KR102268678B1 - Movable radiation transmission survey system including radiation shielding facility for cultural properties - Google Patents

Abstract

The present invention relates to a movable radiation shielding system including a radiation emission device, and more specifically, to a movable radiation shielding system including a radiation emission device, through which a radiation shielding facility including a radiation emission device is loaded and unloaded and then transferred to a cultural asset site. The movable radiation emission survey system for a cultural asset including a radiation shielding facility in accordance with an embodiment of the present invention comprises: a vehicle including a loading box in which a cargo is loaded; a radiation shielding box loaded in the loading box, provided with upper, lower, and side surfaces containing lead to shield radiation, and including a radiation emission means which emits radiation toward an object to be subjected to radiation emission therein; and a support means attached or detached from the loading box and disposed between one end portion of the loading box and the ground surface so as to support the radiation shielding box when the radiation shielding box is being loaded and unloaded. The vehicle includes a wire part which transmits power when the radiation shielding box is being loaded and unloaded. The wire part includes a wire connected to a wire fastening means of the radiation shielding box and a wire body capable of winding or unwinding the wire. A plurality of wheel means are provided on a lower end of the radiation shielding box so that the radiation shielding box can be moved by an operation of the wire.

Description

MOVABLE RADIATION TRANSMISSION SURVEY SYSTEM INCLUDING RADIATION SHIELDING FACILITY FOR CULTURAL PROPERTIES

The present invention relates to a radiation shielding system for mobile cultural heritage including a radiation shielding facility, and more particularly, to a radiation shielding system that allows a radiation shielding facility including a radiation shielding device to be loaded onto a vehicle and then moved to a cultural property survey site and alighted It relates to a portable cultural property radiation exposure system including a facility.

The present invention is a portable cultural heritage radiation exposure irradiation system including a radiation shielding facility, and there is no radiation shielding and field mobile equipment, an X-ray source supplement device, a radiation digital developing equipment, and the like.

In addition, the X-ray non-destructive penetration diagnostic investigation of cultural assets is a special and limited scientific investigation in the process of preservation and treatment of relics and the periodic investigation of national cultural properties by national institutions due to the specificity and uniqueness of access to cultural properties, unlike general radiographic investigations. etc.), there are restrictions on the commercial use of this non-destructive survey of cultural properties.

Radiation irradiation is essential for the preservation of cultural properties, as it is used for diagnosing internal structures, cracks and decaying conditions that are difficult to observe with the naked eye, and for research on manufacturing methods. However, because it is difficult to move and use radiation equipment, cultural assets must be transferred to a place where radiation irradiation facilities are located. However, there is a high risk of damage to cultural assets during movement, and the budget required for packaging, vibration-free vehicle transportation, and storage facilities is also high. In particular, there are cases where movement itself is impossible, such as large iron Buddhas, gilt-bronze Buddhas, small sculptures, and murals.

On the other hand, the radiation generating device subject to notification is self-shielding and has a voltage of 170 kV and a surface radiation dose rate of 10 μSv/h or less.

Therefore, it is necessary to establish a portable radiation irradiation system that meets the conditions for use and notification of the Nuclear Safety Act for the use of radiation transfer for cultural assets.

Republic of Korea Patent Publication No. 10-0367413 (announced on January 10, 2003) Republic of Korea Patent Publication No. 10-0975621 (Announced on August 17, 2010) Republic of Korea Patent Publication No. 10-2009-0050375 (published on May 20, 2009)

It is an object of the present invention to solve the above-mentioned problems by loading the radiation irradiation equipment on the vehicle and then moving to the cultural property investigation site, disembarking the radiation irradiation equipment from the vehicle at the cultural heritage research site, and moving it to the cultural heritage collection space for non-destructive investigation of cultural assets. An object of the present invention is to provide a portable cultural property radiation exposure system including a radiation shielding facility that increases site accessibility.

Another object of the present invention is to provide a portable cultural heritage radiation transmission irradiation system including a radiation shielding facility that satisfies the radiation shielding of the general public through the shielding facility.

Another object of the present invention is to obtain a design approval of a portable radiation shielding device, and it is equipped with radiation shielding performance and radiation generating device radiation capacity according to the Nuclear Safety Act, so it is possible to use a radiation shielding facility that can be used by non-radiation specialists. to provide a system.

