GB2603014A - Apparatus for marking irradiation area for hand-held x-ray device - Google Patents

Abstract

A handheld x-ray device includes an upper cover 100, lower cover 200, x-ray radiation unit 300, radiation tube 400, apparatus 500 and lower support 600. The apparatus 500 includes a cylindrical member (510, fig 6), reflector (520, fig 6), visible light source (550, fig 6), PCB (540, fig 6) and PCB guide (530, fig 6). Light emitted from the light source 550 is reflected by the reflector 520 and marks an illumination area on a subject. The irradiation area may be viewed before performing the x-ray imaging, to ensure correct positioning and alignment of the device. The light source 550 may be an LED. The reflector 520 may have an inclined surface and may allow x-rays to pass through the surface. The portable device may be used for oral or dental imaging, without the need for a collimator.

Description

APPARATUS FOR MARKING IRRADIATION AREA FOR HAND-HELD X-

RAY DEVICE

BACKGROUND OF THE INVENTION

Field of the Invention

The present disclosure relates to an apparatus for marking an irradiation area for a hand-held X-ray device. More specifically, the present disclosure relates to a technology ID for an apparatus that simply includes an LED light source inside a radiation tube. Because a hand-held X-ray device has a small internal structure, the apparatus does not employ a complex collimator structure that uses a reflector, a diaphragm, or the like.

Description of the Related Art

Usually, an X-ray beam needs to be aligned in a manner that is incident perpendicularly to a subject and is above the center of a sensor for acquiring an image. When the X-ray beam is not aligned in this manner, a cone-cut phenomenon occurs. A cone-out portion, resulting from being insufficiently exposed to X-rays, appears as a post-processing transparent area in X-ray imaging. When an image is expressed digitally, the cone-out portion appears as being opaque or in white.

FIG. 1 is a photograph showing the cone-cut phenomenon.

To prevent the cone-out phenomenon, the center of the X-ray beam is aligned in a manner that is perpendicular to an image sensor. Unsuitable fixation of the image sensor also causes the cone-out phenomenon.

While being held by a sensor holder, a sensor for acquiring an image of the subject is inserted into an oral cavity to capture the image thereof. At this point, a user regards the end of the sensor holder as a position of the image sensor in the oral cavity. Then, the user aligns a hand-held X-ray device with a straight line, causes an emission angle to be in the straight line with a subject, and performs X-ray imaging.

FIG. 2 is a view illustrating a commonly used sensor holder; With reference to FIG. 2, the size and weight of the sensor holder make the sensor holder inconvenient to use. Furthermore, the long distance of the hand-held X-ray device to the subject requires an increase in X-ray radiation time. Thus, long-time X-ray exposure can have a harmful effect on a human body.

In addition, a collimator is difficult to install within a radiation tubc of the hand-hold X-ray device.

An X-ray collimator itself weighing 2 kg or more in the related art is fairly heavy. A volume of the X-ray collimator 25 also makes the X-ray collimator difficult to mount inside the radiation tube.

The hand-held X-ray device itself weighs 1.5 Kg to 2.5 Kg. An X-ray collimator having a diaphragm in the related art weighs 2 Kg or more. Thus, the addition of the X-ray collimator to the hand-held X-ray device makes the hand-held X-ray device less portable.

A distance of 5 cm or 2 inches from an end portion of the radiation tube of the hand-held X-ray device to the subject is recommended to acquire a high-quality image. However, when a W separate large-volume collimator is mounted in the front of the radiation tube, the distance for acquiring the high-quality image cannot be secured.

The foregoing is intended merely to aid in the understanding of the background of the present disclosure, and is not intended to mean that the present disclosure falls within the purview of the related art that is already known to those skilled in the art.

Document of Related Art (Patent Document 1) Korean Patent No. 10-1404004 (June 13, 2014)

SUMMARY OF THE INVENTION

According to the present disclosure, there is provided an apparatus capable of marking an X-ray irradiation area for a hand-held X-ray device.

