KR20150113817A - Stacking-Type X-ray Grid, its manufacturing device and manufacturing method - Google Patents

Abstract

The present invention provides a layered X-ray grid having a shape-maintaining property, strength, and durability. The layered X-ray grid (14) according to the present invention uses a print sheet (1) on which a print layer (3) of a prescribed pattern comprised of an X-ray absorbing material arriving layer (4) and an air gap layer (5) on an upper surface of a sheet (2) having an X-ray transmitting property as a unit layer, and comprises a plurality of the print sheets (1) which are layered on top each other and wherein the sheet (2) and the print layer (3) are alternately arranged in a layering direction to form a layered body (13). An X-ray absorbing unit (10) is formed by a plurality of the X-ray absorbing material arriving layers (4) vertically layered with the sheets (2) disposed therebetween. An X-ray transmitting unit (12) is formed by a plurality of the air gap layers (5) vertically layered with the sheets (2) disposed therebetween. And, an upper plate (20) having an X-ray transmitting property can be disposed on an uppermost surface, and a lower plate (18) having an X-ray transmitting property can be disposed on a lowermost surface.

Description

[0001] The present invention relates to a stacking type X-ray grid,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an X-ray grid used in an X-ray apparatus such as an X-ray radiograph or an X-ray CT apparatus, and more particularly to an X- And an X-ray grid which absorbs scattered X-rays generated and transmits primary X-rays.

Fig. 12 is a cross-sectional explanatory view of a general X-ray grid, in particular, a focusing grid. The X-ray grid 114 is a plate-like member formed by alternately arranging an X-ray transmitting portion 112 that penetrates X-rays and an X-ray absorbing portion 110 that absorbs and blocks X-rays. The X-ray absorbing part 110 is formed of a metal having an X-ray absorbing property, and is formed of a metal having a high atomic number, such as Pb, W, Ta, Re, Pt, On the other hand, the X-ray transmitting portion 112 may be an air layer or may be formed by filling a substance which is easily permeable to X-rays, for example, Al or resin. Particularly, the X-ray grid in which the X-ray transmitting portion 112 is an air layer is called an air grid.

Particularly, the X-ray grid 114 is formed such that the X-ray transmitting portion extension line 113, which is an extension of the peripheral wall of the X-ray transmitting portion 112, is concentrated on the focal point 115. The focal point 115 corresponds to the generation point of the X-ray and can be regarded as an X-ray generation point of a source installed in the X-ray tube. When a primary X-ray is generated from the focal point 115 and is irradiated to a subject, as shown in the primary X-ray incidence direction b, a primary X-ray passing through the subject passes through the X- And reaches a receiving portion such as an X-ray film existing downward, and forms a clear transmitted image. On the other hand, as shown in the scattering X-ray incidence direction c, the scattered X-rays generated inside the subject collide with the outer circumferential surface of the X-ray absorbing part 110 and are absorbed by the X-ray absorbing part 110, Scattered X-rays are absorbed and blocked. Therefore, the focusing grid is used when the distance from the source to the object is short.

Fig. 13 is a three-dimensional explanatory diagram of a general X-ray grid, in particular, a parallel grid. The X-ray grid 114 is provided by arranging a plurality of metal plates as an X-ray absorbing unit 110 at a predetermined interval in parallel. The X-ray transmitting portion 112 is a void portion provided between the metal plate and the metal plate. Accordingly, the X-ray absorbing part 110 and the X-ray transmitting part 112 are alternately installed to constitute a parallel grid. The metal plate serving as the X-ray absorbing unit 110 is formed of a metal having X-ray absorbency, and is formed of a metal having a high atomic number such as Pb, W, Ta, Re, Pt,

In particular, the X-ray grid 114 is called a parallel grid because the X-ray transmission portion extension line 113, which is an extension of the peripheral wall of the X-ray transmission portion 112, becomes parallel to each other. If the source is farther away from the object, the primary X-rays from the source are irradiated to the subject in approximately parallel, in which case a parallel grid is used. The primary X-ray transmitted through the object passes through the X-ray transmitting portion 112 as the primary X-ray entering direction b and reaches the lower receiving portion. On the other hand, the scattered X-rays scattered inside the object collide with and absorb the surface of the X-ray absorbing part 110 as shown by the scattering X-ray incidence direction c, and do not reach the lower retaining part.

Wilhelm Röntgen is the winner of the first Nobel Prize, and Röntgen (X-ray) technology is a mature technology. Thus, the manufacturing method of X-ray grids such as focusing grids and parallel grids has been historically long and numerous patents exist, but many of them have been manufactured by machining.

As an example of machining, there is a method of manufacturing an X-ray grid as disclosed in Japanese Patent Application Laid-Open No. 2009-257835 (Patent Document 1). Fig. 14 is a manufacturing process diagram of the X-ray grid according to the patent document 1. Fig. 14A, 14A is a perspective view for explaining a configuration of the foil insertion tray 210, and 14B is a perspective view of a state in which a large number of objects are attached.

The fastening means 210 is provided with fixing means 213 and traction means 215 on the left and right on the base 214. The pulling means 215 is constituted by a base shaft 215a, And an elastic body 215b. Between the fixing means 213 and the traction means 215, comb-shaped plates 211, 212 having a plurality of grooves 211a, 212a at their tip ends are arranged laterally. The pulling means 215 is pulled in the pulling hook 216 and pulling the pulling hook 216 in the X direction so that the pulling means 215 is pulled away from the clamping means 213. [

The metal foil 202 is formed of a metal that absorbs X-rays, in this case, a lead foil. Both ends of the metal foil 202 are bonded to the first hook 203 and the second hook 204 do. Next, the first hook 203 is suspended from the fixing means 213, the second hook 204 is suspended from the pulling means 215, and the metal foil 202 is inserted into the left and right grooves 211a and 212a . A plurality of metal foils 202 are inserted and arranged in the left and right grooves 211a and 212a as shown in Fig. Thereafter, the pulling hook 216 is pulled in the X direction to give the metal foil 202 tension, and the metal foil 202 is made to conform to the shape of the recesses 211a and 212a. The upper and lower edges of the metal foil are adhered to the upper and lower sheet covers, respectively, by bringing a sheet cover (not shown) above and below the metal foil 202 close to each other. After bonding, both ends of the metal foil 202 are cut off to complete the production of the X-ray grid.

As described above, in the case of manufacturing the X-ray grid by machining, there is a drawback that it requires a complicated process and requires a large time because the X-ray grid is formed by setting about 400 metal foil . In addition, when defects occur in some of the metal foils during machining, labor such as replacement of the metal foil is generated, and the completed X-ray grid has a weak point that it becomes expensive.

