JP2004077235A - Active energy ray irradiation device and radiation shielding structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an active energy ray irradiation device and a radiation shielding structure capable of shielding radiation without enlarging the device or generating difficulty in maintenance. <P>SOLUTION: The radiation shielding structure 7 includes a conveying roll 21 for conveying an irradiated object 6, a roll cover 22 for covering the peripheral surface of the conveying roll 21, and a bearing unit 23 for rotatably supporting the conveying roll 21 and covering an end surface of the conveying roll 21. The end surface of the conveying roll 21, the roll cover 22, and the bearing unit 23 are assembled so as to provide a labyrinth structure where radiation generated from an electron beam irradiation section is not emitted outside without at least two times scattering. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention has an active energy ray irradiating unit in a housing, loads an object to be irradiated from a carry-in port provided in the housing, irradiates the active energy ray irradiating unit with an active energy ray to the object to be irradiated, and The present invention relates to an active energy ray irradiating apparatus which performs a series of processes for carrying out an object to be irradiated from a carry-out port provided on a body while continuously carrying the object to be irradiated, and a radiation shielding structure used therein.
[0002]
[Prior art]
In recent years, paints, printing inks, adhesives, etc., which are cured by irradiation with active energy rays such as electron beams and ultraviolet rays, have a higher processing speed than conventional thermosetting drying type paints, printing inks, adhesives, etc. It has come into practical use because it has advantages such as no pollution by using no solvent and downsizing of the active energy ray irradiation device.
[0003]
Among these, electron beams have attracted attention because they do not generate heat during irradiation, so they have a low risk of deteriorating the base material, and have advantages such as being able to cure in a short time because of high transparency. ing.
[0004]
Among the electron beam irradiation devices, a continuous paper-sheet type electron beam irradiation device that irradiates a continuous sheet (web) or a sheet-like sheet with an electron beam has a loading port and a loading port for loading and unloading the web. Although it is necessary, since the electron beam irradiation device generates radiation such as X-rays, a mechanism that shields radiation from such loading / unloading ports that may leak radiation such as X-rays is provided. It is indispensable to attenuate leaking radiation such as X-rays below a reference value. When the object to be irradiated is a sheet-like sheet, a conveyor or the like is generally provided as a transport mechanism.
[0005]
[Problems to be solved by the invention]
In order to attenuate the leakage of radiation such as X-rays below the reference value, it is common to bend the transport path from the ionizing radiation source to the loading / unloading port using a plurality of transport rolls and make the transport path itself a maze structure. Has been done.
[0006]
However, such a radiation shielding mechanism has a complicated structure, so that the transport mechanism is likely to be large, and as a result, there are problems that the entire irradiation apparatus becomes large, maintenance and paper passing are not easy.
[0007]
The present invention has been made in view of such circumstances, and provides an active energy ray irradiation device and a radiation shielding structure capable of shielding radiation such as X-rays without increasing the size of the device and making maintenance difficult. The purpose is to do.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides a housing having an entrance and an exit for an irradiation object, an active energy ray irradiation unit provided in the housing, and a sheet-shaped irradiation object. A transport mechanism that carries in the object to be irradiated from the carry-in entrance of the casing to the active energy ray irradiation unit and carries out the carry-out from the carry-out exit, and a radiation shielding structure provided in the carry-in entrance and / or the carry-out exit An active energy ray irradiation apparatus comprising: a radiation shielding structure, one or more transport rolls for transporting an irradiation target, a roll cover covering a peripheral surface of the transport roll, and the transport roll. And a bearing unit that rotatably supports the end face of the transport roll, wherein the end face of the transport roll, the roll cover, and the bearing unit are generated from the active energy ray irradiation unit. Radiation provides an active energy ray irradiation apparatus characterized by being assembled so as to have a labyrinth structure which is not emitted to the outside to be reflected at least twice.
[0009]
Further, the present invention is a radiation shielding structure provided at a carry-in and / or carry-out port of an irradiation target in an active energy ray irradiation device, wherein one or a plurality of conveyance rolls for conveying the irradiation target, and A roll cover that covers the peripheral surface of the transport roll, and a bearing unit that rotatably supports the transport roll and covers an end surface of the transport roll, wherein the end surface of the transport roll, the roll cover, and the bearing unit A radiation shielding structure which is assembled so as to have a maze structure in which radiation generated from the active energy ray irradiation unit is not emitted to the outside unless reflected at least twice.