The apparatus according to the present disclosure does not employ a complex collimator structure that uses a reflector, a diaphragm, or the like because the hand-held X-ray device has a small internal structure. Instead, the apparatus includes a visible light source (such as an LED light source) to be simply mounted inside a radiation conduit of the hand-held X-ray device and thus can mark the X-ray irradiation area.

The apparatus according to the present disclosure employs a structure where heat occurring in the light source is dissipated from the light source itself. This structure enhances the portability of the hand-held X-ray dcvico and thus increases the user convenience in use.

The use of the apparatus for marking the irradiation area for the hand-held X-ray device according to the present disclosure makes it possible to align an X-ray beam emitted to a subject and an image sensor with each other in an exactly perpendicular manner.

The apparatus for marking the irradiation area for the hand-held X-ray device has a simple lightweight structure enhancing the portability. Thus, the hand-hold X-ray device, made portable, can be used conveniently without being fixed to a specific place.

The apparatus for marking the irradiation area for the hand-held X-ray device, itself, may employ a structure where the light source is cooled. Thus, the efficient heat dissipation and the convenience in use can be provided. According to another aspect of the invention, there is 5 provided a portable X-ray device comprising: an X-ray radiation unit for emitting X-ray radiation; a radiation conduit arranged to receive and guide X-rays emitted from the X-ray radiation unit along the radiation conduit to an output of the radiation conduit; a visible light source and a reflector mounted within W the radiation conduit such that visible light emitted from the light source is reflected by the reflector along said radiation conduit and out said output of the radiation conduit to illuminate an area of the subject to bc irradiated. Typically, the visible light source will be an LED light source, although other visible light sources could be used. The radiation conduit is normally tubular in shape although other geometries of conduit could be used.

BRIEF DESCRIPTION OF THE DRAWINGS

Thc above and other objectives, features, and other advantages of the present disclosure will be more clearly understood from the following detailed description when taken 25 in conjunction with the accompanying drawings, in which: FIG. 1 is a photograph showing a cone-cut phenomenon; FIG. 2 is a view illustrating a commonly used sensor holder; FIG. 3 is a view illustrating a hand-hold X-ray device 5 including an apparatus for marking an irradiation area according to an embodiment of the present disclosure; FIG. 4 is a perspective exploded view illustrating the hand-held X-ray device including the apparatus for marking the irradiation area according to the embodiment of the present 10 disclosure; FIG. 5 is a view illustrating the apparatus for marking the irradiation area according ko the embodiment of the present disclosure; FIGS. 6 and 7 are perspective exploded views each 15 illustrating the apparatus for marking the irradiation area according to the embodiment of the present disclosure; and FIG. 8 is a view illustrating an example where the irradiation area for the hand-held X-ray device is marked according to the embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 3 is an exterior appearance of a hand-held X-ray device including an apparatus for marking an irradiation area 25 according to an embodiment of the present disclosure.

The hand-held X-ray device can provide simplified portability to a user, compared with a stationary X-ray device. However, when X-ray imaging is perforited using a portable handheld X-ray device, the X-ray beam and a subject arc not precisely aligned with each other. Thus, a cone-cut phenomenon or the like occurs frequently.

The X-ray imaging can be performed without causing the cone-cut phenomenon or the like by additionally including a sensor holder for precise alignment. However, the W inconvenience of additionally using the sensor holder, the problem in securing a distance to the subject for the X-ray imaging, long-time exposure to X-rays, and the like occur. According to thc present disclosure, it is proposed that thc apparatus for marking the X-ray irradiation area is provided inside a radiation tube of the hand-held X-ray device in FIG. FIG. 4 is a perspective exploded view illustrating the hand-held X-ray device including the apparatus for marking the irradiation area according to the embodiment of the present disclosure. An apparatus 500 for marking the irradiation area is coupled, in a screw-fastened manner, to a combination member within thc radiation tube. Other fasteners could of course be used.