Therefore, in recent years, printing technology has been improved, and it has been researched that printing technology is used for manufacturing X-ray grid instead of machining. For example, a manufacturing method of an X-ray grid as disclosed in Japanese Patent Application Laid-Open No. 2013-66650 (Patent Document 2) has been proposed.

Japanese Patent Laid-Open No. 2009-257835 Japanese Patent Application Laid-Open No. 2013-66650

Fig. 15 is a flowchart of a manufacturing process of an X-ray grid according to a conventional patent document 2. Fig. In Patent Document 2, an X-ray grid is manufactured using an inkjet printer, and a lead toner in which an X-ray absorbing agent such as a lead powder is mixed with a solvent is used for the ink cartridge. A desired pattern image is created using a personal computer in which a general-purpose image processing application is installed, and a desired X-ray grid is produced by instructing the inkjet printer to print out the pattern image.

As the sheet, a metal (for example, Al) or a resin plate having a high X-ray transmittance is used. A pattern image of (C) is drawn by an inkjet printer to form a lower layer on the upper surface of this sheet. Next, a pattern image of (B) is drawn by an inkjet printer to form an intermediate layer. Finally, Is drawn by an inkjet printer to form an upper layer, thereby completing the X-ray grid shown in (D).

However, the X-ray grid manufactured according to the patent document 2 using the printing method has the following drawbacks. The structure made up of the X-ray absorbing part and the X-ray transmitting part constructed on the sheet has a structure in which after the solvent is evaporated and dried, the metal powder such as lead toner is not a solid solidified by the binder agent, Respectively. Therefore, if the sheet is bent, the sheet spontaneously bends, or the entire X-ray grid collides against the wall surface, there is a risk that the structure on the sheet collapses. Further, when a hand or an object touches the structure itself, there is a risk that the structure collapses due to the vibration. Even if there is no such collision or bending, there is a risk that the structure itself becomes weakened due to absorption of moisture or the like and the original shape can not be maintained.

Accordingly, it is an object of the present invention to provide a laminated X-ray grid by stacking a plurality of printed sheets on which a print layer is printed on a sheet, and alternately laminating the sheet and the print layer to increase the strength of the whole structure, A multilayer X-ray grid having a high durability by eliminating the brittleness of the structure itself because the X-ray absorbing portion and the X-ray transmitting portion are constituted by alternately overlapping the plurality of print layers via the sheet .

A first aspect of the present invention is to provide a printing sheet in which a printing layer having a predetermined pattern of an X-ray absorbent arrival layer and an air gap layer formed on the upper surface of an X- Ray absorber layer formed by stacking a plurality of the above-mentioned print sheets in such a manner that the sheet and the print layer are alternately arranged in the stacking direction, and a plurality of X- Ray absorbing portion is formed by the X-ray absorbing portion and the X-ray transmitting portion is formed by a plurality of void layers laminated vertically opposite each other with the sheet interposed therebetween.

In a second aspect of the present invention, there is provided a laminated X-ray cell having an X-ray transmissive upper plate disposed on an uppermost surface of the printed sheet laminate, and a lower plate having X- to be.

A third aspect of the present invention is a laminated X-ray grid used as a focusing grid, wherein an extension line of the X-ray transmitting portion in the lamination direction of the X-ray transmitting portion existing in the printing sheet laminate is concentrated in one focal point.

A fourth aspect of the present invention is a laminated X-ray grid in which extension lines in the lamination direction of the peripheral walls of the X-ray transmission portion existing in the printing sheet laminate are parallel to each other and used as a parallel grid.

The fifth aspect of the present invention is a laminated X-ray grid, wherein the X-ray absorbent arrival layer is a printing ink having a metal powder formed of a metal absorbing X-rays as a main component or an arrival layer (applied layer) of a printing toner.

According to a sixth aspect of the present invention, there is provided a sheet processing apparatus comprising: a sheet supply device for supplying a sheet having X-ray transmittance; and a print sheet having a predetermined pattern composed of an X-ray absorbent arrival layer and an air gap layer printed on the sheet, A printer, and a stacking device for stacking the prepared print sheets one after another in order to complete a printed sheet stacked body, and a stacked body discharging device for discharging the printed sheet stacked body from the sheet stacking device as a stacked X-ray grid Ray diffraction grating.

In a seventh aspect of the present invention, there is provided a method for producing a laminated sheet, comprising the steps of first feeding a lower plate having X-ray transmittance to the sheet laminator, laminating the print sheet laminate on the lower plate, And a plate supplying device for supplying the X-ray powder to the uppermost surface of the printing sheet laminate to complete a laminated X-ray grid, wherein the laminated X-ray grid is discharged from the laminated X- Manufacturing device.

An eighth mode of the present invention is a device for manufacturing a stacked X-ray grid, comprising: a memory for storing a manufacturing method program; a computer for transmitting a signal according to the program; to be.

In a ninth aspect of the present invention, there is provided a method of manufacturing a printing sheet, comprising: forming a printed layer of a predetermined pattern made of an X-ray absorbent arrival layer and an air gap layer on an upper surface of an X- Ray absorber is formed by a plurality of X-ray absorber arrival layers stacked vertically on each other with a sheet interposed therebetween so that the sheet and the print layer are alternately arranged in the stacking direction, And the X-ray transmitting portion is formed by a plurality of void layers laminated on top of each other with a space therebetween.

In a tenth form of the present invention, a lower plate having X-ray transmittance is arranged, the print sheet laminate is formed on the upper surface of the lower plate, and an upper plate having X-ray transmittance is formed on the uppermost surface of the print sheet laminate And the like.

The eleventh aspect of the present invention is characterized in that the print layer is formed such that extension lines extending in the lamination direction of the peripheral walls of the X-ray transmission portion existing in the printing sheet laminate are concentrated on one focal point, As shown in Fig.

In a twelfth mode of the present invention, the printing layer is formed such that extension lines of the X-ray transmission portion in the lamination direction of the X-ray transmission portions existing in the printing sheet laminate are parallel to each other, and the laminated X- Ray diffraction method.

The thirteenth aspect of the present invention is a method for producing a laminated X-ray grid, which is an arrival layer of a printing ink or a printing toner in which the X-ray absorbent arrival layer is a metal powder formed by a metal having X-

According to a fourteenth aspect of the present invention, there is provided a method of manufacturing a multilayer X-ray grid in which a memory for storing a manufacturing method program is disposed and a computer for transmitting a signal according to the program is installed, to be.