[0010]
According to the present invention, the end face of the transport roll, the roll cover, and the bearing unit have a maze structure in which radiation such as X-rays generated from the active energy ray irradiation unit is not emitted to the outside unless reflected at least twice. As assembled, as a radiation shielding structure provided at the entrance and / or exit of the irradiation target in the active energy ray irradiation device, one or a plurality of transport rolls, and a roll cover covering the peripheral surface of the transport roll With a compact structure having only a bearing unit that covers the end face of the transport roll, radiation such as X-rays can be shielded without increasing the size of the apparatus and making maintenance difficult.
[0011]
In this case, a concave portion (a plurality of concave portions may be provided; other concave portions are also the same) around the axis of the end face of the transport roll, and the bearing unit has a portion corresponding to the concave portion, and The configuration may be such that the transport roll and the bearing unit are assembled such that a portion corresponding to the concave portion is fitted. Further, the bearing unit has a concave portion along an end surface of the transport roll, and the transport roll and the bearing unit are assembled so that the end surface of the transport roll and the concave portion are fitted. You can also. Further, the bearing unit may have a structure having a concave portion into which the roll cover is fitted. Furthermore, the roll cover and the bearing unit may have a structure that can be vertically divided.
[0012]
Further, in the above active energy ray irradiation apparatus, it is preferable that the active energy ray irradiation section has a vacuum tube type electron beam generation section that irradiates an electron beam with an acceleration voltage of 30 to 80 kV.
[0013]
In the present invention, the term “reflection” includes all aspects in which radiation that travels straight hits an object and changes its course.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be specifically described.
FIG. 1 is a perspective view showing an electron beam irradiation apparatus according to an embodiment of the present invention, and FIG. 2 is a vertical sectional view thereof. In this electron beam irradiation apparatus, an electron beam irradiation unit 2 is disposed in a housing 1, and a lid 3 for shielding the electron beam irradiation unit 2 is provided to be freely opened and closed. The lid 3 is covered with a cover 1a. The cover 1a can be opened and closed together with the lid 3. The cover 1a is provided with a carry-in port 4 for a web 6, which is an object to be irradiated. The lid 3 is provided with an irradiation unit entrance 4 ′ for carrying the web 6 into the electron beam irradiation unit 2. Further, below the electron beam irradiation unit 2, an irradiation unit outlet 5 'for carrying out the web 6 from the electron beam irradiation unit 2 is provided. Then, the web 6 carried in from the carry-in port 4 passes through the irradiation section carry-in port 4 ′ and the irradiation section carry-out port 5 ′, and is carried out from the carry-out port 5 provided below the housing 1. . The web 6 is loaded from the loading port 4 by a transport mechanism 10 including two rolls 8 around which the web 6 is wound inside the housing 1 and a motor (not shown) for winding the web 6 outside the housing 1. Then, it is guided to the electron beam irradiation unit 2 and further carried out from the carry-out port 5. The cover 3 is provided with a holding roll 9 for holding the web 6 wound around one of the rolls 8.
[0015]
A radiation shielding structure 7 is provided at the irradiation section entrance 4 ′ of the lid 3. The radiation shielding structure 7 shields radiation such as X-rays generated from the electron beam irradiation unit 2 so that X-rays and the like leaking from the irradiation unit entrance 4 ′ to the outside become equal to or less than a reference value. As will be described later, it has a maze structure in which the radiation generated from the electron beam irradiation unit 2 is not emitted to the outside unless reflected at least twice.
[0016]
The electron beam irradiation unit 2 has an electron beam irradiation unit 11. The electron beam irradiation unit 11 has a plurality of vacuum tube type irradiation tubes 50 as shown in FIG. The irradiation tube 50 is a cylindrical vacuum tube (tube) 51 made of glass or ceramic, and is provided in the vacuum tube (tube) 51. Electrons emitted from the cathode are extracted as electron beams and accelerated. It has a line generating section 52, an electron beam emitting section 53 provided at an end of the vacuum tube 51 for emitting an electron beam, and a pin section 54 for supplying power from a power supply section (not shown). The electron beam emitting section 53 is provided with a thin-film irradiation window 55. The irradiation window 55 of the electron beam emitting unit 53 has a function of transmitting an electron beam without transmitting a gas, and has a slit shape as shown in FIG. Then, an electron beam emitted from the irradiation window 55 is irradiated on the irradiation object arranged in the irradiation chamber.
