KR20060038336A - A digital x-ray photoraphy apparatus for medical use, an x-ray photography system, and a method for taking an x-ray fluorescence image as digital data - Google Patents

Abstract

There are provided a medical digital radiographic device, a radiographic system, and a method for imaging X- ray fluorescent image as digital data. The radiographic device (10) includes: a fluorescent plate (38) for generating fluorescent light of image shape by X-ray radiation; a digital camera (42) for imaging the fluorescent light of the image shape from the fluorescent plate (38); and an X-ray shield material (40) arranged between the fluorescent plate (38) and the digital camera (42). The radiographic device (10)further includes a drive device (44) for changing the distance between the digital camera (42) and the fluorescent plate (38). The digital camera (42) performs imaging with a fixed magnification so that a medical image dimension is focused on the CCD with a predetermined resolution or above when the digital camera (42) is at the farthest position from the fluorescent plate (38).

Description

A digital X-ray photoraphy apparatus for medical use, an X-ray photography system, and a method for taking an X- ray fluorescence image as digital data}

 The present invention relates to the formation of a digital image that can be provided for diagnosis by a doctor, and more specifically, a medical digital X-ray imaging apparatus capable of forming a high quality digital image that can be used for diagnosis by a doctor, X A photographing system and a method of photographing an X-ray fluorescent image as digital data.

X-ray fluorescence is widely used as a method for observing the state of organs and bones inside the human body such as the chest, abdomen, limbs, and head without performing an incision. X-ray fluorescence is formed by irradiating a fluorescent plate with X-rays transmitted to the fluorescent plate based on the difference in the X-ray transmittance of the human body when the X-rays penetrate the human body.

The conventional X-ray camera uses a high-contrast silver salt film, removes the influence of scattered X-rays, and photographs fluorescent images at a high S / N ratio. The photographed silver salt film carries out development and fixing treatment, and conveys an X-ray fluorescence image as a negative film. The negative film obtained in this way is provided to the poison by doctor by irradiating white light from behind. Such a negative film is inconvenient to transport because the sheet is not foldable. In addition, for example, when a patient is diagnosed by another doctor, it is necessary for the patient to bring it to another doctor and receive a diagnosis, but because it is a sheet, the volume is high, and because it is highly personal information, transportation, storage, etc. It will cost extra money or time.

 At the present time, advances in photoelectric conversion technology and photolithography have resulted in the production of high-sensitivity, high-accuracy CCDs, and so-called digital camera technology, which uses this CCD as an imaging means, has become widespread. Also in the medical field, image digitization technology is being advanced, and a system or apparatus for digitally recording images in MRI, angiography apparatus, X-ray television, and the like is provided.

 Furthermore, various apparatuses and systems for recording images digitally even with X-ray fluorescent images have been proposed. For example, Patent Document 1 discloses an X-ray inspection apparatus using a digital camera for performing X-ray imaging. In the X-ray examination apparatus described in Patent Document 1, a fluorescent plate is disposed between an X-ray generator and a digital camera so that an object to be examined, for example, a patient, is positioned on a side close to the X-ray generator facing the fluorescent plate. It is composed. The X-rays generated from the X-ray generators form a strong and weak phase on the fluorescent plate in accordance with the intensity passing through the test object. The image formed on the fluorescent plate is photographed by a digital camera, and the image formed by X-rays is stored as digital data in a rewritable recording medium such as, for example, a flash memory or an EEPROM.

 In addition, Patent Document 2 discloses an X-ray imaging apparatus capable of automatically recognizing a fluorescent image even when a test subject moves. In addition, Patent Document 3 discloses an X-ray imaging apparatus for digitally acquiring a fluorescent image while improving contrast.

Patent Document 1: Japanese Patent Application Laid-Open No. 2001-178711

Patent Document 2: Japanese Patent Laid-Open No. 5-23326

Patent Document 3: Japanese Patent Application Laid-Open No. 10-276366

As described above, an apparatus for digitally acquiring various X-ray fluorescent images is disclosed, but all of them cut the X-rays and scattered X-rays directly using a large area of lead glass. Lead glass cuts X-rays by adding a high concentration of Pb element to X-ray transparent glass such as quartz glass. This lead glass uses a large amount of lead. However, the Pb element has an undesirable effect on the human body, and is therefore a tendency to be discarded, and it is expected that the Pb element will give an environmental load in the future. For this reason, it is desirable to strongly reduce the amount of lead glass used. Moreover, although tungsten glass is currently proposed as a substitute for lead glass, since melting | fusing point of glass and tungsten differs greatly, it is difficult to produce a plate of a certain quality of a large area, and there is an inadequate cost.