In order to achieve the above object, a portable cultural heritage radiation irradiation system including a radiation shielding facility according to an embodiment of the present invention is a vehicle having a loading box on which cargo is loaded, and the top, bottom and side surfaces are loaded in the loading box. A radiation shielding box containing lead to enable shielding of this radiation, and a radiation irradiating means for irradiating radiation toward the radiation irradiating object therein, and detachable from the loading box, placed between one end of the loading box and the ground and support means for supporting the radiation shielding box when the radiation shielding box is loaded and unloaded, and the vehicle includes a wire part that transmits power when the radiation shielding box is loaded and unloaded, and the wire part includes a wire fastening means of the radiation shielding box; It includes a wire to be connected and a wire body capable of winding or unwinding the wire, and a lower end of the radiation shield includes a plurality of wheel means to move the radiation shield by the operation of the wire.

The support means is provided with a plurality of support movement grooves to which the wheel means move in close contact with the upper surface to prevent the load concentration during loading and unloading of the radiation shielding box.

The vehicle includes a side fixing part provided with the wire part at the other end of the loading box, and on the upper surface of the other end of the loading box, the radiation shielding box is loaded with the wire wound toward the side fixing part, and then the It includes a loading fixing groove to which the wheel means is fixed.

At the lower end of the radiation shield box, it is possible to maintain the level of the radiation shield box by further comprising a shield box lifting means for moving the radiation shield box upward.

The radiation shielding box includes the radiation irradiating means at the upper end, the radiation height adjusting means for adjusting the radiation irradiation height of the object at the lower end, and the upper or lower end of the radiation irradiating means, the movement of the radiation shielding box and a vibration-absorbing elastic means for absorbing vibration according to the above to maintain durability of the radiation irradiation means, wherein the radiation irradiation height adjustment means includes an image plate holder on which the image plate on which the object is placed is mounted and the image plate plate and image plate lifting means for adjusting the height.

According to the present invention, the portable cultural property radiation exposure irradiation system including the radiation shielding facility, the radiation irradiation equipment is loaded onto the vehicle and then moved to the cultural property investigation site, and the radiation irradiation equipment is dismounted from the vehicle at the cultural property investigation site and moved to the cultural property collection space This has the effect of increasing the accessibility of the site for non-destructive investigations of cultural properties.

According to the present invention, a radiation shielding system for mobile cultural heritage including a radiation shielding facility, there is an effect of providing a radiation shielding system for mobile cultural heritage including a radiation shielding facility that satisfies the radiation shielding of the general public through the shielding facility.

According to the present invention, the portable cultural heritage radiation irradiation system including the radiation shielding facility, the design approval of the portable radiation shielding device can be used even by non-radiation specialists by having the radiation shielding performance and the radiation generating device's irradiation capacity according to the Nuclear Safety Act. It has the effect of providing a portable cultural property radiation transmission irradiation system including a radiation shielding facility.

1 is a view showing a state in which the radiation shielding box and the supporting means according to the present invention are loaded in the loading box of the vehicle.
2 is a view showing a state in which the radiation shielding box according to the present invention is loaded or unloaded from the loading box of the vehicle through the support means.
3 is a plan view showing a support moving groove, a loading moving groove, and a loading fixing groove respectively provided in the loading box and the supporting means according to the present invention.
4 is a plan view showing a state in which the loading of the radiation shielding box is completed in the loading box according to the present invention.
5 is a side view showing a state in which the radiation shielding box is loaded and unloaded on the support means according to the present invention and the wheel means is in close contact with the support moving groove.
6 is a side view showing the radiation shielding box upward by the shielding box lifting means on the support means according to the present invention.
7 is a view showing an embodiment of the shield box lifting means according to the present invention.
8 and 9 are views showing the radiation shielding box and the inside according to the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated in different drawings.

And in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms.

As used herein, the singular also includes the plural, unless the phrase specifically states otherwise. As used herein, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other components in addition to the stated components.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a view showing a state in which the radiation shielding box 100 and the supporting means 300 according to the present invention are mounted on the loading box 410 of the vehicle 400, and FIG. 2 is the radiation shielding box 100 according to the present invention. ) is a view showing a state that the loading or unloading from the loading box 410 of the vehicle 400 through the support means (300).