[0017]
Such a vacuum tube type electron beam generating unit is fundamentally different from a conventional drum type electron beam generating unit which irradiates an electron beam while constantly evacuating the inside of a drum. An apparatus having an irradiation tube having such a configuration is disclosed in U.S. Pat. No. 5,414,267. Such an electron beam generator can effectively extract an electron beam even at a low accelerating voltage, and thus has a small adverse effect on an irradiation target. Further, there is an advantage that the amount of radiation such as X-rays is small because the energy of the electron beam is small. As described above, since the amount of radiation such as X-rays is small and the accelerating voltage is low, the size of the electron beam generator can be reduced, and the size of the electron beam irradiation device can be dramatically reduced. Here, the acceleration voltage of the electron beam is preferably 150 kV or less, more preferably 10 to 130 kV. More preferably, it is 30 to 80 kV.
[0018]
Next, the radiation shielding structure 7 will be described. 4A is a horizontal sectional view of the radiation shielding structure 7, and FIG. 4B is a vertical sectional view thereof. FIG. 5 is an exploded perspective view of the X-ray shielding structure 7. The radiation shielding structure 7 rotatably supports one transport roll 21 for web transport disposed at the entrance 4, a roll cover 22 that covers the peripheral surface of the transport roll 21, and a shaft 21 a of the transport roll 21. And a bearing unit 23 that covers the end surface of the transport roll 21.
[0019]
The roll cover 22 can be vertically divided into an upper cover 22a and a lower cover 22b. A web introduction port 22c is provided in the upper cover 22a, and a web passage port 22d is provided in a lower end of the lower cover 22b. A concave portion 21b is formed around the shaft 21a on the end face of the transport roll 21. The bearing unit 23 has a main body 24 and a fitting part 25, which are separable. The main body 24 can be divided into an upper half 24a and a lower half 24b. A concave portion 24c for fitting the roll cover 22 is formed in the main body 24. The fitting portion 25 corresponds to the concave portion 21b of the transport roll 21, and the transport roll 21 and the bearing unit 23 are assembled so that the fitting portion 25 fits into the concave portion 21b. Thereby, the fitting surface between the end face portion of the transport roll 21 and the bearing unit 23 is in a state of being bent in an uneven shape. The fitting portion 25 has an insertion hole 25a into which the shaft 21a is inserted.
[0020]
Next, the operation of the thus configured electron beam irradiation apparatus will be described.
First, the lid 3 and the cover 1a are closed, and in this state, the web 6 is passed through the inside of the housing 1 so that the web 6 can be irradiated with an electron beam. Next, the electron beam is irradiated from the electron beam irradiation unit 11 of the electron beam irradiation unit 2, and the web 6 is continuously carried in from the entrance 4 by the transport mechanism 10 and guided to the electron beam irradiation unit 2. Unload from exit 5.
[0021]
At this time, the irradiation unit entrance 4 'is provided near the electron beam irradiation unit 2, so that radiation such as X-rays generated by the irradiation of the electron beam is hardly attenuated to the irradiation unit entrance 4'. It is radiated toward. This radiation enters between the transport roll 21 and the roll cover 22 from the web passage opening 22d of the radiation shielding structure 7. In this case, a portion where radiation such as X-rays may leak to the outside is located between the web inlet 22c and the bearing unit 23 and the roll cover 22, but radiation such as X-rays is transmitted to the web inlet 22c. Does not reach unless multiple reflection (reflection twice or more) occurs in the roll cover 22, and between the bearing unit 23 and the roll cover 22, there is an uneven surface between the end face portion of the transport roll 21 and the bearing unit 23. It will not reach unless it is reflected more than once through the maze between the bent mating surfaces. The radiation such as X-rays generated by the electron beam irradiator 2 can be attenuated below the reference value by reflecting it twice or more times. It becomes possible to attenuate to.
