KR20200005688A - Apparatus for Reducing Scatter Radiation in Mobile X-ray Equipment - Google Patents

Abstract

According to the present invention, a device for blocking secondary radiation of a mobile radiographic apparatus is to provide a means which is coupled to a collimator of a radiographic apparatus to be used to prevent radiation exposure caused by secondary radiation scattered from the radiographic apparatus for medical staff or surrounding patients if using a mobile radiographic apparatus in a hospital room, an operating room, an intensive care unit, a recovery room, etc. to take an X-ray. The device for blocking secondary radiation of a mobile radiographic apparatus can block secondary radiation scattered in a radiographic process from a mobile radiographic apparatus including a radiation generation apparatus and a collimator coupled to the radiation generation apparatus. The device comprises: a blocking container having a shape of a frustum of a quadrangular pyramid becoming narrower towards an upper end thereof, wherein the upper end and a lower end thereof are opened; a rectangular connection plate connected to four edges of the upper end of the blocking container to be vertically extended from a center axis of the blocking plate towards an opposite side of the center axis; and a coupling means to detachably couple the connection plate to the collimator.

Description

Apparatus for Reducing Scatter Radiation in Mobile X-ray Equipment}

The present invention relates to a secondary radiation shielding device of a mobile radiograph. More particularly, the present invention relates to an apparatus for preventing exposure to the surroundings due to secondary radiation generated in a photographing process of a subject in a mobile radiography apparatus capable of moving to a hospital room or the like to perform radiography on a subject.

Radiation is a kind of invisible light beam with energy. Radiation types include alpha rays, beta rays, gamma rays, x-rays, and electromagnetic waves, which are emitted when the radioactive element decays. Radiation, which began with the discovery of X-rays by Roentgen in 1895, has been useful for many years until now, and has contributed greatly to the diagnosis and treatment of patients in the medical field. Radiography technology is a big part of the medical field. In particular, recent advances in technology have led to the development of digital radiography equipment combined with digital technology, which contributes to much more accurate and rapid diagnosis and effective disease treatment than ever before.

However, since exposure from radiation causes fatal damage to the human body, such as those associated with the development of diseases such as cancer and leukemia, efforts should be made to reduce the risk of exposure during medical radiography. The problem of radiation exposure in taking a radiographic image and performing a test using a radiographic imager is that it affects not only the patient being examined but also the medical staff performing the test. Therefore, the radiographic room and the like have enough safety equipment and safety facilities. However, the mobile radiography machine is not used in a well-equipped radiography room, but when the patient cannot move to the radiography room, the portable radiography device is taken to a hospital room, operating room, intensive care unit, recovery room, etc. It is a very vulnerable reality. In particular, when performed in a hospital room, operating room, intensive care unit, recovery room, etc., there has been a problem of unprotected exposure to unwanted exposure risks not only to the medical staff but also to the surrounding patients.

However, at the time of diagnosis in a university hospital, etc. using a mobile radiography system for a patient admitted to a multi-room, the reality is that most hospitals take pictures without protection of the surrounding patients. However, patients who cannot move are forced to be exposed to radiation exposure. In some cases, a separate radiography zone is created for each ward to move the patient's bed to the shooting area and to take pictures. This does not take advantage of the mobile radiography system, which can be taken to a patient's place. This results in discomfort for both the staff and the patient.

Mobile radiographers are also legally regulated because of serious exposure problems. The rules for the safety management of diagnostic radiation generators are “must be equipped with a portable medical X-ray protective partition when photographed outside the operating room, emergency room or intensive care unit. It is stated. ” Therefore, the medical radiation shielding wall may be purchased or manufactured and used. In the case of the medical radiation shielding wall, application is very difficult in reality. For example, if you are taking a patient using an intermediate bed in a shared room, you will need three shielding walls, so if you are going to photograph many patients in multiple rooms, you may need to share three or more barriers with a mobile radiography system. It is difficult to move because it is not used in the actual clinical practice in many cases.

Therefore, there is an urgent need for the development of assistive devices to reduce exposure of nearby patients or medical staff when using mobile radiators.