A portable cultural heritage radiation irradiation system including a radiation shielding facility according to the present invention, with reference to FIGS. 1 and 2 , a vehicle 400 having a loading box 410 on which cargo is loaded, the loading box 410 is mounted on the And the upper surface, the lower surface and the side contain lead to enable shielding of radiation, and the radiation shielding box 100 and the loading box 410 including a radiation irradiating means 150 for irradiating radiation toward the radiation irradiated object therein. It is detachable from and is placed between one end of the loading box 410 and the ground, and includes a support means 300 for supporting the radiation shielding box 100 when the radiation shielding box 100 is loaded and unloaded.

The vehicle 400 according to the present invention includes a loading box 410 in which cargo is loaded. The vehicle 400 may be, for example, a truck, which is a vehicle mainly designed to transport cargo, and includes both a truck with a roof in the loading box 410 and a truck without a roof. The vehicle 400 may, in one embodiment, be a 1-ton truck. The 1-ton truck includes, for example, a 1-ton general cargo vehicle 400 or a 1-ton top car one-body vehicle 400 . In the case of a 1 ton truck, the width of the loading standard is 160 cm, the length is 275-285 cm, and the ground clearance of the loading box 410 is 80 cm. When the vehicle 400 according to the present invention is a 1 ton truck, the radiation shielding box 100 loaded in the loading box 410 of the 1-ton truck is horizontal in the inner space so that it can be loaded in the loading box 410 of the 1-ton truck. , length and height can be manufactured to 120cm, 140cm, 140cm, respectively. However, the present invention is not limited thereto, and it may be a dedicated vehicle 400 in which the radiation shielding box 100 according to the present invention can be loaded.

The radiation shielding box 100 according to the present invention can be loaded and unloaded on the loading box 410 of the vehicle 400 . The radiation shielding box 100 is manufactured including a lead-containing soft plate so that the upper surface, the lower surface, and the side can all shield the radiation. In this case, the soft plate may include 99% or more of lead as an embodiment. The shielding lead weight of the radiation shielding box 100 is, as an example, when the lead soft plate has a thickness of 6 mm, about 500 kg of lead is required, the upper surface is 98 kg, and the side and lower surfaces are 134 kg lead soft plate may be used, but in this It is not limited. The radiation shielding box 100 according to the present invention, the radiation shielding box 100, may include a radiation shielding facility, and may be a shielding facility with a capacity of a report generating device capable of irradiating on-site radiation.

The radiation shielding box 100 according to the present invention includes a radiation irradiating means 150 therein. The radiation irradiation means 150 includes a radiation source for irradiating radiation. The radiation source irradiates radiation toward the image plate 160 . The radiation may be x-ray or r-ray. The radiation source may further include an essential component in irradiating x-rays, that is, for example, a known X-ray tube (not shown) or a known X-ray generator (not shown). The x-ray irradiated by the radiation source may have different energy and transmittance depending on the density and thickness of the radiation irradiated object. When the radiation source irradiates r-ray, co-60 or ir-192 can be used. When a radiation source irradiates r-ray, the r-ray irradiator is convenient for outdoor shooting due to its small size and light weight. The quality of the transmitted image obtained using x-ray is lower than that of the transmitted image obtained by using x-ray because it cannot control the Hereinafter, it is assumed that the radiation irradiated by the radiation source according to the present invention is an x-ray. Meanwhile, as an embodiment, the output of the x-ray may be 150 kv, 3 mA, but is not limited thereto.

The radiation shielding box 100 according to the present invention includes the radiation irradiating means 150 at the upper end, and the radiation source may irradiate the radiation toward the lower end. An image plate 160 to which radiation is irradiated is provided at the lower end of the radiation shielding box 100 .