According to the first aspect of the present invention, there is provided a printing sheet in which a printing sheet having a predetermined pattern of a pattern of an X-ray absorbent arrival layer and an air gap layer formed on the upper surface of a sheet having X- The thickness of the printed sheet laminate corresponds to the thickness of the laminated X-ray grid because it is constituted by the printed sheet laminate in which the sheet and the printed layer are alternately arranged in the lamination direction. That is, since the thickness of one sheet of printing sheet is thin and the thickness of the printing layer is thinner, there is no risk that the printing layer is firmly bonded to the sheet even if the printing layer is dried and solidified, and the printing layer is peeled or collapsed . Further, since one sheet exists for one printing layer, and furthermore, a plurality of sheets are stacked, the laminated X-ray grid is maintained in strength and shape by a plurality of stacked sheet groups, and a large number Since the sheet of each sheet is flexible, the laminated X-ray grid has strength, shape stability and durability.

The X-ray absorbing portion is formed by a plurality of X-ray absorbent arrival layers stacked vertically with the sheet therebetween, and the X-ray transmitting portion is formed by a plurality of air gap layers stacked vertically with the sheet interposed therebetween The X-ray absorber has a large area in which the number of layers of the X-ray absorber arriving layer is deposited, and the X-ray incident on the X-ray absorber is completely absorbed. Also, when the scattered X-rays incident on the X-ray transmitting portion collide with the peripheral wall of the X-ray absorbing portion, they are all absorbed, so that the primary X-ray incident parallel to the main wall surface of the X-ray transmitting portion is transmitted downward.

Since the sheet is formed of a thin film such as a resin sheet having X-ray transmittance, a paper sheet, or an Al sheet, a plurality of stacked sheet groups efficiently transmit X-rays, and the X-ray absorbing portion and the X- .

The X-ray absorbent arrival layer is a deposited layer of printing ink or printing toner that has arrived (coated) on a sheet by printing. The printing ink or the printing toner contains a metal powder composed of a metal that absorbs X-rays as a main component. Specifically, metal powders such as Pb, W, Ta, Re, Pt, Au, . As other additives, a binder, a solvent, an adhesive, and the like may be appropriately added to provide a wet ink or a dry toner. When an inkjet printer is used as a printer, a wet ink is used. When an electronic copying machine is used, a dry toner called a toner is used. Needless to say, existing printers and ink suitable for the present printers can be used.

According to the second aspect of the present invention, there is provided a laminated type X-ray diffraction apparatus in which an upper plate having X-ray transmittance is disposed on the uppermost surface of the printing sheet laminate, and a lower plate having X- A grid can be provided. As described above, the printing sheet laminate has shape retention, stability, and durability because a plurality of sheets are laminated. However, when the upper plate and the lower plate having X-ray transmissivity are arranged on the upper and lower surfaces of the printed sheet laminate, The flatness and strength of the laminated X-ray grid can provide better shape retention, stability and durability. The upper plate and the lower plate may be formed of a resin plate, a sheet of paper, an Al plate or the like having X-ray transmittance, or may be a plate covering the entire upper and lower surfaces of the laminate of the printing sheet, or a rectangular frame having a central opening. The rectangular frame protects the periphery of the printed-sheet laminate, and since the X-ray is completely transmitted through the opening, the X-ray is not attenuated by the plate.

According to a third aspect of the present invention, there is provided a stacked X-ray grid used as a focusing grid, wherein an extension line in the stacking direction of the peripheral wall of the X-ray transmitting portion existing in the printing sheet laminate is focused on one focal point .

As described above, in the focusing grid, the focal point corresponds to the generation point of the X-ray, and it can be said to be the X-ray generation point of the source installed in the X-ray tube. When a primary X-ray is generated from the focal point and is irradiated to a subject, a primary X-ray transmitted through the subject is transmitted through the X-ray transmitting portion to the X- And the like, and forms a transmission image of the test object. On the other hand, the scattered X-rays generated inside the object collide with the outer peripheral surface of the X-ray absorbing part, that is, the main wall surface of the X-ray transmitting part and absorbed into the X-ray absorbing part. Therefore, the focusing grid is used to obtain a clear X-ray transmission image when the distance from the source to the object is short.

As described above, according to the fourth aspect of the present invention, a laminated X-ray grid in which extension lines in the lamination direction of the peripheral walls of the X-ray transmission portion existing in the printing sheet laminate are parallel to each other and used as a parallel grid / RTI >

As described above, the parallel grid is used when the source is far from the subject. In this case, the primary X-rays from the source are irradiated to the subject substantially parallel, and the primary X-rays transmitted through the subject reach the lower receptacle through the X-ray transmitting portion. On the other hand, the scattered X-rays scattered inside the object collide with and absorb the surface of the X-ray absorbing part, and do not reach the lower receiving part. Therefore, a clear image can be given to the receptacle portion, and a clear image signal can be generated.

In addition, when the top parallel grid rotated by 90 degrees on the parallel grid at the bottom is overlapped, it is possible to form a rectangular tube-shaped X-ray transmission portion, and the absorption efficiency of the scattered X-rays increases, An image signal can be generated.

According to the fifth aspect of the present invention, it is possible to provide a laminated X-ray grid which is an arrival layer of a printing ink or a printing toner in which the X-ray absorbent arrival layer contains metal powder formed of a metal absorbing X-rays as a main component.

The X-ray absorbent arrival layer is a deposited layer of a printing ink or a printing toner which has arrived on a sheet by printing. As described above, the printing ink or the printing toner contains, as a main component, a metal powder composed of a metal that absorbs X-rays, and specifically, a metal such as Pb, W, Ta, Re, Pt, Au, Powder may be used. As another additive, a binder, a solvent, an adhesive, and the like may be suitably used to provide a wet ink or a dry ink (or toner). When an inkjet printer is used as a printer, a wet ink is used. When an electronic copying machine is used, a dry toner called a toner is used. Needless to say, a printing ink or a printing toner suitable for an existing printer can be used.

According to a sixth aspect of the present invention, there is provided a sheet supply apparatus comprising: a sheet supply device for supplying a sheet having X-ray transmittance; and a print layer of a predetermined pattern made of an X-ray absorbent arrival layer and an air gap layer on the sheet supplied by the sheet supply device A sheet stacking device for stacking the prepared printing sheets in order while aligning the sheets so as to form a printing sheet laminate; and a sheet stacking device for discharging the printing sheet stack as a stacked X-ray grid from the sheet stacking device It is possible to provide an apparatus for manufacturing a laminated X-ray grid having a stacked body discharging device. With this manufacturing apparatus, it becomes possible to consistently mass-produce the multilayer X-ray grid according to the present invention at a low cost.

The sheet supply device, the printer, the sheet stacking device, and the stack discharging device may be driven separately, or all of them may be driven in conjunction with each other, or automatically linked by a computer signal.

The sheet feeding device, the printer, the sheet stacking device, and the stacking device discharging device may be assembled as an integrated device. Alternatively, the four devices may be separated into individual devices, or two devices suitably selected from these, 3 device may be integrated.

As a result, it is possible to provide an apparatus for producing a laminated X-ray grid capable of mass production of the above-mentioned printed sheet laminate as a stacked X-ray grid at low cost.