In order to solve the above problems, the secondary radiation shielding device of the mobile radiograph according to the present invention is radiographed using a mobile radiograph in a hospital room, operating room, intensive care unit, recovery room, etc. It is an object of the present invention to provide a shielding means that can be used in combination with a collimator of a radiographer to prevent radiation exposure due to secondary radiation scattered from the radiographer.

In a preferred embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention, in the mobile radiographer comprising a radiation generating device and a collimator coupled to the radiation generating device, the secondary scattered during the radiographic process A flux limiting device capable of shielding radiation, comprising: a shield barrel having a shape of a frustum of quadrangular pyramid that is narrowed toward an upper end thereof, wherein the upper and lower ends are open; A rectangular connecting plate connected to the upper four sides of the shielding tube and extending toward the opposite side of the central axis perpendicular to the central axis of the shielding tube; And coupling means for detachably coupling the connecting plate to the collimator. It is preferable to include a.

Another embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention, in addition to the above-described features, the coupling means is fixed to the edge of the radiation flux outlet of the collimator, the cross section in the width direction as a U-shape It is also preferable that the open side of the U shape toward the radiation exit, the U-shaped groove portion is characterized in that the pair of rail form, so that the connecting plate can be slidably inserted.

In addition, the upper opening area of the shield barrel is equal to or larger than the opening area of the radiation beam outlet when the radiation flux outlet of the collimator is opened to the maximum, and the lower opening area of the shield cylinder is the radiation flux. It is also possible to set it as the secondary radiation shielding device of the mobile radiography apparatus which is equal to or larger than the irradiation field area when the exit is opened to the maximum and the distance from the lower end of the shielding tube to the radiation generating device is SID.

In addition to the above-described features, another embodiment of the present invention includes one or more extension means shaped like the shielding cylinder, wherein the length of each of the top four sides of each of the extension means is the bottom four sides of the shielding cylinder. Each length is shorter than the length of each of the lower four sides of the upper extension means coupled to its upper side of the extension means, each of the extension means is detachably coupled to the shielding tube or the upper extension means, the extension It is also preferable to use a secondary radiation shielding device of a mobile radiograph, characterized in that the upper inner surface of each of the means is coupled to the shielding tube or the lower outer surface of the upper extension means, in addition to the upper end of the shielding cylinder. The opening area is equal to the opening area of the radiation exit when the radiation exit of the collimator is opened to the maximum. The lower opening area of the shielding cylinder is wider than or equal to the irradiation field area when the radiation flux exit is opened to the maximum and the distance from the lower end of the shielding cylinder to the radiation generating device is SID. It is also possible to set it as the secondary radiation shielding device of a mobile radiography device.

As described above, in the secondary radiation shielding apparatus of the mobile radiography apparatus according to the present invention, the shielding means is coupled to the collimator, and the scattering is performed without affecting the irradiation field range of the primary radiation for producing a medical image of the diagnosis subject. By selectively shielding the secondary radiation, even if the radiograph is taken using a mobile radiography in a hospital room, operating room, intensive care unit, recovery room, etc., the radiation exposure can be prevented for the medical staff and the patients in the vicinity. In general, when a patient is diagnosed with a mobile radiography device, the radiation dose is measured to be 27.79 μGy at a distance of 1 m. However, when the secondary radiation shielding device of the mobile radiator according to the present invention is used, the radiation dose is reduced to 10.21 μGy. As a result, it can be seen that the effect of reducing 63% of the radiation exposure dose within a distance of 1m.

In addition, since the secondary radiation shielding device of the mobile radiography apparatus according to the present invention has a small and lightweight structure, the secondary radiation shielding device is easy to carry and can be coupled to the collimator in a sliding manner, thereby providing excellent convenience in use. Therefore, it is not necessary to use several heavy and large shielding walls, and it is not necessary to move the patient's bed out of the shared room, and to avoid evacuating the patients near the bed to prevent exposure. .

In addition, the manufacturing cost is lower than the shielding wall, which requires a lot of manufacturing costs, and the operating cost is also reduced, because the manpower required for transporting the shielding wall is reduced.