The image plate 160 according to the present invention is a flexible plate having a certain thickness and may be coated with a flammable phosphor. The flammable phosphor stores energy absorbed in a quasi-energy state when excited by X-rays, electrons, ultraviolet rays, or the like. The flammable phosphor has a characteristic of emitting energy corresponding to the absorbed energy when stimulated by visible light or ultraviolet light. The image plate 160 is photosensitized by x-rays to form a latent image. The latent image formed by being photosensitized on the image plate 160 may be developed so that it can be seen with the naked eye by an image conversion unit (not shown). If there is a foreign material inside the irradiated object, the density of the foreign material is mostly smaller than the density of the irradiated object, so the amount of radiation transmitted through the foreign material is greater than the amount of radiation transmitted through the irradiated object, so the latent image or converted final image may appear black. For the latent image formed by being photosensitized on the image plate 160, a known technique of the CR system may be used. The image conversion unit may further include components necessary for developing a latent image formed by being photosensitive to the image plate 160 , for example. The image conversion unit may further include an optical scanner (not shown), a photomultiplier tube (not shown), an A/D converter (not shown), or an image processor (not shown). The optical scanner may scan the surface of the image plate 160 , the photomultiplier tube may convert the latent image formed on the image plate 160 from an optical signal to an electrical signal, and the A/D converter is connected to the photomultiplier tube. It is possible to convert the electrical signal converted by the digital image signal into a digital image signal. The digital image signal converted from the A/D converter is converted into a final processed image through an image processing process of an image processor, and the final processed image may be transmitted to an image processing device such as a computer to be visually confirmed.

Between the radiation irradiating means 150 and the image plate 160 according to the present invention, more specifically, the radiation irradiating object may be disposed on the image plate 160 . The radiation irradiated object may be a nationally designated cultural property or relic. When the object is irradiated with radiation, the irradiated radiation passes through the object and the image plate 160 is photosensitized to form a latent image on the image plate 160 . Through the latent image formed on the image plate 160, the internal structure or internal defect of the object can be known. The purpose of radiographic inspection is to detect discontinuities or defects present in an object. The method of inspecting cultural assets or relics by radiation according to the present invention may employ a CR system in which images are stored digitally.

The support means 300 according to the present invention is manufactured to be detachable from the loading box 410 of the vehicle 400 . The support means 300 is loaded and moved on the loading box 410 together with the radiation shielding box 100 as shown in FIG. 1 when the radiation shielding box 100 is loaded and the vehicle 400 is moved, and the radiation shielding box 100 is moved. ) is placed between one end of the loading box 410 and the ground as shown in FIG. 2 when loading and unloading, and then supports the radiation shielding box 100 that is loaded and unloaded. The attachment and detachment of the support means 300 may be possible by manpower, or may be made through a separately known pneumatic or hydraulic lifting means.

Meanwhile, in the present specification, the rear end of the vehicle 400 , that is, the direction opposite to the driver's seat is referred to as one end of the loading box 410 , and the direction toward the driver's seat is referred to as the other end of the loading box 410 .

After the radiation shielding box 100 and the supporting means 300 according to the present invention are loaded in the loading box 410 of the vehicle 400, the vehicle 400 can move and move together to the site of the cultural heritage collection. When the radiation shielding box 100 and the supporting means 300 arrive at the site of the cultural heritage collection, the supporting means 300 is placed between one end of the vehicle 400 and the ground, and when the radiation shielding box 100 is disembarked, the It plays a role, and this is the same even when the radiation shielding box 100 is loaded onto the loading box 410 of the vehicle 400 .

The vehicle 400 according to the present invention includes wire parts 210 and 211 including an electric wire 211 . The vehicle 400 includes a side fixing unit 200 provided between the vehicle 400 and the loading box 410 . The side fixing unit 200 may be formed upwardly between the driver's seat and the loading box 410 , that is, at the other end of the loading box 410 . At the upper end of the side fixing part 200, wire parts 210 and 211 are installed as an embodiment.