The hand-held X-ray device includes an upper cover 100, a 25 lower cover 200, an X-ray radiation unit 300, a radiation tube 400, the apparatus 500 for marking the irradiation area according to the present disclosure, and a lower support 600. The hand-held X-ray device includes the apparatus 500 for marking thc irradiation area, in thc middle of a pathway to thc 5 subject. The apparatus 500 for marking the irradiation area in advance marks the irradiation area that guides X-rays, emitted from the X-ray radiation unit 300, toward the subject. Thus, the X-rays pass through the radiation tube 400 and precisely reach the subject.

An LED light source is included in the apparatus 500 for marking the irradiation area. When the LED light source is operated before the X-rays are emitted, light emitted from the LED light source in advance marks the irradiation arca to be irradiated with the X-rays passing through the radiation tube 15 400, on the subject.

The irradiation area marked on the subject by the light emitted by the LED light source can be viewed in advance. Thus, while viewing the irradiation area, it can be checked whether or not the irradiation area is exactly the same as an area, on which the X-Ray imaging is required, of the subject. If not, a fine adjustment can be made for exact positioning of the irradiation area. If the irradiation area to be irradiated with the X-rays is exactly the same as the area, on which the X-ray imaging is required, of the subject, the X-ray radiation unit 300 emits the X-rays and thus performs the X-ray imaging.

Desirably, the LED light source and the X-ray radiation unit 300 have respective operation switches on the lower support 600. Desirably, in addition to the operation switches, the lower support 600 may further include a power supply (not illustrated) supplying power to the apparatus 500 for marking the illumination area.

The apparatus 500 for marking the irradiation area, illustrated in FIGS. 5, 6, and 7, is configured to include a cylindrical member 510, a reflector 520, a PCB guide 530, a PCB 540, an LED light source 550, and a fastening screw 560.

The cylindrical member 510 is configured to include a connection portion 511, a hollow body member 512, and a reflector combination portion 513. Thc connection portion 511 is externally threaded in such a manner as to be combined with the X-ray radiation unit 300. The hollow body member 512 is provided on the connection portion 511. An inclination surface of the reflector combination portion 513, formed by obliquely cutting off a portion of the hollow body member 512 from the top thereof to close to the connection portion 511, is brought into contact with the reflector 520.

The reflector 520 is configured in such a manner that a diameter thereof is minimized to a size that allows all X-rays emitted therebehind to pass through an inclined surface of the reflector 520.

A front surface of the reflector 520 is brought into close contact with a reflector combination protrusion 532 of the PCB guide 530 that will be described below, and a rear surface thereof is brought into close contact with a combination portion 513 of the cylindrical member 510.

Light propagating from the LED light source 550 is reflected by the front surface of the reflector 520 toward the radiation tube 400.

The reflector 520 allows all X-rays emitted from the X-ray radiation unit 300 therebehind to pass through.

The PCB guide 530 is configured to include: a pair of body members 531, as guide members supporting the PCB 540, being combined in a screw-fastened manner to the reflector combination portions 513, respectively, of thc cylindrical member 510, and extending lengthwise in the form of a rectangle; a pair of combination protrusions 532 protruding from upper surfaces, respectively, of the body members 531 in such a manner as to be brought into close contact with the reflector 520; a pair of PCB combination members 533 extending perpendicularly from end portions, respectively, of the body members 531 in a direction opposite to the reflector 520; and a pair of screwing grooves 534 formed in such a manner that the PCB combination member 533 and the PCB 540 arc combined with the fastening screws 560, respectively, in a screw-fastened manner. In alternative embodiments, glue or other fastener could be used to replace the screws.

Desirably, the PCB guide 530 is formed of aluminum in such a manner as to dissipate heat.

The PCB 540 is also forited of aluminum in such a manner as to dissipatc hcat. For combination with thc PCB 540, the LED 5 light source 550 is bonded with the central portion of the PCB 540 using a heat conductive adhesive.

Screw fastening guidance portions 541 are further provided in such a manner as to be inward recessed from opposite lateral surfaces, respectively, of one side of the PCB 540. Thus, with W the fastening screw 560, the PCB 540 and the PCB guide 530 can be combined with each other in a screw-fastened manner.

FIG. 8 illustrates an example where the irradiation area for the hand-hold X-ray device is markcd according to the present disclosure.