 For this reason, it is not suitable for the purpose of providing a digital X-ray fluorescent image at low cost, using a large area tungsten glass as an X-ray shield material. In addition, although the X-ray imaging apparatus described in Patent Document 2 and Patent Document 3 makes it possible to accurately acquire an X-ray fluorescent image digitally and to perform image processing, it is expensive and large-scale hospitals do not have to pay for it. Though it is not burdensome, it is not necessarily a popular X-ray imaging device.

 Fig. 11 shows a schematic perspective view of a small X-ray imaging apparatus that has been used in small-scale medical care facilities such as local medical offices and private hospitals. The X-ray imaging apparatus 100 shown in FIG. 11 is configured as a separate body from the X-ray generating apparatus, and generally includes a camera 102 and a wrinkle box 104, so that the inspection target body of the wrinkle box 104 ( The fluorescent plate 106 is arrange | positioned at the side adjacent to SP). The fluorescent plate 106 is comprised in more detail including the grid plate and the fluorescent plate, and forms the fluorescent image corresponding to a transmission X-ray. The fluorescent image formed as fluorescence passes through an X-ray shield material (not shown) called lead glass, and is then reflected by the reflecting plate 108 and projected onto the camera 110.

 The camera 110 exposes a fluorescent image on a high-contrast silver salt film and forms a latent image of the fluorescent image. The latent image formed is fixed to provide a negative film. In the case of performing X-ray imaging, the subject SP such as a patient raises the jaw to the jaw fixing part 112 formed outside the corrugation box adjacent to the fluorescent plate 106 to stabilize the photographing posture. Thereafter, X-rays are irradiated from an X-ray generator (not shown) to form a fluorescent image on the fluorescent plate by X-rays transmitted through the inspection object SP. This fluorescent image is picked up by an X-ray camera and subjected to post-treatment such as fixing treatment as described above to form a negative film. The obtained negative film is provided for diagnosis by a doctor, and in general, the result of diagnosis and the cost of X-ray imaging are charged as medical treatment.

 In recent years, the importance of the so-called second opinion, which is diagnosed by a plurality of doctors and judged by a patient rather than being treated by only one doctor, has been pointed out. In the conventional case, however, it is common practice for doctors to contact each other and to obtain a second opinion by bringing or sending an X-ray film. To do this, the patient is asked to fill out a letter of introduction to the doctor, or it is necessary to transport or send X-ray fluorescent images, which are highly private information, so that the burden on the patient is extremely high in a small area of the doctor.

 In recent years, with advances in computer and network technology, information can be shared with almost no time difference on the basis of the so-called communication infrastructure base called the Internet. For this reason, if digital data of a high-precision X-ray fluorescent image can be obtained at low cost, the second opinion can be easily transmitted by transmitting the acquired X-ray fluorescent image through a network to, for example, a remote server located at a diagnostic site. It is thought that the present invention can provide a medical diagnosis system.

 In addition, digital cameras are typical non-film imaging systems, and the digital images necessary for storage resources, computer resources, and medical resources for X-ray film sizes ranging from 6 to half sizes used in medical X-ray photographs. It is thought that it can form.

In other words, there has been a need for an X-ray imaging apparatus capable of digitally recording high-precision X-ray fluorescent images at low cost while reducing environmental load.

Moreover, there is a need for an X-ray imaging apparatus and a method of digitally forming an X-ray fluorescent image that can flexibly cope with the size of an inspection object by utilizing the characteristics of a digital camera called film-free.

In addition, by transmitting X-ray fluorescent images acquired as digital data via the Internet, an X-ray imaging system capable of obtaining second opinions easily and without regional gaps is required.

The present invention has been made in view of the above-mentioned inadequacies of the prior art, and has been made under the idea that it is possible to provide a low-cost digital X-ray imaging apparatus capable of acquiring an X-ray fluorescent image and to improve the above-mentioned incompatibility of the prior art. will be.