The wire parts 210 and 211 according to the present invention transmit power during loading and unloading of the radiation shielding box 100 . The wire parts 210 and 211 include a wire 211 connected to the radiation shield 100 and a wire body 210 on which the wire 211 is wound. The wire body 210 may wind or unwind the wire 211 by electric power. One end of the wire 211 is connected to the wire fastening means of the radiation shielding box 100 . For example, one end of the wire 211 is formed with a hook, and the hook may be caught on a ring included in the wire fastening means. The other end of the wire 211 is wound around the wire body 210 . The wire parts 210 and 211 serve to pull the radiation shielding box 100 on the support means 300 when the radiation shielding box 100 is loaded, and radiation shielding when the radiation shielding box 100 is unloaded. (100) to relieve the load. Since the radiation shielding box 100 has a large weight by using lead or the like for radiation shielding, the wire parts 210 and 211 transmit tension to the radiation shielding box 100 when loading and unloading the vehicle 400 to improve handling stability. guarantee

The wire fastening means 101 and 103 according to the present invention includes the first wire fastening means 101 provided on the upper surface of the radiation shielding box 100 and the second wire fastening means 101 provided on the side of the radiation shielding box 100 . means 103 . One end of the wire 211 may be coupled to the first wire fastening means 101 , or may be coupled to the second wire fastening means 103 . When the radiation shielding box 100 is loaded or unloaded on the support means 300 , one end of the wire 211 is, as shown in FIG. 2 , a second wire fastening means 103 provided on the side of the radiation shielding box 100 . It is preferable to reduce the load of the radiation shielding box 100 when it is combined with and dragging the radiation shielding box 100 onto the loading box 410 when loading, or when getting off. However, when loading onto the loading box 410 of the radiation shielding box 100 is completed, one end of the wire 211 is coupled to the first wire fastening means 101 as shown in FIG. It would be preferable to adhere to the In the radiation shielding box 100 in close contact with the side fixing part 200 , the second wire fastening means 103 may be in close contact with the contact groove 203 provided in the side fixing part 200 . The size of the contact groove 203 is determined so that the second wire fastening means 103 can be inserted and adhered thereto. The vibration of the radiation shielding box 100 can be prevented when the vehicle 400 is moved by the second wire fastening means 103 in close contact with the contact groove 203 .

The radiation shielding box 100 according to the present invention includes a plurality of wheel means 120 at the lower end. Accordingly, the radiation shielding box 100 may be more easily moved by the wheel means 120 when the radiation shielding box 100 is loaded and unloaded from the loading box 410 by the operation of the wire parts 210 and 211 . A plurality of wheel means 120 may be provided to form a pair in front and back of both sides of the radiation shield (100). The wheel means 120 follows a known wheel and a coupling structure of the wheel.

3 is a plan view showing the support moving groove 310, the loading moving groove 110 and the loading fixing groove 123 respectively provided in the loading box 410 and the supporting means 300 according to the present invention, FIG. 4 is this It is a plan view showing a state in which loading of the radiation shielding box 100 to the loading box 410 according to the invention is completed.

Referring to FIG. 3 , on the upper surface of the support means 300 according to the present invention, a support movement groove 310 to which the wheel means 120 of the radiation shielding box 100 is closely attached is provided. The support moving groove 310 may be in the form of a streamlined groove having a predetermined angle downward so as to prevent a load concentration during loading and unloading in the loading box 410 of the radiation shielding box 100 . The support moving groove 310 is formed to fit the distance between the wheel means 120 .

The wheel means 120 according to the present invention, again referring to FIG. 2 , moves on the support means 300 and moves in close contact with the plurality of support movement grooves 310 when getting up and down from the loading box 410 . Therefore, when the radiation shielding box 100 moves on the support means 300, it prevents the load from being concentrated according to the weight.

Referring back to FIG. 3 , on the upper surface of the loading box 410 according to the present invention, a loading moving groove 110 having the same shape as the supporting moving groove 310 may be formed. Therefore, even when the wire body 210 winds the wire 211 and the radiation shielding box 100 moves toward the side fixing part 200 and is loaded, the wheel means 120 is also on the loading box 410, the loading moving groove 110. It can be moved by being in close contact with it. However, the loading moving groove 110 may be optionally provided.