[0022]
Thus, the end face of the transport roll 21, the roll cover 22, and the bearing unit 23 are assembled so as to have a maze structure in which the X-rays generated from the active energy ray irradiation unit are not emitted to the outside unless refracted at least twice. Since the radiation shielding structure 7 is configured, the radiation shielding structure 7 has a compact structure including only one transport roll 21, a roll cover 22 that covers the peripheral surface of the transport roll 21, and a bearing unit 23 that covers an end surface of the transport roll 21. Radiation such as X-rays can be shielded without increasing the size of the apparatus and making maintenance difficult.
[0023]
In addition, since the roll cover 22 and the main body 24 of the bearing unit 23 have a vertically divided structure and the fitting portion 25 of the bearing unit 23 can be separated, the radiation shielding structure 7 can be easily assembled and disassembled.
[0024]
Next, another embodiment of the radiation shielding structure will be described.
FIG. 6 is a horizontal sectional view of a radiation shielding structure 7 'of another embodiment, and FIG. 7 is an exploded perspective view of the radiation shielding structure 7'. In this example, the end face of the transport roll 21 'does not have a concave portion, and the bearing unit 23' is not separated into a main body portion and a fitting portion. The bearing unit 23 'has a recess 23'd formed along the end face of the transport roll 21', that is, fitted near the end face of the transport roll 21 ', and the end face of the transport roll 21' and the recess 23'd are formed. It is designed to fit. As a result, the fitting surface between the end face portion of the transport roll 21 'and the bearing unit 23' is in an unevenly bent state. Other configurations are the same as those of the radiation shielding structure 7. The bearing unit 23 'has an insertion hole 23'e into which the shaft 21'a is inserted. The bearing unit 23 'has a recess 23'c for fitting the roll cover 22 therein.
[0025]
Even in such a radiation shielding structure 7 ', the radiation does not reach the web inlet 22c unless it is multiple-reflected (reflected twice or more) in the roll cover 22, and the bearing unit 23' and the roll cover 22 are not connected to each other. Between the end portion of the transport roll 21 'and the concavo-convex curved fitting surface between the bearing unit 23 and the bearing unit 23. , Radiation can be attenuated below the reference value, and the above effect can be obtained.
[0026]
Note that the present invention can be variously modified without being limited to the above embodiment. For example, in the above-described embodiment, the example in which the radiation shielding structure 7 is provided at the irradiation unit carrying-in port 4 ′ is shown. However, the radiation shielding structure 7 may be provided at the carrying-in port 4, the irradiation unit carrying-out port 5 ′, and the carrying-out port 5. The radiation shielding structure 7 can be provided at any one or more of the carry-in entrance 4 ′, the carry-in entrance 4, the irradiation unit carry-out exit 5 ′, and the carry-out exit 5. That is, in the above embodiment, both the carry-in port 4 and the irradiation section carry-in port 4 'correspond to the "transport" in the present invention, and both the carry-out port 5 and the irradiation section carry-out port 5' in the present invention. Corresponds to. However, it is sufficient that the radiation shielding structure 7 is provided at a portion of the irradiation section carry-in port 4 ′, the carry-in port 4, the irradiation section carry-out port 5 ′, and the carry-out port 5 where there is a risk of radiation exceeding the standard. Further, in the above embodiment, the case where the number of the transport rolls of the radiation shielding structure is one is described, but a plurality of transport rolls may be provided. When a plurality of transport rolls are provided, they can be arranged side by side, a bearing unit can be provided for each transport roll, and a roll cover that covers the plurality of transport rolls can be provided. However, one transport roll is preferable as in the above embodiment. Further, the concavo-convex structure between the transport roll and the bearing unit of the radiation shielding structure is not limited to the above embodiment. Furthermore, in the above embodiment, the case where the present invention is applied to the electron beam irradiation apparatus is described. However, the present invention can be applied to other active energy ray irradiation apparatuses, such as a γ-ray irradiation apparatus, where radiation leakage is a concern. Needless to say.
[0027]
【The invention's effect】
As described above, according to the present invention, the end face of the transport roll, the roll cover, and the bearing unit have a maze structure in which the radiation generated from the active energy ray irradiation unit is not emitted to the outside unless reflected at least twice. Since the radiation shielding structure is configured by assembling as described above, a compact unit having only one or a plurality of transport rolls, a roll cover covering the peripheral surface of the transport roll, and a bearing unit covering the end surface of the transport roll is provided. With the structure, radiation can be shielded without increasing the size of the apparatus and making maintenance difficult.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an electron beam irradiation apparatus according to one embodiment of the present invention.