According to a seventh aspect of the present invention, there is provided a method for producing a laminated sheet, comprising the steps of first feeding a lower plate having X-ray transmittance to the sheet laminator, laminating the print sheet laminate on the lower plate, By providing a plate supplying device for supplying a plate to the uppermost surface of the printing sheet laminate to complete the laminated X-ray grid, a robust laminated X-ray grid stuck to the plate can be manufactured. That is, by adding the plate supply device of this embodiment to the production device of the sixth aspect, it is possible to inexpensively mass-produce a multilayer X-ray grid in which the printing sheet laminate is stuck with the lower plate and the upper plate.

Therefore, the plate supplying apparatus of this embodiment may be added to the sheet supplying apparatus, the printer, the sheet stacking apparatus, and the stack discharging apparatus so that the apparatuses may be driven separately or all of them may be driven in cooperation with each other. It may be automatically interlocked. Further, two to four devices selected from a plate supply device, a sheet supply device, a printer, a sheet stacking device, and a stacked product discharge device may be integrally assembled, or all five devices may be integrally formed. So that the device can be driven freely according to the situation.

According to an eighth aspect of the present invention, there is provided a manufacturing apparatus for a multilayer X-ray grid, which comprises a memory for storing a manufacturing method program, a computer for transmitting signals according to a manufacturing method program, Can be provided. There are ROM and RAM in the memory, and the preparation program is saved in ROM. Temporarily necessary data is saved in RAM, ROM is output-only, and RAM can be input and output.

ROM, signals are output from the computer to each of the plate feeding device, the sheet feeding device, the printer, the sheet laminating device, and the laminate ejecting device, and the laminated X- Are driven to produce an X-ray grid, and the production is terminated. Therefore, the stacked X-ray grid can be mass-produced consistently and inexpensively.

According to a ninth aspect of the present invention, a printing sheet is formed by forming a print layer of a predetermined pattern composed of an X-ray absorbent arrival layer and an air gap layer on the upper surface of a sheet having X-ray transmittance, The thickness of the printed sheet laminate can be made to be the thickness of the laminated X-ray grid, since the printed sheet laminate is formed by laminating the sheets and the printed layers alternately in the lamination direction while determining. That is, the thickness of one sheet of printing sheet is thinner and the thickness of the printing layer is thinner. Therefore, even if the printing layer dries and solidifies, the risk that the printing layer is firmly bonded to the sheet and the printing layer peels off or collapses Not at all. Further, since there is one sheet for one printing layer and a plurality of sheets are laminated, the laminated X-ray grid is maintained in strength and shape by a plurality of laminated sheet groups, and a large number of sheets The sheet is flexible and integrally supported, so that strength, shape stability, and durability are imparted to the laminated X-ray grid.

The X-ray absorbing portion is formed by a plurality of X-ray absorbent arrival layers stacked vertically with the sheet therebetween, and the X-ray transmitting portion is formed by a plurality of air gap layers stacked vertically with the sheet interposed therebetween The X-ray absorber has a large area in which the number of layers of the X-ray absorber arriving layer is deposited, and the X-ray incident on the X-ray absorber is completely absorbed. When the scattered X-rays incident on the X-ray transmitting portion collide with the peripheral wall of the X-ray absorbing portion, they are all absorbed. Therefore, the primary X-ray incident parallel to the main wall surface of the X-ray transmitting portion is transmitted downward.

According to the above-described manufacturing method of the layered X-ray grid, it becomes possible to mass-produce a layered X-ray grid having shape retentivity, strength and durability at low cost. In addition, since the printing sheet on which the printing layer with the predetermined pattern composed of the X-ray absorbent arrival layer and the gap layer is formed is merely laminated in multiple stages, the advantage of being able to freely form arbitrary shapes of the X- .

Since the sheet is formed of a thin film such as a resin sheet having X-ray transmittance, a paper sheet, or an Al sheet, a plurality of stacked sheet groups efficiently transmit X-rays so that the X-ray absorbing portion and the X- .

The X-ray absorbent arrival layer is a deposited layer of a printing ink or a printing toner which has arrived on a sheet by printing. The printing ink or the printing toner contains a metal powder composed of a metal that absorbs X-rays as a main component. Specifically, metal powders such as Pb, W, Ta, Re, Pt, Au, . As other additives, a binder, a solvent, an adhesive, and the like may be appropriately added to provide a wet ink or a dry toner. When an inkjet printer is used as a printer, a wet ink is used. When an electronic copying machine is used, a dry toner called a toner is used. Needless to say, existing printers and ink suitable for the present printers can be used.

According to a tenth aspect of the present invention, there is provided a liquid crystal display device, comprising: a lower plate having X-ray transmittance disposed therein; a print sheet laminate formed on an upper surface of the lower plate; Ray diffraction pattern of the X-ray diffraction pattern.

The printed sheet laminate has shape retention, stability, and durability because a large number of sheets are laminated. However, according to the manufacturing method of the tenth aspect, since the upper plate and the lower plate having X-ray transmittance are arranged on the upper and lower surfaces of the printed sheet laminate, the laminate type X- It is possible to impart stability and durability. The upper plate and the lower plate may be formed of a resin plate, a sheet of paper, an Al plate or the like having X-ray transmittance, and may be a plate covering the entire upper surface and the lower surface of the laminate of the printing sheet, or a rectangular frame having an opening at the center. The rectangular frame protects the periphery of the printed sheet laminate, and since the X-ray is completely transmitted through the opening, the X-ray is not attenuated by the plate.

According to an eleventh aspect of the present invention, there is provided a printing sheet production method comprising the steps of: forming the print layer such that an extension line of the X-ray transmission portion in the lamination direction of the X- A method of manufacturing a laminated X-ray grid formed as a grid can be provided.

According to the manufacturing method of the eleventh aspect, a multilayer X-ray grid which is a focusing grid can be manufactured. In the focusing grid, the focus corresponds to the origin of the x-ray and is the x-ray origin of the source located in the x-ray conduit. When a primary X-ray is generated from the focal point and is irradiated to a subject, the primary X-rays transmitted through the subject are transmitted through the X-ray transmitting portion to reach the lower portion of the X- , And a transparent image of a clear subject can be formed. On the other hand, the scattered X-rays generated inside the object collide with the outer peripheral surface of the X-ray absorbing part, that is, the main wall surface of the X-ray transmitting part and are absorbed by the X-ray absorbing part and the scattered X- , The transmission image of the object can be made clearer. Therefore, the focusing grid is used to obtain a clear X-ray transmission image when the distance from the source to the object is short.

According to a twelfth aspect of the present invention, there is provided a printing sheet production method comprising the steps of: forming the print layer such that extension lines of the X-ray transmission portion in the stacking direction of the X- Ray diffraction pattern of the X-ray diffraction pattern.