At the other end of the upper surface of the loading box 410 according to the present invention, referring to FIGS. 3 and 4 , when the radiation shielding box 100 moves in close contact with the side fixing unit 200 , the wheel means 120 is caught and fixed. A loading fixing groove 123 that can be formed is formed. As the wheel means 120 is caught in the loading fixing groove 123 , the radiation shielding box 100 , where the loading is completed, can be maintained in a fixed state even when the vehicle 400 moves. The loading fixing groove 123 may have a shape in which a predetermined depth groove is dug inward at a point where the wheel means 120 of the radiation shielding box 100 where the loading of the loading box 410 is completed is located. In the radiation shielding box 100 that has been loaded, the wheel means 120 is caught by the loading fixing groove 123 and fixed, and at the same time, the second wire fastening means 103 is in close contact with the contact groove 203 to be more firmly fixed. . As shown in FIG. 3, the loading fixing groove 123 may have a 'c' shape when viewed from the top, and the boundary toward the inside of the 'c' shape is such that the wheel means 120 can move easily. It may be formed to have a gentle slope. In FIG. 3 , the boundary facing the outside of the letter 'C' is shown with a solid line, whereas the boundary facing the inside of the letter 'C' is not shown with a solid line.

Meanwhile, the loading fixing groove 123 may further include an elastic means (not shown) for minimizing vibration and movement toward the radiation shielding box 100 when the vehicle 400 moves.

5 is a side view showing a state in which the radiation shielding box 100 is lowered and lowered on the support means 300 according to the present invention, and the wheel means 120 is in close contact with the support movement groove 310 .

Referring to FIG. 5 , the wheel means 120 of the radiation shielding box 100 according to the present invention moves in close contact with the support moving groove 310 . The wheel means 120 may be provided with a pair of left and right, and may further include a wheel shaft 121 connecting the central shaft of each wheel means 120 .

6 is a side view showing the radiation shielding box 100 is raised by the shielding box lifting means 130 on the supporting means 300 according to the present invention, and FIG. 7 is a shielding box lifting means 130 according to the present invention. ) is a diagram showing an embodiment of

At the lower end of the radiation shielding box 100 according to the present invention, referring to FIG. 6 , a plurality of shielding box lifting means 130 for moving the radiation shielding box 100 upward may be further included. The shielding box lifting means 130 is capable of moving the radiation shielding box 100 upward so as to maintain the level of the radiation shielding box 100 . The lower surface of the shielding box lifting means 130 may be in contact with the support means 300 , and thus it is possible for the radiation shield box 100 to rise on the support means 300 . Therefore, there is an effect of maintaining the level of the radiation shielding box 100 on the support means 300 even on an irregular road surface at the site of the cultural property collection.

Shield box lifting means 130 according to the present invention, referring to Figure 7, may be a pneumatic or hydraulic type lift. The shield box lifting means 130 may further include a pneumatic or hydraulic device 131 and a control rod 133 for controlling the pneumatic or hydraulic device. The lower surface of the shielding box lifting means 130 is in contact with the ground or the supporting means 300 , and the upper surface of the shielding box lifting means 130 is in contact with the lower surface of the radiation shielding box 100 .

8 and 9 are views showing the inside of the radiation shielding box 100 according to the present invention.

Referring to FIG. 8 , the radiation shielding box 100 according to the present invention is provided with a radiation irradiating means 150 at the upper end thereof. The radiation irradiation means 150 is the same as described above. The radiation irradiating means 150 includes a radiation source, and the radiation source irradiates radiation toward the bottom. The radiation shielding box 100 may further include an object access door 170 through which cultural assets or relics enter and exit. An image plate 160 on which an object is disposed is provided at the lower end of the radiation irradiating means 150 . On the other hand, the image plate 160 needs to be adjusted in height in order to secure X-ray penetrating power for various types or types of cultural assets or relics.

The image plate 160 according to the present invention, with reference to FIG. 9, is provided on the irradiation height adjusting means. The irradiation height adjusting means (161, 163) can adjust the irradiation height of the object.

The irradiation height adjusting means 161 and 163 according to the present invention includes an image plate holder 161 and an image plate lifting means 163 . An image plate 160 on which an object is placed is mounted on the image plate holder 161 . The image plate lifting means 163 adjusts the height of the image plate holder 161 . The image plate lifting means 163 may be raised or lowered by a pneumatic or hydraulic device in the same way as the shield lifting means 130 . The image plate lifting means 163 may be provided with a separate control panel for controlling the rise or fall of the radiation shielding box 100 inside and outside. Alternatively, a control rod may be provided similarly to the shield box lifting means 130 . The lower end of the image plate lifting means 163 is in contact with the lower end of the radiation shielding box 100 , and the upper end of the image plate lifting means 163 is in contact with the bottom surface of the image plate holder 161 . A plurality of image plate lifting means 163 may be provided, and a plurality of image plate lifting means 163 may be set to operate simultaneously or individually for the horizontality of the image plate 160 . .