FIG. 2 is a vertical sectional view showing an electron beam irradiation apparatus according to one embodiment of the present invention.
FIG. 3 is a diagram showing a structure of an irradiation tube of the electron beam irradiation unit.
FIG. 4 is a horizontal sectional view and a vertical sectional view showing a radiation shielding structure used in the electron beam irradiation apparatus according to one embodiment of the present invention.
FIG. 5 is an exploded perspective view showing a radiation shielding structure used in the electron beam irradiation apparatus according to one embodiment of the present invention.
FIG. 6 is a horizontal sectional view showing another example of the radiation shielding structure.
FIG. 7 is an exploded perspective view showing another example of the radiation shielding structure.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Casing 2 ... Electron beam irradiation part 3 ... Lid 4 ... Carry-in 5 ... Carry-out 6 ... Web (irradiated object)
7 radiation shielding structure 10 transport mechanism 11 electron beam irradiation units 21 and 21 'transport roll 21b recess 22 roll cover 22c web inlet 22d web passage ports 23 and 23 '... Bearing unit 23'd ... Recess

Claims (11)

A housing having an entrance and an exit for the irradiation target;
An active energy ray irradiator provided in the housing;
A transport mechanism for continuously transporting the sheet-shaped object to be irradiated from the carry-in entrance of the housing, carrying the object to be irradiated to the active energy ray irradiation unit, and further carrying out the object from the carry-out opening,
An active energy ray irradiation device comprising: a radiation shielding structure provided at the entrance and / or the exit.
The radiation shielding structure, one or a plurality of transport rolls for transporting the irradiation object, a roll cover that covers the peripheral surface of the transport roll, and rotatably supports the transport roll, the end face of the transport roll An end surface of the transport roll, the roll cover, and the bearing unit have a maze structure in which radiation generated from the active energy ray irradiation unit is not emitted to the outside unless reflected at least twice. An active energy ray irradiation device characterized by being assembled as follows. The conveying roll has a concave portion around the end surface of the shaft, the bearing unit has a portion corresponding to the concave portion, the conveying roll and the said so that the concave portion and the portion corresponding to the concave portion fit. The active energy ray irradiation device according to claim 1, wherein the bearing unit and the bearing unit are assembled. The bearing unit has a concave portion along the end surface of the transport roll, and the transport roll and the bearing unit are assembled so that the end surface of the transport roll and the concave portion are fitted. The active energy ray irradiation device according to claim 1. 4. The active energy ray irradiation device according to claim 2, wherein the bearing unit has a recess into which the roll cover is fitted. 5. The active energy ray irradiation device according to any one of claims 1 to 4, wherein the roll cover and the bearing unit have a structure that can be vertically divided. The activity according to any one of claims 1 to 5, wherein the active energy beam irradiator has a vacuum tube type electron beam generator that irradiates an electron beam with an acceleration voltage of 30 to 80 kV. Energy beam irradiation device. A radiation shielding structure provided at a carry-in and / or carry-out port of an irradiation target in an active energy ray irradiation device, wherein one or a plurality of transfer rolls for transferring the irradiation target and a peripheral surface of the transfer roll are provided. A cover unit that covers the end surface of the transfer roll, and a bearing unit that rotatably supports the transfer roll and that covers the end surface of the transfer roll, wherein the end surface of the transfer roll, the roll cover, and the bearing unit emit the active energy ray. A radiation shielding structure, which is assembled so as to have a maze structure in which radiation generated from a part is not emitted to the outside unless reflected at least twice. The conveying roll has a concave portion around the end face of the shaft, the bearing unit has a portion corresponding to the concave portion, the conveying roll and the said so that the concave portion and the portion corresponding to the concave portion fit. The radiation shielding structure according to claim 7, wherein the bearing unit and the bearing unit are assembled. The bearing unit has a recess corresponding to the axis of the end face of the transport roll, and the transport roll and the bearing unit are assembled so that the axis of the end face of the transport roll and the recess fit together. The radiation shielding structure according to claim 7, wherein: 10. The radiation shielding structure according to claim 8, wherein the bearing unit has a concave portion into which the roll cover is fitted. The radiation shielding structure according to any one of claims 7 to 10, wherein the roll cover and the bearing unit have a structure that can be vertically divided.

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