at least halfway therethrough.
20. The x-ray image intensifier input phosphor screen set forth in claim 1 wherein the wall-like projections of said metallic substrate member extend through approximately 80% of the phosphor layer.