 That is, according to the present invention, an X-ray imaging apparatus for photographing an X-ray fluorescent image as digital data is used for photographing a fluorescent plate for generating an image-shaped fluorescence by X-ray irradiation and a fluorescence for image-forming fluorescence from a fluorescent plate. An X-ray imaging apparatus comprising an X-ray shield material disposed between the camera and the fluorescent plate and the digital camera, wherein the digital camera has a frame and a lens mounting portion and extends between the frame and the lens mounting portion. And a magnification lens equipped with a CCD cooling unit for holding the CCD outside the frame and the lens mounting unit, and equipped with a filter of an X-ray shield material and outputting image and data acquired by the CCD in a predetermined format. An X-ray imaging apparatus including an output unit is provided.

 The magnification lens of the present invention is focused so that the surface of the fluorescent plate is imaged on a CCD.

 The X-ray imaging apparatus of the present invention may further include a drive member for varying the distance between the digital camera and the fluorescent plate.

 The constant magnification lens of the present invention may be fixed to a magnification in which a photograph size dimension is formed on the CCD at a predetermined resolution or more in a state where the digital camera is positioned farthest from the fluorescent plate.

 In the present invention, a pleated box member made of a stretchable material surrounding the fluorescent plate, the digital camera, and the X-ray shield material may be included.

 Further, according to the present invention, an X-ray imaging system for displaying an X-ray fluorescent image as a digital image, the X-ray imaging system includes a lens mounting portion, extends between the frame and the lens mounting portion, and extends the CCD to the outside of the frame. The digital camera and the digital camera, each having a CCD cooling unit held in the lens and the lens mounting unit, and a magnification lens equipped with a filter of an X-ray shield material, and outputting image data acquired by the CCD in a predetermined format. An X-ray imaging system including a photographing control device for controlling the exposure amount of the camera in relation to X-ray irradiation and an image processing device for storing and image-processing image data from the digital camera can be provided.

 The X-ray imaging system of the present invention may include a function of transmitting the image data to a remote server via a network.

 The X-ray imaging apparatus of the present invention can store image data with image quality of 1000 x 1000 matrix or more.

 Furthermore, according to the present invention, as a method of photographing X-ray image as digital data, the method includes a digital camera including a constant magnification lens provided with an X-ray shield material filter and a CCD cooling unit for holding the CCD outside the frame. A step of movably arranging the fluorescent plate and a step of fixing the magnification of the constant magnification lens such that a fluorescent image having a picture size dimension is acquired by the CCD at a position farthest from the fluorescent plate at a predetermined resolution or more and the digital A method of photographing an X-ray fluorescent image as digital data including a step of adjusting a focus in response to a predetermined position with respect to the fluorescent plate of the camera and a step of acquiring an X-ray fluorescent image to the CCD at the position can be provided.

 The step of adjusting the focus in the present invention may include a step of adjusting the focus on the surface of the digital camera side of the fluorescent plate.

1 is a side view of the X-ray imaging apparatus of the present invention.

2 is a view showing the internal configuration of the wrinkle box portion notch part of the X-ray imaging apparatus of the present invention.

3 is a diagram showing details of a digital camera used in the present invention.

It is a figure which shows the specific embodiment of the digital camera in the specific embodiment of this invention.

5 is a view for explaining the function and action of the X-ray imaging apparatus of the present invention.

6 is a schematic diagram showing the relationship between the CCD and the X-ray image P formed in the CCD according to the present invention.

It is a figure which shows the other usage form of the digital camera used in this invention.

8 is an exploded view showing the configuration of an X-ray shield filter used in the present invention.

Fig. 9 is a diagram showing the optical configuration of the inside of the wrinkles box portion of the X-ray imaging apparatus for reflecting a fluorescent image and performing imaging.

10 is a diagram showing a schematic configuration of an X-ray imaging system of the present invention.

11 is a diagram showing a schematic configuration of a conventional X-ray imaging apparatus.

<Description of reference numerals indicating major parts>

10: X-ray imaging apparatus 12: Wrinkle box part

14: support portion 16: inspection object positioning portion

18: support arm 20: support

22: weight 24: mounting member

26: wrinkle box connecting member 28: fluorescent panel

30: first section 32: second section,

34: third section 36: grid plate,

38: fluorescent plate 40: X-ray shield material,

42: digital camera 44: drive device

46: wrinkle box member 50: frame

52: CCD cooling part 54: Lens mounting part

56: CCD 58: Power connector

60: data input / output connector 62: power on / off switch

64: connector 66: EXT. Terminals,

68: magnification lens 70: X-ray shield filter

72: reflection member 80: X-ray imaging system

82: recording controller 84: image analysis device

88: storage means 90: network

EMBODIMENT OF THE INVENTION Hereinafter, although this invention is demonstrated with embodiment shown to drawing, this invention is not limited to embodiment mentioned above.