The upper or lower end of the radiation irradiating means 150 according to the present invention further includes a vibration absorbing elastic means 151 for absorbing vibrations caused by the movement of the radiation shielding box 100 . A plurality of vibration-absorbing elastic means 151 may be provided, and the center is provided with elastic means such as rubber and springs, and the upper and lower surfaces are in contact with each wall of the radiation irradiating means 150 and the radiation shielding box 100, respectively. provided to do The vibration-absorbing elastic means 151 absorbs vibrations caused by movement on an uneven road surface at the cultural heritage site to maintain durability of the radiation irradiating means 150 .

The lower end of the radiation irradiating means 150 according to the present invention may further include a radiation irradiating window 153 .

In the vicinity of the radiation irradiating means 150 according to the present invention, it may further include an output control device 190 for controlling the output of radiation, and a radiation control device 180 for controlling the radiation.

In this specification, a "part" includes a unit realized by hardware, a unit realized by software, and a unit realized using both. In addition, one unit may be implemented using two or more hardware, and two or more units may be implemented by one hardware.

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the protection scope of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention pertains.

100: radiation shielding box 101: first wire fastening means
103: second wire fastening means 110: loading moving groove
120: wheel means 121: wheel axle
123: loading fixing groove 130: shield box lifting means
131: pneumatic or hydraulic device 133: control rod
150: radiation irradiation means 151: vibration-absorbing elastic means
153: irradiation window 160: image plate
161: image plate holder 163: image plate lifting means
170: object access door 180: radiation control device
190: output control device 200: side fixing part
203: contact groove 210: wire body
211: wire 300: support means
310: support moving groove 400: vehicle
410: loading box

Claims (5)

a vehicle having a loading box on which cargo is loaded;
a radiation shielding box that is loaded in the loading box and includes a radiation irradiating means for irradiating radiation toward a radiation irradiated object therein, including lead so that the upper surface, lower surface and side surfaces can shield radiation; and
a support means detachable from the loading box and placed between one end of the loading box and the ground to support the radiation shielding box during loading and unloading of the radiation shielding box;
includes,
The vehicle includes a wire unit that transmits power when loading and unloading the radiation shielding box,
The wire unit includes a wire connected to the wire fastening means of the radiation shielding box and a wire body capable of winding or unwinding the wire,
A portable cultural heritage radiation exposure irradiation system including a radiation shielding facility, characterized in that the lower end of the radiation shield includes a plurality of wheel means so that the radiation shield can be moved by the operation of the wire. The method according to claim 1,
The support means,
A portable cultural heritage radiation transmission irradiation system including a radiation shielding facility, characterized in that it has a plurality of support moving grooves in which the wheel means are moved in close contact with the upper surface to prevent load concentration when the radiation shielding box is unloaded. 3. The method according to claim 2,
The vehicle is
and a side fixing part provided with the wire part at the other end of the loading box,
On the upper surface of the other end of the loading box,
The radiation shielding box comprises a loading fixing groove to which the wheel means is fixed after the wire is wound and loaded toward the side fixing part. 4. The method according to claim 3,
At the lower end of the radiation shield,
A portable cultural heritage radiation exposure irradiation system including a radiation shielding facility, characterized in that it is possible to maintain the level of the radiation shielding box by further comprising a shield box lifting means for moving the radiation shield box upward. 5. The method according to claim 4,
The radiation shield is
The radiation irradiating means is included in the upper end,
The lower end includes an irradiation height adjusting means for adjusting the irradiation height of the object,
At the top or bottom of the radiation irradiation means,
and vibration-absorbing elastic means for absorbing vibrations caused by the movement of the radiation shielding box to maintain durability of the radiation irradiating means,
The radiation irradiation height adjustment means,
an image plate holder on which the image plate on which the object is placed is mounted; and an image plate lifting means for adjusting the height of the image plate plate, a portable cultural heritage radiation exposure system including a radiation shielding facility.

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