According to the manufacturing method of the twelfth aspect, a multilayer X-ray grid which is a parallel grid can be manufactured. The parallel grid is used when the source is far from the object. In this case, the primary X-rays from the source are irradiated to the subject substantially parallel, and the primary X-rays transmitted through the subject reach the lower receptacle through the X-ray transmitting portion. On the other hand, the scattered X-rays scattered inside the object collide with and absorb the surface of the X-ray absorbing part, and do not reach the lower receiving part. Therefore, it is possible to provide a method of producing a parallel grid in which a clear image is given to the receptacle and a clear image signal can be generated.

In addition, since the top parallel grid rotated 90 degrees on the lower parallel grid can be superimposed to form a rectangular tube-shaped X-ray transmitting portion and the absorption efficiency of scattered X-rays can be increased, An image or an image signal can be generated.

According to the thirteenth aspect of the present invention, it is possible to provide a production method of a layered X-ray grid, which is an arrival layer of a printing ink or a printing toner in which the X-ray absorbent arrival layer is composed of a metal powder formed of a metal having X- .

The X-ray absorbent arrival layer is a deposited layer of a printing ink or a printing toner which has arrived on a sheet by printing. As described above, the printing ink or the printing toner contains, as a main component, a metal powder composed of a metal that absorbs X-rays, and specifically, a metal such as Pb, W, Ta, Re, Pt, Au, Powder may be used. As another additive, a binder, a solvent, an adhesive, and the like may be suitably used to provide a wet ink or a dry ink (or toner). When an inkjet printer is used as a printer, a wet ink is used. When an electronic copying machine is used, a dry toner called a toner is used. Needless to say, a printing ink or a printing toner suitable for an existing printer can be used.

According to a fourteenth aspect of the present invention, there is provided a computer readable recording medium storing a computer program for causing a computer to transmit a signal in accordance with the program by arranging a memory for storing a manufacturing method program, You can provide a recipe.

There are ROM and RAM in the memory, and the preparation program is saved in ROM. The temporarily required data is saved in the RAM, the ROM is output-only, and the RAM is capable of input and output.

According to the manufacturing method of the fourteenth aspect, as the manufacturing method program output from the ROM proceeds, each step of the manufacturing process is automatically advanced by a signal from the computer, and the multilayer X-ray grid can be efficiently mass-produced.

As described above, in order to execute each step of the manufacturing process, the production apparatus is constituted by a plate supply apparatus, a sheet supply apparatus, a printer, a sheet stacking apparatus, a stack discharge apparatus and / or a plate supply apparatus, A signal is output to each of them, and each device of the layered X-ray grid manufacturing apparatus that has received the signal is driven to produce an X-ray grid, and the manufacturing is completed. Therefore, the stacked X-ray grid can be mass-produced consistently and inexpensively.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic explanatory view of a manufacturing process of a printing sheet to be a unit layer used in a laminated X-ray grid according to the present invention. FIG.
[Fig. 2] Fig. 2 is a schematic sectional view of a focusing grid, which is a first embodiment of a laminated X-ray grid according to the present invention.
[Fig. 3] Fig. 3 is a schematic sectional view of a parallel grid which is a second embodiment of a laminated X-ray grid according to the present invention.
[Fig. 4] Fig. 4 is a partially enlarged perspective view of a hexagonal transmission structure of a laminated X-ray grid according to the present invention.
5 is a partially enlarged view of various transmission structures of the layered X-ray grid according to the present invention.
6 is a perspective view of a laminated X-ray grid in which upper and lower surfaces are stuck with a plate in the present invention.
[Fig. 7] Fig. 7 is a schematic explanatory diagram of a case where X-ray radiography of a human body is performed using the laminated X-ray grid according to the present invention.
[Fig. 8] Fig. 8 is a block diagram of an apparatus for manufacturing a laminated X-ray grid without a plate in the present invention.
9 is a flowchart of a manufacturing process of a laminated X-ray grid without a plate in the present invention.
10 is a block diagram of an apparatus for manufacturing a laminated X-ray grid having plates on the upper and lower surfaces in the present invention.
[Fig. 11] Fig. 11 is a flowchart of a manufacturing process of a laminated X-ray grid having a plate in the present invention.
12 is a sectional view of a focusing grid in a conventional X-ray grid.
[Fig. 13] Fig. 13 is a perspective view of a parallel grid in a conventional X-ray grid.
[Fig. 14] Fig. 14 is a perspective view of a manufacturing process of an X-ray grid in the conventional patent document 1 (Japanese Patent Laid-open No. 2009-257835).
[Fig. 15] Fig. 15 is an explanatory diagram of a manufacturing process of an X-ray grid in the conventional patent document 2 (Japanese Patent Laid-open Publication No. 2013-66650).

BEST MODE FOR CARRYING OUT THE INVENTION As shown in the following, a multilayer X-ray grid according to the present invention, an apparatus for producing the same, and embodiments of the manufacturing method will be described in detail with reference to the drawings.

Fig. 1 is a schematic explanatory view of a manufacturing process of a printing sheet serving as a unit layer used in the layered X-ray grid according to the present invention.

The printed sheet 1 is formed by printing a printed layer 3 on the upper surface of the sheet 2. [ The printing layer 3 is formed by arranging an X-ray absorbent arrival (applied) layer 4 and a void layer 5 in a predetermined pattern. The both ends of the gap layer 5 are called void layer ends 5a and 5a and the void layer ends 5a and 5a become the same as the arrival layer ends 4a and 4a of the X-ray absorber arrival layer, 5a and 5a.

The printing means can be appropriately selected in an existing printer if the printer is capable of printing in fineness. Here, an inkjet printer 9 is shown. A drop 8 of printing ink is ejected from a nozzle 7 in the direction of arrow a, and a printing layer 3 is printed on the upper surface of the sheet 2 .

The printing ink which is a wet ink is composed of at least a metal powder as an X-ray absorbing agent, an adhesive agent as a binder and a solvent. After the drop 8 is adhered to the upper surface of the sheet 2, When dried, the X-ray absorbent arrival layer 4 is formed. The printing toner, which is a dry toner, is composed of at least a metal powder and an organic binder, and is printed on the upper surface of the sheet 2 and fixed by heat treatment to form an X-ray absorbent arrival layer 4.

The metal constituting the metal powder may be a metal having a high atomic number such as Pb, W, Ta, Re, Pt, Au or Cu having X-ray absorptivity. For example, Pb (lead) or Au (gold) is preferable. The sheet 2 can be appropriately selected from a sheet having an X-ray transmission property such as a resin sheet, a paper sheet, and an aluminum sheet.