 1 is a side view of the X-ray imaging apparatus of the present invention. The X-ray imaging apparatus 10 of the present invention generally includes a wrinkle box portion 12, a support portion 14, and an inspection object positioning portion 16. The corrugation box portion 12 contains an optical system for removing scattered X-rays, forming an X-ray fluorescent image at a high resolution, and photographing a fluorescent image. In addition, the support portion 14 is a weight portion for maintaining the balance even when the inspection object is raised and positioned on the support arm 18, the support 20, and the inspection object positioning portion 16 in more detail. It includes (22). The support arm 18 is bolted to the support 20 via the mounting member 24. The crimp box connecting member 26 is fixed to the support 20 by welding or the like, and the corrugation box part 12 is fixed to the crimp box connecting member 26. Moreover, the support part 14 is firmly fixed, for example, the support arm 18 becomes a bolt fixing etc. with respect to the floor surface FL. In another embodiment of the present invention, the support arm 18 may be fixed to a plate of an appropriate size, and the plate may be fixed to the bottom surface FL.

 The inspection object positioning portion 16 is moved to the weight portion 22 so as to be movable in the direction of the indicator line A so that the inspection object can be properly positioned on the fluorescent panel 28 according to the height or the photographing position of the inspection object. It is connected. The weight portion 22 is equipped with a hydraulic jack for supporting the moving object positioning unit 16 or a mechanical jack of manual or motor drive, so that the moving object and the weight-keepability with respect to the inspection object positioning unit 16 are provided. Is giving.

 In addition, in the embodiment shown in FIG. 1, the corrugation box part 12 is comprised by three sections which consist of the 1st section 30, the 2nd section 32, and the 3rd section 34 instead.

 2 is a view showing the internal configuration of the wrinkles box portion 12 by notching a part of the wrinkles box portion 12 in the X-ray imaging apparatus 10 of the present invention. As shown in FIG. 2, the fluorescent panel 28 is mounted on the first section 30 by a hinge 28a or the like, and is opened and closed with respect to the first section 30, so that the interior of the wrinkle box part 12 or the fluorescent panel is provided. Workability to 28 is improved. In addition, the fluorescent panel 28 is comprised in more detail including the grid plate 36 for removing scattering X-rays, and the fluorescent plate 38 for forming the image by X-rays. The grid plate 36 can use the glass plate in which the grid 10: 1 for reducing X-ray scattering was formed in the specific embodiment of this invention. In addition, the fluorescent plate 38 can be used as any high-sensitivity fluorescent plate known to date that is a gardium-based rare earth phosphor according to a specific embodiment of the present invention.

 In the specific embodiment of the present invention, the second section 32 holds the X-ray shield material 40 called lead glass or tungsten glass near the boundary with the first section, and at the same time, the digital camera Space for changing the distance to the fluorescent panel 28 is provided. In the embodiment shown in FIG. 2, it is shown that the third section 34 accommodates the digital camera 42. This position is a position at which the largest X-ray fluorescent image can be photographed. Specifically, an image having an X-ray photograph size of 6 sections or half sections is shown as a position formed at the highest resolution on the CCD. In addition, the second section 32 and the third section 34 house a drive unit 44 for driving the digital camera 42.

 The drive device 44 can be comprised using the worm gear 44a, the motor 44b, the mount 44c, etc. in the specific embodiment of this invention, and the digital camera 42 with respect to the fluorescent plate 38 is carried out. Is changing its relative position. The digital camera 42 is fixedly adjustable on the mount 44c and is movable in the z direction defined by the ground plane left and right with rotation of the worm gear 44a. The mount 44c is provided with adjustment means (not shown) for fine-adjusting the digital camera 42 in the X and y directions defined in directions which are orthogonal to the z direction, respectively, to provide an optimal imaging position. The X-ray imaging apparatus 10 has a configuration that can be provided.