In addition, since the secondary radiation shielding apparatus of the mobile radiography apparatus according to the present invention may include an extension means detachable from the shielding tube, when the SID is far away according to a diagnosis part, the extension means may be combined to increase the shielding range. As a result, the exposure by secondary radiation can be prevented more effectively. There is an advantage that the shielding tube and the extension means can be used in combination with the situation and the condition.

1 shows a schematic diagram of radiation emitted from a mobile radiography apparatus including a collimator.
FIG. 2 is a plan view of the field adjuster of the collimator in the mobile radiograph.
Figure 3 shows an embodiment of a secondary radiation shielding device of a mobile radiograph according to the present invention.
Figure 4 is a perspective view for explaining the connection of the shield, the connecting plate and the coupling means of one embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention.
Figure 5 shows a longitudinal cross-sectional view of the shielding means in one embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention.
Figure 6 shows another embodiment of the secondary radiation shielding apparatus of the mobile radiograph according to the present invention.
Figure 7 is a perspective view for explaining the connection between the shielding tube and the extension means in another embodiment of the secondary radiation shielding device of a mobile radiograph according to the present invention.
8 is a plan view and a side cross-sectional view showing another embodiment of the connecting plate of the secondary radiation shielding device of the mobile radiograph according to the present invention.

DETAILED DESCRIPTION Hereinafter, the present invention will be described in detail so that the above-described objects and features become clear, and thus, those skilled in the art can easily implement the technical idea of the present invention. In addition, in the following description of the present invention, well-known technology related to the present invention is well known in the technical field, and if it is determined that the detailed description of the known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be given. It will be omitted.

In addition, the terminology used in the present invention was selected as a general term that is widely used at present, but in certain cases, the term is arbitrarily selected by the applicant, and in this case, since the meaning is described in detail in the corresponding part of the present invention, a simple term It is to be understood that the present invention is to be understood as a meaning of terms rather than names. The terms used in the description of the embodiments are only used to describe specific embodiments, and are not intended to limit the embodiments. Singular expressions include plural expressions unless the context clearly indicates otherwise.

The embodiments may be modified in various forms and have various additional embodiments, in which specific embodiments are shown in the drawings and related detailed descriptions are set forth. However, this is not intended to limit the embodiments to a particular form, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the embodiments.

Expressions such as “first”, “second”, “first” or “second” in the description of various embodiments may modify various elements of the embodiments, but do not limit the corresponding elements. For example, the above expressions do not limit the order and / or importance of the corresponding elements. The above expressions may be used to distinguish one component from another.

Hereinafter, with reference to the accompanying drawings will be described the present invention. 1 shows a schematic diagram of radiation emitted from a mobile radiography apparatus including a collimator. As shown in FIG. 1, most radiators including mobile radiators include a radiation generating apparatus 100 for generating a radiation flux for radiography, a collimator 200 for adjusting a field of irradiation for the generated radiation flux, and a patient's It includes a detector 400 for generating a diagnostic image in response to the radiation flux passing through the diagnostic site. In more detail, the radiation flux is generated from the X-ray tube 110 inside the radiation generator 100, the radiation flux generated in the X-ray tube 110 is the radiation generator 100 While passing through the collimator 200 attached to the lower end of the irradiation range of the radiation flux is limited to within a certain range, to limit the irradiation field within the minimum range required for the diagnosis, the diagnosis site of the patient. Therefore, the collimator 200 is preferably to include an irradiation field control plate 210 that can limit the range of the radiation flux.

The irradiation field adjusting plate 210 will be described with reference to FIG. 2. 2 is a plan view of the irradiation field control plate 210 of the collimator 200. As shown in FIG. 2, the irradiation field adjusting plate 210 includes adjusting plates 211a and 211b for adjusting the front and rear gaps and adjusting plates 212a and 212b for adjusting the left and right gaps, and as the front and rear gaps and the left and right gaps are adjusted. The area S0 = a0 x b0 of the quadrangular radiation flux outlet 220 formed in the center of the irradiation field control plate 210 is widened or narrowed, and the detector according to the area S0 of the radiation flux outlet 220. The area (F0 = c0 x d0) of the irradiation field formed on the 400 is changed. The distance from the X-ray tube 110 to the detector 400 becomes a source to image distance (SID), which is the distance from the source of radiation to the image. In FIG. 1, the SID will be SID0.