2 is a schematic cross-sectional view of a focusing grid, which is a first embodiment of a layered X-ray grid according to the present invention. The laminated X-ray grid 14 is formed as a converging grid and is configured as a printed sheet laminate 13 in which a plurality of printed sheets 1 are laminated. The print layer 3 is laminated on the upper and lower sides in multiple stages via the sheet 2. Therefore, the X-ray absorbent arrival layers 4, 4 ... are stacked in multiple stages while the sheet 2 is sandwiched therebetween to form the X-ray absorbing portion 10. At the same time, the space layers 5, 5 ... are laminated in multiple stages with the sheet 2 sandwiched therebetween, so that the X-ray transmitting portion 12 is formed. The direction of the air gap layer connecting line 12a connecting the gap layer ends 5a ... 5a of the gap layers 5 ... determines whether or not the stacked X-ray grid 14 is a focusing grid parallel grid. In the first embodiment, since the extension line of the air gap layer connecting line 12a, that is, the extension lines 15, 15 ... of the X-ray transmission portion is concentrated on the focal point 16, Can be determined as a focusing grid. Since the extension line 15 of the X-ray transmission portion is the same as the extension line 11 of the X-ray absorption portion, the extension line 15 is unified with the extension line 15 of the X-ray transmission portion.

It is necessary to align the void layer ends 5a, 5a ... of the printed sheets 1, 1 ... in accordance with the design chart in order to align the void layer folding line 12a in a designed manner, It is necessary to laminate the sheets 1, 1 ... while accurately positioning them, and this positioning accuracy is an important factor for determining the accuracy of the X-ray grid.

Since the primary X-rays are emitted from the focal point 16, the primary X-rays pass through the X-ray transmitting portion 12 like the primary X-ray incidence direction b. On the other hand, the scattered X-rays collide with the peripheral wall of the X-ray transmitting portion 12 as in the scattering X-ray incidence direction c and are absorbed by the X-ray absorbing portion 10. Therefore, only the primary X-ray is incident on the bottom portion arranged below, and a clear transmission image can be formed.

3 is a schematic cross-sectional view of a parallel grid which is a second embodiment of a laminated X-ray grid according to the present invention. The laminated X-ray grid 14 is formed as a parallel grid, and is constituted as a printed sheet laminate 13 in which a plurality of printed sheets 1 are laminated. The print layer 3 is laminated on the upper and lower sides in multiple stages via the sheet 2. Thus, the X-ray absorbent arrival layers 4, 4 ... are stacked in multiple stages while the sheet 2 is sandwiched therebetween to form the X-ray absorbing portion 10. At the same time, the space layers 5, 5 ... are laminated in multiple stages with the sheet 2 sandwiched therebetween, so that the X-ray transmitting portion 12 is formed. The direction of the air gap layer connecting line 12a connecting the gap layer ends 5a ... 5a of the gap layers 5 ... determines whether or not the stacked X-ray grid 14 is a focusing grid parallel grid. In the second embodiment, since the extending lines of the air gap layer connecting lines 12a, that is, the extending lines 15, 15 ... of the X-ray transmitting portions are parallel to each other, the laminated X- . ≪ / RTI >

It is necessary to align the void layer ends 5a, 5a ... of the printed sheets 1, 1 ... in accordance with the design chart in order to align the void layer folding line 12a in a designed manner, It is necessary to laminate the sheets 1, 1 ... while accurately positioning them, and this positioning accuracy is an important factor for determining the accuracy of the X-ray grid.

In the case where the X-ray grid is disposed far from the source, the primary X-rays are incident parallel to the X-ray grid, and the primary X-rays are incident on the X-ray transmitting portion 12) through the inside. On the other hand, the scattered X-rays collide with the peripheral wall of the X-ray transmitting portion 12 as in the scattering X-ray incidence direction c and are absorbed by the X-ray absorbing portion 10. Therefore, only the primary X-ray is incident on the bottom portion arranged below, and a clear transmission image can be formed.

4 is a partially enlarged perspective view of a hexagonal transmission structure of a stacked X-ray grid according to the present invention. The layered X-ray grid 14 according to the present invention is composed of a printed sheet laminate 13. When a portion 17a of the surface of the layered X-ray grid 14 is enlarged, it becomes a partially enlarged portion 17. As can be seen from the enlarged portion 17, the layered X-ray grid 14 has a honeycomb structure, that is, a hexagonal transmission structure. The X-ray absorbing part 10 is a hexagonal wall body, and a hexagonal through-hole constitutes an X-ray transmitting part 12. The X- Sectional view of the partially enlarged portion 17 corresponds to the sectional view of Fig. 2, and this layered X-ray grid 14 is a focusing grid of a honeycomb structure.

Fig. 5 is a partially enlarged view of various transmission structures of the layered X-ray grid according to the present invention. In Fig. 5, the structure of the various magnifying portions 17 is shown. The X-ray transmitting portion 12 is circular, but the X-ray absorbing portion 10 can be seen as a hexagon. (5B), the X-ray transmitting portion 12 is rectangular, but the X-ray absorbing portion 10 is also rectangular. The X-ray transmitting portion 12 is a parallel slit, and the X-ray absorbing portion 10 is a parallel wall. Therefore, this layered X-ray grid is the parallel grid described in FIG. For the structures of (5A), (5B), and (5C), it is needless to say that the stacked X-ray grid according to the present invention can be configured as a focusing grid or a parallel grid. That is, when the extension line of the peripheral wall of the X-ray transmitting portion 12 is converged to the focus, the condensing grid becomes a focusing grid, and if the extension line of the peripheral wall of the X- Sectional views taken along the line X-X of (5A), (5B) and (5C) correspond to the sectional views of Fig. 2 or Fig.

6 is a perspective view of a laminated X-ray grid in which the upper and lower surfaces are stuck with a plate in the present invention. (6A) is a lamination flow chart for laminating the printing sheet (1) on the lower plate (18). The printed sheet 1 is a printed sheet in which the printed layer 3 is formed on the sheet 2. In the printed sheet 1, positioning sheet holes 1a and 1a are formed at the left and right lower corner portions. In this embodiment, the positioning sheet holes 1a and 1a are penetrated through one sheet of the printed sheet 1. Positioning pawls 19, 19 are also protruded from the lower plate 18 at left and right lower corners. By positioning the positioning sheet holes 1a and 1a in the positioning pawls 19 and 19, the positioning of the printed sheet 1 is automatically performed.

As a positioning method other than the hole and the pole, for example, the left and right lower corners of the positioning sheet 1 are matched with the left and right lower corners of the lower plate 18 The lower plate 18 and the printing sheet 1 are prepared in the same shape so that the lower plate 18 and the printing sheet 1 are accurately placed in the seat receiver The positioning may be performed automatically. This positioning ensures that the X-ray absorbent arrival layer 4 and the gap layer 5 are laminated accurately when a plurality of the printing sheets 1 are laminated, It is ensured that the X-ray transmitting portion 12 is accurately formed.