 In addition, an imaging control line and an image / data output line (not shown) are derived from the third section. The photographing control line is connected to an exposure adjusting device (not shown), and adjusts the amount of X-ray irradiation by the exposure of the digital camera 42 and the X-ray irradiation apparatus. In addition, the photographing control line sends a signal for driving the drive device 44 to the drive device 44, and the drive device 44 can receive a signal and acquire an image having a predetermined size with an optimal dimension. By the position, the digital camera 42 is positioned. In addition, the image data output line sends image data from the digital camera 42 to an image analysis device (not shown), thereby making it possible to provide an image for diagnosis. Furthermore, between the first section and the digital camera 42 provided in the third section, a corrugation box member 46 for stray light reduction composed of elastic material as a wave shape is disposed, and the ambient light and the stray light X-rays are disposed. The incident amount to the digital camera 42 is reduced. In addition, each apparatus mentioned above of this invention is mentioned later in detail.

 3 is a diagram showing in detail the digital camera 42 used in the present invention. Fig. 3A is a front view, Fig. 3B is a side view and Fig. 3C is a rear view. As shown in Fig. 3A, the digital camera 42 used in the present invention includes a frame 50, a CCD cooling unit 52, and a lens mounting unit 54 for mounting a constant magnification lens. A CCD 56 is arranged in the CCD cooling unit 52 on the inner side of the lens mounting unit 54, and the X-ray fluorescent image can be digitally acquired under cooling.

 In addition, the CCD cooling unit 52 is formed integrally with the lens mounting unit 54 as shown in FIG. 3 (b) and extends between the frame 50 and the lens mounting unit 54. In addition, the CCD cooling unit 52 is provided with a plurality of cooling fins 52a to increase the cooling efficiency of the CCD 56. In addition, in the present invention, the CCD cooling unit 52 may be air cooled or may be cooled by a fluid refrigerant such as water cooling. The reason why the CCD 56 is cooled is to prevent the occurrence of thermal carriers accompanying the temperature rise of the CCD 56, and to secure accurate diagnosis by giving a high contrast image comparable to that of a high-contrast silver salt film. .

 Furthermore, in the present invention, a luminance multiplication CCD can also be used. In the present invention, the luminance multiplication CCD means a CCD having a sensitivity capable of acquiring an X-ray fluorescent image with sufficiently high accuracy without using an image intensifier. Also in this case, it is necessary for the pixel size to be 1000 or 1000 matrices or more as described above for high accuracy diagnosis. In the present invention, when a luminance multiplication CCD is used, an X-ray imaging apparatus can acquire not only still images but also moving images.

 When a heat carrier is generated, the charge of the portion where the image is recorded among the pixels of the CCD 56 is leaked because it is a heat carrier, and in the part where the image is not recorded, so-called space charges are generated by the generation of the heat carrier. It becomes easy and a relative contrast falls. This decrease in contrast causes blur in the affected area in X-ray fluorescent images, so even if the image is acquired digitally, the image cannot be used for diagnosis at the doctor's level.

 In the present invention, the CCD 56 is preferably as high resolution as possible. For this reason, in a specific embodiment in this invention, a side x length can form a digital image using the CCD of 1024x1360 pixel (1.4 million pixels). In the present invention, a high pixel CCD can be used if necessary, but the CCD 56 can be appropriately selected in consideration of cost and size, as long as it can provide a pixel of 1000 × 1000 matrix or more at worst. 3 (c) shows a rear surface configuration of the frame 50. On the rear side of the frame 50, an input port of a control line for driving the digital camera 42 and a port for connecting an image data output line are arranged. When the rear structure of the frame 50 is demonstrated based on more specific embodiment, the back of the frame 50 is a power connector 58, a USB connector, or the data input / output connector 60 which is an ILINK, and power on / off. A switch 62, a connector 64 for receiving a trigger signal for pressing the shutter, an EXT terminal 66 for receiving an external control signal, and the like are provided.

 The digital camera 42 stores the image data formed on the CCD 56 once in an appropriate memory, for example, a random access memory, a storage means which is a small hard disk, after the exposure ends. Thereafter, the processing apparatus included in the digital camera 42 reads out the stored image data and converts the image data into an appropriate format. The image data after conversion is stored in a rewritable recording medium, for example, a flash memory, an EEPROM, or a small hard disk, as image data sent to an image analysis device (computer: not shown).                 