On the other hand, as described above, the radiation flux adjusted by the irradiation field adjusting plate 210 of the collimator 200 passes through the diagnosis site of the patient and generates a diagnostic image on the detector 400, wherein the diagnostic image is generated. The radiation flux is the primary radiation flux x1. However, in the process of limiting the irradiation field of the primary radiation flux x1 by the collimator 200, secondary radiation x2 is generated inside the collimator 200 by scattering of the primary radiation flux x1. In addition, since the secondary radiation (x2) is generated in the radiation generating apparatus 100 for various reasons, the secondary radiation as well as the primary radiation flux (x1) in the radiation exit outlet 220 and its vicinity. (x2) is also emitted, in the case of the secondary radiation (x2), unlike the primary radiation flux (x1) that is concentrated irradiated toward the detector 400, the emission direction is not constant and scattered in all directions Therefore, radiation exposure will be caused to patients or medical personnel around.

Therefore, in the secondary radiation shielding apparatus of the mobile radiography apparatus according to the present invention, the shielding means 300 for shielding scattering of the secondary radiation x2 on the radiation flux outlet 220 side of the collimator 200. ) Will be used in combination, which will be described with reference to FIGS. 3 and 4. Figure 3 shows an embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention, Figure 4 is a shielding tube 310 of one embodiment of the secondary radiation shielding device of the mobile radiograph according to the present invention ), A perspective view for explaining a connection relationship between the connecting plate 320 and the coupling means 230. As shown in FIG. 3, the secondary radiation shielding device of the mobile radiograph according to the present invention includes a mobile radiographer including the radiation generator 100 and a collimator 200 coupled to the radiation generator 100. In the radiography process, the secondary radiation (x2) to shield the scattered out in all directions, to the radiation exit outlet 220 side of the collimator 200, for shielding the secondary radiation (x2) It is preferable to allow the shielding means 300 to be coupled. The shielding means 300 is preferably made of a material such as lead (Pb) that can effectively shield the radiation, which will be described later.

To this end, the secondary radiation shielding device of the mobile radiograph according to the present invention has a frustum shape of a square pyramid, ie, a frustum of quadrangular pyramid that narrows toward the top 315, as shown in FIG. The upper end 315 and the lower end 316 are respectively connected to the shielding cylinder 320 and the four sides of the upper end 315 of the shielding tube 320, the center of the square pyramid-shaped shielding cylinder Vertically perpendicular to 301, the coupling means for detachably coupling the connecting plate 320 and the connecting plate 320 to the collimator 200 extending toward the opposite side of the central axis (301) ( 230). Here, the coupling means 230 is fixed to the edge of the side of the radiation flux outlet 220 of the collimator 200, the cross section in the width direction as the U-shaped, the open side of the U-shaped radiation exit Towards the 220, the U-shaped groove portion is preferably formed in a pair of rails so that the rectangular connecting plate 320 can be slidably inserted, but may also be coupled using a method other than the rail shape. Of course it is possible.

Accordingly, the shielding means 300 formed of the square pyramid shaped shielding tube 320 and the connecting plate 320 can be inserted or withdrawn in a sliding manner with respect to the coupling means 230, the shielding means. 300 is easily detachable at any time to the collimator 200. That is, when the shielding means 300 is not required, or when a cylindrical flux controller for a specific inspection needs to be attached to the collimator 200, the shielding means 300 can be easily separated, and the ward, the intensive care unit Wherever you are concerned about radiation exposure to people around you, you can quickly and easily combine.