(6B) is a state in which the printing sheet laminate 13 composed of a plurality of sheets is laminated on the lower plate 18 while being positioned. It is shown that the positioning holes 1a and 1a are automatically positioned only by inserting them into the positioning pawls 19 and 19. Further, the upper plate 20 is laminated on the printing sheet laminate 13. Needless to say, the positioning holes 21, 21 of the upper plate 20 are inserted into the positioning pawls 19, 19 at this time.

(6C) is the completeness of the layered X-ray grid 14. [ The laminated X-ray grid 14 is completed by integrally fixing the positioned lower plate 18, the printing sheet laminate 13, and the upper plate 20 together. The upper and lower portions of the printed sheet laminate 13 are rigid and stuck by the lower plate 18 and the upper plate 20 having X-ray transmittance, so that a laminated X- (14) is completed.

Fig. 7 is a schematic explanatory view of the case where X-ray radiography of a human body is performed using the laminated X-ray grid according to the present invention. This layered X-ray grid 14 represents a focusing grid. The primary X-ray 24 is irradiated to the human body 25 in the X-ray source 23 corresponding to the focus. Most of the primary scattered X-rays reach the X-ray detector 27 through the X-ray transmitting portion 12 in the primary X-ray arrow direction b. On the other hand, a part of the primary X-ray 24 is scattered by the compton effect or the like in the human body 25 and changes its direction. The scattered X-ray 26 changes in the scattered X- And collides with the wall surface of the X-ray absorbing part 10. The scattered X-rays 26 are absorbed by the X-ray absorbing portion 10 and do not reach the X-ray detector 27 due to the collision. As a result, since scattered X-rays can be removed, a clear image can be formed in the X-ray detector 27. It goes without saying that the X-ray detector 27 may be an X-ray film.

Fig. 8 is a block diagram of an apparatus for manufacturing a plate-less multilayer X-ray grid according to the present invention. The multilayer X-ray grid manufacturing apparatus E is an apparatus for continuously and automatically producing the multilayer X-ray grid 14. [ For the sake of automation, it is arranged around the computer C, the preparation program is stored in the ROM of the memory M, and the temporarily input / output data is stored in the RAM of the memory M. [ According to the manufacturing method program, a necessary signal is outputted from the computer C as a command signal as follows to produce the layered X-ray grid 14. [ The external input to the computer C is made in the input device I and the external output from the computer C is made in the output device O. [

One sheet S is fed from a sheet feeding device SS which accumulates a plurality of sheets in accordance with a signal from the computer C and fed to the sheet S by the printer P in accordance with a signal from the computer The printing of the printing layer 3 is performed. The printed sheet 1 having been printed is laminated on the sheet stacking apparatus L while positioning is performed in accordance with a signal from a computer, and the necessary number of sheets are printed in accordance with a signal from the computer and lamination is repeated. When all of the printing is finished and the stacking of the sheets is completed in accordance with the signal from the computer, the discharging device R discharges the printing sheet stack 13 from the sheet stacking device L. In this embodiment, the printing sheet laminate 13 is a laminated X-ray grid 14. [

9 is a flowchart of a manufacturing process of a laminated X-ray grid without a plate in the present invention. This manufacturing process flow chart is a flow chart of a manufacturing method program of the layered X-ray grid manufacturing apparatus (E) of Fig.

In step S1, it is determined whether or not the stacked X-ray grid production machine E has been started. If it is started (Y), it is determined in step S2 whether or not the printing software as the production program has been started. When the printing software is started (Y), it is determined in step S3 whether or not the sheet supplying apparatus SS has supplied the sheet S, and if the sheet is supplied (Y) It is determined whether the sheet P has been printed on the printer P or not. Next, in the case where the sheet is printed (Y), it is judged in step S5 whether or not the sheet stacking apparatus L has positioned and stacked the printed sheet 1, and in the case of positioning and stacking (Y) , It is determined whether or not the number of stacked sheets has been completed in accordance with step S6. If not completed (N), the process returns to step S3, and steps S3 to S6 are repeated for the number of stacked sheets. When the number of stacked sheets has been completed (Y), it is determined in step S7 whether or not the printing sheet laminate 13 is fixed. If it is fixed (Y) It is determined whether or not the printed sheet laminate 13 has been discharged. When discharged (Y), the production of the layered X-ray grid 14 is completed.

Fig. 10 is a block diagram of an apparatus for manufacturing a laminated X-ray grid having plates on the upper and lower surfaces in the present invention. The multilayer X-ray grid manufacturing apparatus E according to this embodiment is merely provided with the plate supplying apparatus PS in the manufacturing apparatus E shown in Fig. 8. As a result, the completed multilayer X- 8 in that the printed sheet laminate 13 is stuck by the upper plate 20 and the lower plate 18 in the structure shown in Fig. Therefore, only the differences from FIG. 8 will be described below.

The computer C outputs a signal to the plate supply device PS to supply the lower plate 18 to the plate lamination device L and then to the respective devices shown in Fig. 8 on the lower plate 18 The computer C outputs a signal to the plate feeding device PS and feeds a signal to the plate stacking device L from the upper side The plate 20 is supplied to complete and discharge the laminated X-ray grid 14 of the plate stuck structure of this embodiment. The operation and effect of each of the other devices are the same as those described in Fig. 8, and a description thereof is omitted here.

11 is a flowchart of a manufacturing process of a laminated X-ray grid having a plate in the present invention. This manufacturing process flow chart is a flow chart of the manufacturing method program of the layered X-ray grid manufacturing apparatus (E) of Fig.

In step S11, it is determined whether or not the stacked X-ray grid production machine E has been started. If it is started (Y), it is determined in step S12 whether or not the printing software as the production program has been started. When the printing software is started (Y), in step S13, it is determined whether or not the lower plate 18 is stacked on the plate stacking apparatus L by the plate feeding apparatus PS. When the lower side plate 18 is stacked (Y), it is judged whether or not the sheet feeding device SS has fed the sheet S in accordance with the step S14. When the sheet is supplied (Y) It is determined whether the sheet P has been printed by the printer P or not. Next, in the case of sheet printing (Y), it is judged in step S16 whether or not the sheet stacking apparatus L has positioned and stacked the printing sheet 1, and in the case of positioning and stacking (Y) , It is determined whether or not the stacking number has been completed in accordance with step S17. If the stacking number is not completed (N), the process returns to step S14, and steps S14 to S17 are repeated for the number of stacked sheets.