 At this time, as an appropriate image format, it can be used also in the format known so far, and a bitmap (BMP) format, JPEG, JPEG2000, TIFF, MPEG, DICOM3 compatible format, etc. can be used, for example. In addition, since it is desirable for the image quality to be subdivided as much as possible, it is preferable that the number of data bits of the image data to be stored be in a format of 16 bits or more. Image stored in proper format. In the case of using the USB connector as the data input / output connector 60, for example, the data is output to the image analyzing apparatus via the connected image data output line, and the image analysis, screen display, hard copy, etc. as necessary. Is provided for diagnosis by a physician.

 4, the specific embodiment of the digital camera 42 in specific embodiment of this invention is shown. In the specific embodiment shown in FIG. 4, the constant magnification lens 68 is attached to the lens mounting portion 54. In particular, the magnification lens 68 may be a lens having a fixed magnification, but using a lens that can independently adjust the magnification and focal length. The image corresponding to the X-ray photograph size can be used as a constant magnification lens adjusted to a magnification giving a resolution of 1000 x 1000 matrix or more. Specifically, as the constant magnification lens 68 that can be used in the present invention, a commercially available product manufactured by CBC Corporation, name "megapixel lens" and model number M0814-MP can be used.

This lens has the characteristics of being able to form an image with high contrast with a CCD of 1 million pixels or more and have a high stability with a strain rate of 1.0% or less. In addition, in the present invention, by using the magnification lens 68 having the above-described characteristics, it is possible to make the depth of field shallower than in the conventional X-ray imaging apparatus. Since this makes it possible to selectively focus on the fluorescent plate 38, the influence by which the grid | lattice provided in the grid plate 36 was image | photographed is remarkably reduced.

In the present invention, by using the lens as a constant magnification, it is only necessary to adjust the distance between the digital camera 42 and the fluorescent plate 38 to acquire a fluorescent image from six to half at a constant resolution. It becomes possible. The broken line shown in FIG. 4 shows the viewing range of a constant magnification lens. 5 is a diagram illustrating the above-described function and action of the present invention. Since the digital camera 42 is equipped with the constant magnification lens fixed to the above-mentioned magnification, the viewing angle? Seen from the CCD 56 is always the same. For this reason, as the distance d with respect to the fluorescent plate 38 becomes shorter, the viewing area L of the fluorescent plate 38 becomes narrower, and as a result, images of different sizes are captured by the same CCD 56. In general, it can be formed with a constant resolution. That is, according to the present invention, for example, 6 sections (201 × 252 mm), 4 sections (252 × 303 mm), 4 sections (279 × 354 mm), diagonal (354 × 354 mm), and half section (354 × 430 mm) An appropriate diagnostic image can be provided without unnecessary the distance d giving the viewing area corresponding to the size.

6 shows the relationship between the CCD 56 and the X-ray fluorescent image P formed in the CCD image. In the embodiment shown in FIG. 6, the CCD 56 has pixels of 1024 dots and 1360 dots vertically. The X-ray fluorescent image P is reduced-projected by the constant magnification lens 68 and imaged on the CCD. At this time, the magnification of the constant magnification lens 68 is determined so that the X-ray fluorescent image P becomes a size corresponding to 1000 × 1000 matrices or more in the transverse direction of the CCD 56. By digitizing the X-ray fluorescent image P in the above-described optical relationship, high resolution image data can be formed.

In addition, since the magnification of the lens to be mounted is fixed, the size of the X-ray fluorescent image P can be made substantially constant even if the distance between the fluorescent plate 38 and the CCD 56 is changed. Further, in the present invention, it may be set to exactly match the entire pixel of the CCD 56, but it is somewhat smaller than the pixel area of the CCD 56 and 1000 in relation to the minute fluctuation of the image size due to the focus adjustment. It is preferable to form an X-ray optical image so as to secure a resolution of × 1000 matrix or more.

Fig. 7 is a diagram showing another use mode of the digital camera 42 used in the present invention. In the use form shown in FIG. 7, the X-ray shield filter 70 is attached to the tip of the constant magnification lens 68. In the case of this embodiment, a large area lead glass and an X-ray shield material such as tungsten glass are not necessary. In the embodiment shown in Fig. 7, there is no difference in the quality of the acquired image and data, but since the amount of the X-ray shield material can be significantly reduced, for example, X-ray shielding is performed using a large amount of tungsten glass. Even if the filter is manufactured, the X-ray imaging apparatus is not expensive, and the environmental load can be greatly reduced.