In addition, the secondary radiation shielding device of the mobile radiograph according to the present invention is preferably configured such that the shielding means 300 cannot limit the primary radiation flux x1 directed to the detector 400. Therefore, the open area a1 x b1 of the upper end 315 of the shielding tube 320 is the maximum when the radiation flux outlet 220 of the collimator 200 is opened to the maximum, that is, the front field back and forth control panel 210 And it is preferable to be equal to or wider than the open area (S0 = a0 x b0) of the radiation flux outlet 220, as far as possible to the widest side, more preferably the upper end 315 of the shielding tube 320 The length (a1 or b1) of each side of the) is larger than the side of the maximum length (a0 or b0) of each side of the radiation flux outlet 220 when the irradiation field control plate 210 is widest as far as possible back and forth and left and right Good to do. Accordingly, the shielding means cannot limit the primary radiation flux x1 even when the radiation flux outlet 220 of the collimator 200 is opened to the maximum.

In addition, since the lower end 316 or the side surface of the shielding tube 320 should not be in a path limiting the primary radiation flux x1, the lower end 316 of the shielding tube 320 is the primary radiation. It should be large enough to take into account the path of the genus (x1). Therefore, the open area c1 x d1 of the lower end 316 of the shielding tube 320 opens the radiation flux outlet 220 to the maximum and the radiation generating device (the lower end 316 of the shielding tube 320). The distance to 100, more precisely, is equal to the irradiation field area when the distance from the lower end 316 of the shielding tube 320 to the center of the radiation beam formed on the x-ray tube 110 is SID. In this case, the square pyramid of the shielding tube 320 covers all of them without disturbing the path through which the primary radiation flux x1 spreads, whereas the primary radiation flux x1 is included. Unlike the path of the secondary radiation is emitted to the side exit (x2) is mostly absorbed can be blocked.

On the other hand, Figure 5 is a longitudinal cross-sectional view of the shielding means 300 in the secondary radiation shielding device of the mobile radiograph according to the present invention. As shown in FIG. 5, the shielding tube 310 having a square pyramid shape is preferably made of a sandwich structure by coating PVC materials 312 such as Formax on both sides of the panel 311 made of lead (Pb). Here, the thickness of the lead panel 311 is preferably about 0.5mm, which is because it is mobile because the weight must be taken into account, and the shielding efficiency must also be sufficiently considered. When 0.5mm is used, 93.7% of the radiation is shielded. It may be light enough to be used as a mobile device. Meanwhile, as described above, when the PVC material 312 such as Formax is coated on both sides of the lead panel 311, the human body can be prevented from directly contacting lead, and durability is reinforced in place of the thinned lead thickness. It works.

And the connecting plate 300 of the square is attached to the metal plate 322 to the lead plate 321 having a thickness of about 0.5mm to block the radiation coming through the gap of the field adjustment plate 210 of the collimator 200, etc. It is preferable to have a structure, by reinforcing the metal plate 322 to the lead plate 321 is further strengthened the robustness of the connecting plate 300, it is possible to be stably coupled to the coupling means, furthermore the shielding The durability and stability of the entire means 300 can be enhanced. The metal plate 322 may have a thickness of about 2 mm.

6 and 7 show another temporary example of the secondary radiation shielding device of the mobile radiography apparatus according to the present invention. As shown in FIG. 6, the secondary radiation shielding apparatus of the mobile radiograph according to the present invention is preferably a shielding means capable of enhancing a shielding range, and further comprising an extension means 500. This is because it is difficult to effectively block the exposure of the secondary radiation only by the shielding cylinder 310 when the SID is prolonged in the radiographic imaging using the mobile radiograph. In addition, even if the SID is short, a higher level of secondary radiation shielding may be required in a space requiring perfect exposure prevention. As such, when the SID is long or when a higher level of secondary radiation blocking is required, the secondary radiation blocking can be effectively blocked when the extension means 500 that can be connected to the shielding tube 310 is used. Will be.