When the number of stacked sheets has been completed (Y), it is determined in step S18 whether or not the upper plate 20 is stacked on the plate stacking apparatus L by the plate feeding device PS. When the upper plate 20 is laminated (Y), it is judged in step S19 whether or not the entire laminated body of the lower plate 18, the printed sheet laminate 13 and the upper plate 20 is fixed, If it is fixed (Y), it is determined in step S20 whether or not the discharging device R has discharged the printing sheet laminate 13. When discharged (Y), the production of the layered X-ray grid 14 is completed.

It is needless to say that the present invention is not limited to the above-described embodiment and modifications, and various modifications and changes in design, for example, may be made without departing from the technical spirit of the present invention.

As a result of intensive research, the inventors of the present invention have succeeded in forming a multilayer X-ray grid by printing a printed layer composed of an X-ray absorbent arrival layer and an air gap layer on a sheet, and laminating a plurality of these sheets. The strength of the entire structure is increased by alternately laminating the sheet and the print layer and the X-ray absorbing portion and the X-ray transmitting portion are constituted by alternately overlapping the plurality of print layers via the sheet, And it has been succeeded in providing a stacked X-ray grid having high durability. Therefore, by providing the X-ray grid of the new structure to the X-ray technique field, it can greatly contribute to the medical technology field and the non-destructive inspection technology field using X-rays.

1 printed sheet
1a positioning sheet ball
2 sheets
3 printing layer
4 X-ray absorber arrival layer
4a arrival floor
5 void layer
5a pore layer
7 nozzle
8 drop
9 Inkjet Printers
10 X-ray Absorption Part
11 X-ray absorptive extension line
12 X-ray transmission part
12a pore layer connection
13 Printed sheet laminate
14 Stacked X-ray Grid
15 Extension line of X-ray transmission part
16 Focus
17a part
17 partial enlargement section
18 Lower plate
19 Positioning pole
20 upper plate
21 Positioning Balls
23 X-ray source
24 Primary X-ray
25 Human body
26 Scattering X-ray
27 Detainer (X-ray film, X-ray detector)
113 X-ray Transmission Line Extension Line
110 X-ray absorption part
112 X-
113 X-ray Transmission Line Extension Line
114 X-ray grid
210 Solid inserts
203 1st hook
213 fixing means
202 metal foil
212a home
211a home
211 slim plate
212 Thick plate
204 second hook
216 Towing Hook
215 Towing means
215a axis
215b elastic body
214 Base
203b first projection
204b second projection
E stacking type X-ray grid manufacturing apparatus
I input device
C Computer
O output device
M memory
SS sheet feeder
S sheet
P printer
L Sheet stacking device
R ejection device
PS plate feeder

Claims (14)

A printing sheet in which a printing layer having a predetermined pattern composed of an X-ray absorbent arrival layer and an air gap layer is formed on an upper surface of an X-ray transmissive sheet is used as a unit layer, and a plurality of said printing sheets are alternately stacked in a stacking direction And a printing sheet laminate laminated so as to be disposed,
An X-ray absorbing portion is formed by a plurality of X-ray absorbent arrival layers laminated in a vertically opposed manner with a sheet interposed therebetween,
Wherein the X-ray transmitting portion is formed by a plurality of air gap layers stacked vertically with a sheet interposed therebetween. The method according to claim 1,
An upper plate having X-ray transmittance is disposed on the uppermost surface of the printed sheet laminate,
And a lower plate having X-ray transmittance is disposed on the lowermost surface of the print sheet laminate. 3. The method according to claim 1 or 2,
Wherein the extension line in the lamination direction of the peripheral wall of the X-ray transmission portion existing in the printing sheet laminate is concentrated on one focal point, and is used as a focusing grid. 3. The method according to claim 1 or 2,
Wherein a line extending in a stacking direction of a peripheral wall of the X-ray transmitting portion existing in the printing sheet laminate is parallel to and used as a parallel grid. 3. The method according to claim 1 or 2,
Wherein the X-ray absorbent arrival layer is a printing ink containing a metal powder formed of a metal absorbing X-rays as a main component or an arrival layer (applied layer) of a printing toner. A sheet supply device for supplying a sheet having X-ray transmittance,
A printer for printing a printed layer of a predetermined pattern made of an X-ray absorbent arrival layer and an air gap layer on the supplied sheet to form a printed sheet,
A sheet stacking device for stacking the prepared print sheets in order while aligning them to complete a printed sheet stack,
A stacked body discharging device for discharging the printed sheet stacked body from the sheet stacking apparatus as a stacked X-
And a plurality of X-ray generators for generating X-rays. The method according to claim 6,
A lower plate having X-ray transmittance is first fed to the sheet stacking apparatus, and after the print sheet laminate is laminated on the lower plate, an upper plate having X-ray transmittance is formed on the uppermost surface of the print sheet laminate And a plate supply device for completing the stacked X-ray grid,
And the stacked X-ray grid is discharged from the sheet stacking apparatus by the stack discharging device. 8. The method according to claim 6 or 7,
A manufacturing apparatus for a layered X-ray grid in which a memory for storing a manufacturing method program is disposed and a computer for transmitting a signal according to the program is provided, and the manufacturing apparatus is driven by a signal from the computer. A printing sheet is formed by forming a printing layer of a predetermined pattern composed of an X-ray absorbent arrival layer and an air gap layer on the upper surface of an X-
A printing sheet laminate is formed by laminating a plurality of sheets of the printing sheet so that the sheets and the printing layers are arranged alternately in the lamination direction,
An X-ray absorbing portion is formed by a plurality of X-ray absorbent arrival layers stacked vertically with a sheet interposed therebetween,
Wherein the X-ray transmitting portion is formed by a plurality of air gap layers stacked vertically with a sheet interposed therebetween. 10. The method of claim 9,
A lower plate having X-ray transmittance is disposed,
The printed sheet laminate is formed on the upper surface of the lower plate,
Wherein an upper plate having X-ray transmittance is disposed on the uppermost surface of the printed sheet laminate. 11. The method according to claim 9 or 10,
Wherein the printing layer is formed so that an extension line of the X-ray transmission portion in the laminating direction of the peripheral wall of the X-ray transmission portion existing in the printing sheet laminate is concentrated on one focal point, and the laminated X The recipe of line grid. 11. The method according to claim 9 or 10,
Wherein the printing layer is formed so that extension lines of the peripheral wall of the X-ray transmission portion in the stacking direction of the printing sheet stack are parallel to each other, and the laminated X-ray grid is formed as a parallel grid Recipe. 11. The method according to claim 9 or 10,
Wherein the X-ray absorbent arrival layer is a printing ink containing a metal powder formed of a metal having X-ray absorptivity, or an arrival layer (coating layer) of a printing toner. 11. The method according to claim 9 or 10,
A method of manufacturing a multilayer X-ray grid in which a memory for storing a manufacturing method program is provided and a computer for transmitting a signal according to the program is installed, and the procedure of the manufacturing method is advanced by a signal from the computer.

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