 8 is an exploded view showing the configuration of the X-ray shield filter 70 used in the present invention. The X-ray shield filter 70 used in the present invention generally includes a filter holder 70a, a spacer 70b, and an X-ray filter 70c. The filter holder 70a is provided with a screw portion 70d for screwing into the constant magnification lens 68, and is configured to be mounted on the constant magnification lens 68 without shaking. In addition, the filter holder 70a is provided with a passage 70e having a diameter that does not obstruct the viewing angle of the constant magnification lens 68, so that the above-described optical relationship is not impaired. The spacer 70b is inserted between the filter holder 70a and the X-ray filter 70c and used to hold the X-ray filter 70c without shaking.

 The spacer 70b can be used in any thickness, diameter, number of sheets, or arrangement as long as it is a thickness and diameter capable of stably retaining the X-ray filter 70c. In the present invention, the X-ray filter 70c can be made of, for example, lead glass, tungsten glass, lead-tungsten glass, or any thickness so long as it can sufficiently shield X-rays. You can do it. In addition, it is necessary to make the diameter of the X-ray filter 70c larger than the diameter given by the viewing angle of the constant magnification lens in order to obtain favorable X-ray shield characteristics.

 FIG. 9 is a diagram showing an optical configuration of the inside of the wrinkles box portion 12 of the X-ray imaging apparatus in which imaging is performed by reflecting a fluorescent image. The structure shown in FIG. 9 is effective when space saving is performed like a vehicle-mounted X-ray imaging apparatus or the like. Fig. 9 (a) is a diagram showing the internal structure of the pleat box portion 12 of the X-ray imaging apparatus for photographing the lateral arrangement when imaging the abdomen, etc., and Fig. 9 (b) is the chest X It is a figure which shows the internal structure of the wrinkles box part 12 of the X-ray imaging apparatus of a vertical arrangement at the time of taking a ray photograph etc .. In the X-ray imaging apparatus shown in FIG. 9, the reflection member 72 is arrange | positioned inside the wrinkle box part 12 in all, and it is set as the structure which image | photographs by reflecting a fluorescent image once. Also in this case, the magnification of the constant magnification lens is fixed so that it can cope with the photograph size, such as from 6 to half, according to the distance from the reflecting member 72 as described above. In addition, although the reflection member 72 of this invention can be comprised as a reflection mirror, in another embodiment, a prism can be used and total reflection by a prism can also be used.

 10 is a diagram showing a schematic configuration of an X-ray imaging system of the present invention. The X-ray imaging system 80 shown in FIG. 10 includes an X-ray imaging apparatus 10, an imaging control device 82, and an image analysis device 84. The shooting control device 82 includes a trigger control unit for irradiating X-rays from an X-ray generator in association with a shutter control unit for causing exposure to start and a signal for instructing exposure start, and a signal for instructing a trigger signal or exposure start. It is configured to control the exposure so as to be triggered by a given exposure amount, for example, an exposure control unit which is an integrated exposure total or a timer and a drive control device for driving the drive device 44.

 The imaging controller 82 sends each signal to the X-ray imaging apparatus via the imaging control line 86a to form image data. The formed image data is sent to the image analysis device 84 via the image data output line 86b and stored in an appropriate memory, and then various processes are performed. In addition, the image analysis device 84 may control the imaging control device 82 via the line 86c as necessary. Moreover, in another form of the X-ray imaging system 80 of this invention, the image analysis apparatus 84 and the imaging control apparatus 82 can also be comprised integrally.                 

 The image data acquired by imaging of a predetermined exposure time or exposure amount is sent to the image analysis device 84, and image processing is performed. In the image processing in the present invention, a processing known to date such as a trimming process that gives an image of a predetermined size other than adjustment of contrast or density, etc., is performed using a keyboard 84a or a mouse 84b, for example, a medical radiologist or the like. Can be operated on by any qualified operator. The image data after the image processing is completed can be displayed on the display screen 84c and used for reading by a doctor or the like.

 The obtained image data is a storage means 88 composed of a database or the like connected to the image analysis device 84, and stored in a format in which text data such as a patient's name, site, photographing date and time, finding, and photographer can be referred to. do. Although this image data is diagnosed by a doctor directly reading, for example, it is assumed that a radiologist must read it in the future. In this case, a diagnosis can be made if there is a radiologist at the photographed site, but for example, a radiologist cannot be permanently located in a medical underserved area in a private hospital or a province. In addition, even when there is a radiologist, it is sometimes necessary to obtain a second opinion by the patient or the like.