To this end, the secondary radiation shielding device of the mobile radiograph according to the present invention preferably includes at least one extension means 500 having the same shape as the shielding tube 310 in addition to the above-described features. When the extension means 510 is one or the extension means 510 is the extension means at the top of the extension means 500, the length c2 or d2 of each of the top four sides of the extension means 510 is Longer than the length (a1 or b1) of each of the upper four sides of the shielding cylinder 310, it is preferable to be slightly shorter than the length (c1 or d1) of each of the lower four sides of the shielding cylinder (310). And the extension means 510 is detachably coupled to the shielding tube 310, it is preferable to be coupled in such a way that the upper inner surface of the extension means 510 is fitted to the lower outer surface of the shielding tube 510. Do. To this end, when the open lower end 516 and the upper end 515 of the extension means 510 are covered from the upper end 315 side of the shielding tube 510, each of the four sides of the upper end 515 of the extension means 510. Since the length c2 or d2 is shorter than the length c1 or d1 of each of the four sides of the lower end 316 of the shielding cylinder 310, the inner surface of the upper end 515 of the extension means 510 is shielded from a certain position. It is inserted into the outer surface of the lower end 316 of the barrel 310 and is guided further, and the upper end 515 of the extension means 510 and the lower end 316 of the shielding tube 310 overlap with a predetermined portion (D). Will be produced. Wherein the overlapping portion (D) is preferably a minimum range that can be firmly coupled to the extension means 510 and the shielding tube 310, in order to do this, the upper end 515 of the extension means 510 The length difference between each of the four sides (c2 or d2) and the length (c1 or d1) of each of the four sides of the lower end 316 of the shielding cylinder 310 is about 1mm to 3mm, but the shielding cylinder 310 of the When the size is large, it is also preferable to set it as about 3 mm to 4 mm. This is because as the size of the shielding tube 310 increases, the extension means 510 also increases, and thus, the area of the overlapping portion D must be somewhat widened to improve the tightness of the coupling.

On the other hand, the length (L0) of each of the four sides of the connecting plate 320 is greater than the length (c2 or d2) of each of the four sides of the upper end 515 (in some cases also the lower end) of the extension means 510 There may be a large case, in this case, since the four sides of the connecting plate 320 is caught by the upper end 515 or the lower end 516 of the extension means 510, the extension means 510 to the shielding tube 310 ) Can not be lowered by covering from the top (315) side. Therefore, in this case, as shown in FIG. 8, at least one side of the four sides of the connecting plate 320 is preferable to have a wing folded only downward, for this purpose, one side of the connecting plate 320 ( In some cases, both sides are divided into a fixed blade 323 and a folded blade 324 and a hinge 325 is disposed between the fixed blade 323 and the folded blade 324 so that the folded blade 324 is lowered. Only, that is, it is preferable to be able to rotate only in the direction of the lower end 316 of the shielding cylinder (310). In this case, the length of the two sides of the four sides of the connecting plate 320 is shortened after the folding wing 324 is folded downward. At this time, the length of the short side of the connecting plate 320 is short. It is preferable to make at least shorter than the length (c2 or d2) of any one of the four sides of the upper end 516 of the extension means (510). In doing so, the extension means 510 is obliquely covered from the upper side of the shielding tube 510 so that a short side of the connecting plate 320 can enter the lower end 516 and the upper end 515 of the extension means 510. When lowered, the lower end 516 and the upper end 515 of the extension means 510 can pass down the connecting plate 320. Since the folding wing 324 is folded only downward, after the extension means 510 is engaged, the folding wing 324 is extended to insert the connecting plate 320 into the coupling means 230. The connecting plate 320 and the coupling means 230 can maintain a firm coupling state.

On the other hand, with respect to the case where there are two or more extension means 500 and other extension means higher than itself, referring to Figure 7 again, of the extension means 500, another extension means higher than itself In the case of the lower extension means 520 having the upper extension means 510, the length c4 or d4 of each of the four sides of the upper end 525 of the lower extension means 520 is determined by the upper extension means 510. Longer than the length (c2 or d2) of each of the upper four sides, and preferably shorter than the length (c3 or d3) of each of the four sides of the lower 516 of the upper extension means (510).