As illustrated in FIG. 8, before performing the X-ray imaging, the user first causes the LED light source to emit the light toward the area, on which the X-ray imaging is required, of the patient to mark the irradiation area.

In a case where the center portion indicated on the irradiation area is not exactly the same as that of the area, on which the X-ray imaging is required, of the patient, even when the X-ray imaging is performcd, an imago sensor may not precisely capture an image of an affected area of the patient, or an opaque or bright white image may be generated due to the cone-cut phenomenon.

Therefore, with the apparatus for marking the irradiation area to the present disclosure, when the center portion of the irradiation area marked by the light emitted by the LED light source is precisely aligned with that of the affected area of the patient and then the X-ray beam is emitted, a precise clear image of the affected area of the patient can be obtained by performing the X-ray imaging.

Although the specific embodiment of the present disclosure has been described for illustrative purposes, those skilled in W the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope of the invention as defined in the accompanying claims.

Claims (11)

1. WHAT IS CLAIMED IS: 1. An apparatus for marking an irradiation area for a hand-held X-ray device, the device comprising an upper cover, a 5 lower cover, an X-ray radiation unit, a radiation conduit, the apparatus, and a lower support, the apparatus comprising: a cylindrical member; a reflector; a PCB guide; a PCB; and a visible light source; wherein light emitted from the visible light source is reflected by the reflector and marks the irradiation arca on a subject in front of the reflector.
2. 2. The apparatus of claim 1, wherein the cylindrical member comprises: a connection portion being externally threaded in such a manner as to be combined with the X-ray radiation unit; a hollow body member being provided on the connection portion; and a reflector combination portion, with an inclination surface thereof being formed by obliquely cutting off a portion of the hollow body member from the top thereof to close to the 25 connection portion and being brought into contact with the reflector.
3. 3. The apparatus of claim 1, wherein a front surface of the reflector is brought into close contact with a reflector 5 combination protrusion of the PCB guide, a rear surface thereof is brought into close contact with a combination portion of the cylindrical member, and light propagating from the light source is reflected by the front surface of the reflector toward the radiaticn tube.
4. 4. The apparatus of claim 3, wherein the reflector is configured in such a manner that a diameter thereof is minimized to a size that allows all X-rays omitted thcrcbchind to pass through an inclined surface of the reflector
5. 5. The apparatus of claim 1, wherein the PCB guide comprises: a pair of body members, as guide members supporting the PCB, being combined in a fastened manner with the reflector 20 combination portions, respectively, and extending lengthwise in the form of a rectangle; a pair of combination protrusions protruding from upper surfaces, respectively, of the body members in such a manner as to be brought into close contact with the reflector; a pair of PCB combination members extending downward perpendicularly from end portions, respectively, of the body members in a direction opposite to the reflector; and a pair of screwing grooves being formed in such a manner that the PCB combination member and the PCB are combined with 5 fastening screws, respectively, in a screw-fastened manner.
6. 6. The apparatus of claim 5, wherein the PCB guide is formed of aluminum.
7. 7. The apparatus of claim 1, wherein for combination with the PCB, the light source is bonded with a central portion of the PCB using a heat conductive adhesive.
8. 8. The apparatus of claim 1, further comprising: a pair of 15 screw fastening guidance portions configured to be inward recessed from opposite lateral surfaces, respectively, of one side of the PCB.
9. 9. The apparatus of claim 1, wherein the PCB is formed of 20 aluminum and dissipates heat.
10. 10. The apparatus of claim 1, wherein switches that turn on and off the light source and the X-ray radiation unit, respectively, are provided on the lower support.
11. 11. A portable X-ray device comprising: an X-ray radiation unit for emitting X-ray radiation; a radiation conduit arranged to receive and guide X-rays omitted from the X-ray radiation unit along the radiation 5 conduit to an output of the radiation conduit; a visible light source and a reflector mounted within the radiation conduit such that visible light emitted from the light source is reflected by the reflector along said radiation conduit and out said output of the radiation conduit to W illuminate an area of the subject to be irradiated.