 For this purpose, the image analysis device 84 is connected to a network 90 connected by the Internet or a dedicated communication line. For example, a remote server (not shown) can be used for a suitable method, for example, e-mail. It can be used and sent with text data accompanying digital images. In this case, the remote server can be configured with a mail server function to protect privacy by issuing a dedicated mail address, user account, password, and the like. In transmission and reception, in order to further protect privacy, it is preferable to perform transmission and reception using encryption software.

 The present invention has been described so far with the specific embodiments shown in the drawings, but the present invention is not limited to the embodiments shown in the drawings, and the means known to those skilled in the art so far can provide equivalent functions and actions. It can be used in anything, such as a technique, a material, or a material.

As described above, the present invention can provide an X-ray imaging apparatus capable of digitally recording high-precision X-ray optical images at low cost while reducing environmental load.

 Moreover, according to this invention, the X-ray imaging apparatus and X-ray fluorescent image which can respond flexibly to the magnitude | size of an inspection object can be provided using the characteristic of the digital camera called a film free, and can provide. .

 Furthermore, the present invention can be provided with an X-ray imaging system capable of obtaining a second opinion easily and without local gap by transmitting the X-ray fluorescent image acquired as digital data via the Internet.

Claims (10)

An X-ray imaging apparatus for photographing X-ray fluorescent images as digital data, comprising: a fluorescent plate for generating image-shaped fluorescence by X-ray irradiation, a digital camera for photographing image-shaped fluorescence from the fluorescent plate, and the fluorescence An X-ray imaging apparatus including an X-ray shield material disposed between a plate and the digital camera, The digital camera, Frame,  A CCD cooling unit having a lens mounting unit and extending between the frame and the lens mounting unit and holding the CCD outside the frame; A magnification lens mounted on the lens mounting portion and mounted with a filter of an X-ray shield material; And an output unit for outputting the image data acquired by the CCD in a predetermined format. The method according to claim 1, And said constant magnification lens is focused so that said fluorescent plate surface is imaged on a CCD. The method according to claim 1 or 2, The X-ray imaging apparatus further includes a drive member for varying the distance between the digital camera and the fluorescent plate. The method according to any one of claims 1 to 3, And said constant magnification lens is fixed at a magnification such that a photograph size dimension is formed on the CCD at a resolution higher than or equal to a predetermined resolution in a state where the digital camera is positioned farthest from the fluorescent plate. The method according to any one of claims 1 to 4, And an pleated box member made of a stretchable material surrounding the fluorescent plate, the digital camera, and the X-ray shield material. An X-ray imaging system for displaying an X-ray optical image as a digital image, wherein the X-ray imaging system is A CCD cooling unit having a lens mounting portion and extending between the frame and the lens mounting portion to hold the CCD outside the frame; A digital camera equipped with a magnification lens mounted on the lens mounting portion and mounted with a filter of an X-ray shield material, and outputting image data acquired by the CCD in a predetermined format;  An imaging controller for controlling the exposure amount of the digital camera in relation to X-ray irradiation;  And an image processing apparatus for storing and processing image data from said digital camera. The method according to claim 6, And said X-ray imaging system includes a function of transmitting said image data to a remote server via a network.  The method according to claim 6 or 7,  And said X-ray imaging apparatus stores image data with image quality of 1000 x 1000 matrix or more. As a method of photographing X-ray image as digital data, the method A step of movably arranging a digital camera including a constant magnification lens provided with an X-ray shield material filter and a CCD cooling unit which holds the CCD outside the frame with respect to the fluorescent plate, Fixing the magnification of the magnification lens such that the fluorescent image having the picture size dimension is acquired in the CCD at a position farthest from the fluorescent plate so as to obtain a predetermined resolution or more, and  Adjusting focus in response to a predetermined position with respect to the fluorescent plate of the digital camera; And acquiring the X-ray fluorescent image at the position into the CCD. The method according to claim 9, And the step of adjusting the focus comprises the step of adjusting the focus on the surface of the digital camera side of the fluorescent plate, wherein the X-ray optical image is captured as digital data.

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