The lower extension means 520 is detachably coupled to the upper extension means 510, and an inner surface of the upper end 525 of the lower extension means 520 is an outer surface of the lower end 516 of the upper extension means 510. It is desirable to be coupled in such a way that it fits in. To this end, when the lower extension means 520 is covered by the upper extension means 510 from the upper end 515, the length c4 or d4 of each of the four sides of the upper end 525 of the lower extension means 520 is increased. Since the lower end 516 of the extension means 510 is shorter than the length (c3 or d3) of each of the four sides, the inner surface of the upper end 525 of the lower extension means 520 is lower than the lower end of the upper extension means 510. 516 is inserted into the outer surface and is no longer guided, and an upper portion of the lower extension means 520 and a lower portion of the upper extension means 510 have a portion D overlapping with each other. The overlapping portion (D) is preferably a minimum range that can be firmly coupled to the lower extension means 520 and the upper extension means 510, in order to do this, the upper four of the lower extension means 520 The length difference between each length c4 or d4 and the length c3 or d3 of each of the lower four sides of the upper extension means 510 is appropriately about 1 mm to 3 mm, but is 3 mm when the size of the extension means is large. It is also preferable to set it as about 4 mm. This is because as the size of the extension means increases its weight, the area of the overlapping portion D must be somewhat widened to improve the tightness of the coupling.

Although the present invention has been described with various examples, the present invention is not necessarily limited to these examples, and various modifications can be made without departing from the spirit of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the technical idea of the present invention but to explain the present invention, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100 radiation generator
110 X-ray Tube
200 collimators
210 Irradiation Control Panel 220 Radiation Flux Outlet
300 shielding means
310 shield box 320 connection plate
311 Lead Panel 312 PVC Material
315 Top of shield 316 Bottom of shield 316
321 lead plate 322 metal plate
323 Fixed wing 324 Folding wing
325 hinge
400 detector
500 Extension
510 Extension means 520 Extension means

Claims (6)

In the mobile radiograph including a radiation generator and a collimator coupled to the radiation generator, a device capable of shielding the secondary radiation scattered during the radiographic process,
A shield box having a shape of a frustum of quadrangular pyramid that is narrowed toward an upper end thereof, wherein the upper and lower ends are open;
A rectangular connecting plate connected to the upper four sides of the shielding tube and extending toward the opposite side of the central axis perpendicular to the central axis of the shielding tube; And
Coupling means for detachably coupling the connecting plate to the collimator; Secondary radiation shielding device of a mobile radiography apparatus comprising a The method of claim 1,
The coupling means is fixed to the edge of the radiation flux outlet of the collimator, the cross-section in the width direction of the U-shaped, the open side of the U-shaped toward the radiation flux exit, the connecting portion is sliding in the U-shaped groove portion Secondary radiation shielding device of a mobile radiograph, characterized in that it is a pair of rails so that it can be inserted The method of claim 1,
The upper opening area of the shielding barrel is equal to or larger than the opening area of the radiation flux outlet when the radiation flux exit of the collimator is opened to the maximum.
The lower end opening area of the shielding cylinder is the same as or larger than the irradiation field area when the radiation flux exit is opened to the maximum and the distance from the lower end of the shielding tube to the radiation generating device is SID. Secondary radiation shielding device The method of claim 1,
At least one extension means shaped like the shielding cylinder,
The length of each of the top four sides of each of the extension means is shorter than the length of each of the bottom four sides of the shielding tube or the length of each of the bottom four sides of the upper extension means coupled to its upper side among the extension means.
Each of the extension means is detachably coupled to the shielding barrel or the upper extension means, and the upper inner surface of each of the extension means is coupled to the shielding barrel or the lower outer surface of the upper extension means. Secondary Radiation Shielding Device of Mobile Radiography The method of claim 4, wherein
The upper opening area of the shielding barrel is equal to or larger than the opening area of the radiation flux outlet when the radiation flux exit of the collimator is opened to the maximum.
The lower opening area of each of the extension means is the same as or larger than the irradiation field area when the radiation exit is maximized and the distance from the lower end of each of the extension means to the radiation generating device is SID. Radiation Shield Secondary Device The method according to claim 4 or 5,
At least one side of the connecting plate includes a folding wing,
The folding wing is rotatable only in the lower direction of the shield,
In a state in which the folding wings are folded in the lower direction of the shielding cylinder, the length of the shorter side of the connecting plate is shorter than the length of any one of the four sides of the extension means fitted to the shielding cylinder. Secondary radiation shielding device

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