JP2016040078A - Production device of bag for cryopreservation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a production device of a bag for cryopreservation, in which, in producing of a bag for cryopreservation formed of a fluorine-based resin to which heating processing is not easily performed, a deposition work of two resin sheets overlapped on each other can be automatically and properly performed, the bag for cryopreservation can be produced in mass production and cost reduction is achieved.SOLUTION: A production device of a bag for cryopreservation comprises: a sheet table 18; a sheet press body 19; a laser device 16; and a scanning structure 17. While relatively moving the sheet table 18 and the laser device 16 by the scanning structure 17, an infrared radiation laser beam is radiated to an interface of fluorine-based resin sheets S1, S2, then both sheets S1, S2 are integrated by a contour line bead 1, for forming a storage part 2 for storing a living body texture. In a state that the fluorine-based resin sheets S1, S2 are pressed and held by a radiator 25 which is a deposition posture, the infrared radiation laser beam is made act on the interface of both resin sheets S1, S2 via the radiator 25, for forming the storage part 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an apparatus for manufacturing a cryopreservation bag used when cryopreserving a living tissue such as a human, animal, or plant. The cryopreservation bag is formed as a bag-like container by welding two laminated fluororesin sheets with an infrared laser beam.

  A manufacturing method of this type of cryopreservation bag is disclosed in Patent Document 1, for example. In this case, two laminated thermoplastic resin films are sandwiched between a support and an infrared transmitting solid heat dissipating material (hereinafter simply referred to as a heat dissipating material) and pressurized, and both infrared laser beams are applied from the heat dissipating material side. The film is irradiated to form a weld bead to form a bag-like cryopreservation bag. Examples of the heat radiating material include transparent alumina, transparent beryllia, transparent magnesia, and transparent silicon single crystal that allow infrared laser beams to pass therethrough and have high thermal conductivity. Also, in this document, a fluororesin that is difficult to weld as a thermoplastic resin film is used, or a welding bead in which the accommodation part and the entrance are continuously drawn in a single stroke by operating an infrared laser beam in a horizontal plane. Is formed on the contact surface of a thermoplastic resin film.

  In Patent Document 2, as a heat sealing device for a cryopreservation bag, an apparatus is disclosed in which two sheets of polyolefin film are overlapped and sandwiched between a pair of upper and lower seal dies to heat-seal both sheets. Yes. A vertical gap (slit) is formed at the center of the seal die, and a thin wall region is formed at the bottom of the gap. A through hole through which the coolant passes is formed in each of the meat walls divided by the gap. When heat sealing is performed, both sheets overlapped by a pair of sealing dies are sandwiched, a laser diode disposed in the gap is operated, and a laser beam is applied to a thin wall region to heat-seal both sheets. . At this time, portions other than the thin wall region are cooled by the coolant supplied to the through hole. The obtained polyolefin film bag-like container is used for packaging liquid medicines and foods.

  In the method for fusing the sheet material according to Patent Document 3, two heat-fusing sheet materials are placed on the upper surface of the heat generating member made of a metal plate, and the peripheral portion thereof is pressed by the light transmissive member. Laser light is irradiated from the upper surface side of the light transmissive member to heat the heat generating member, the heat sealing sheet material in contact with the heat generating member is melted, and the two heat sealing sheet materials are fused. Yes. The light transmissive member is made of pressure-resistant glass, quartz glass, heat-resistant glass or the like, and a pressing portion for pressing the heat-bonding sheet material protrudes from the lower surface side thereof. The obtained bag is used as a medical container such as an infusion bag, a nutrient bag, or a blood bag.

International Publication No. 2003-039843 (page 11, Example 1, FIG. 3) JP-A-11-227050 (paragraph number 0010, FIG. 1) JP 2004-142225 A (paragraph number 0056, FIG. 1)

  In the cryopreservation bag of Patent Document 1, a thermoplastic resin film such as a two-layered fluorine-based resin is sandwiched between a support and a heat dissipation material and pressurized, and both infrared laser beams are applied from the heat dissipation material side. By irradiating the film, the accommodating portion filled with the living tissue and the entrance / exit are formed in a single stroke. However, although verification of the cryopreservation bag forming method has been performed by an experimental apparatus, there are some problems in realizing mass production of the cryopreservation bag and reducing the cost.

  The heat sealing apparatus of Patent Document 2 irradiates a laser beam from a laser diode disposed in a gap and heat seals two polyolefin film sheets. Therefore, unlike the welding method of Patent Document 1 in which an infrared laser beam is operated in a horizontal plane, the housing portion for filling the living tissue and the entrance / exit cannot be continuously formed in a single stroke, and the bag shape It is inevitable that it takes a lot of time to form a cryopreservation bag. If the seal die type is configured in a single stroke along the outline of the housing part and the entrance / exit, a bag-like bag can be formed simply by irradiating with an infrared laser beam. Each time it is different, it is necessary to prepare a dedicated seal die mold, which increases costs and lacks responsiveness when changing the shape and size of the bag-like bag.

  In the sheet material fusing method of Patent Document 3, the laser beam is operated along the short side of the heat-bonded sheet material formed in a rectangular shape, and the heat-generating member supporting the heat-bonded sheet material is heat-fused. A bag is formed by feeding and moving along the long side of the dressing sheet material. The feed movement amount of the heat generating member is set equal to the beam diameter of the laser beam. In the obtained bag, all of the peripheral portion (ear portion) excluding the accommodating portion for accommodating the infusion and the like and the entrance / exit are fused on the surface, so that a sturdy bag is obtained. However, since the feed amount of the heat generating member is equal to the beam diameter (0.5 to 3.0 mm) of the laser beam, it takes much time to form one bag, and the bag processing cost is high.

  The object of the present invention is to manufacture a cryopreservation bag made of a fluororesin, which is difficult to heat-process, by automatically and accurately carrying out the welding operation of the resin sheets stacked in two sheets, An object of the present invention is to provide an apparatus for manufacturing a cryopreservation bag that can be mass-produced and reduced in cost.

  The cryopreservation bag manufacturing apparatus according to the present invention includes, as shown in FIG. 2, a sheet table 18 that supports two fluorine resin sheets S1 and S2 stacked on a base 14, and a sheet table 18. Any one of the sheet pressing body 19 for pressing and holding the placed fluororesin sheets S1 and S2, the laser device 16 for irradiating the fluororesin sheets S1 and S2 with an infrared laser beam, the sheet table 18 and the laser device 16 A scanning structure 17 for moving one of them is provided. While the sheet table 18 and the laser device 16 are moved relative to each other by the scanning structure 17, a welded portion is formed by irradiation with an infrared laser beam at the interface between the fluororesin sheets S1 and S2, and the two sheets S1 and S2 are surrounded by an outer bead. 1 (FIG. 6), and a manufacturing apparatus that forms a housing portion 2 that houses a living tissue and an entrance 3 that is continuous with the housing portion 2 is assumed. The sheet table 18 (FIG. 1) includes a metal table main body 20 having a heat-conducting surface and a flush mounting surface. The sheet pressing body 19 includes a heat radiating body 25 made of a solid material rich in infrared transmission and good heat conduction, and a pressing frame 26 that supports the heat radiating body 25. The sheet pressing body 19 is supported by the sheet table 18 so as to be openable and closable, and a welding posture in which the fluororesin sheets S1 and S2 placed on the table body 20 are pressed and held by the radiator 25, and the radiator 25 is a fluororesin. It can be displaced between the standby postures separated from the sheets S1 and S2. In a state where the fluororesin sheets S1 and S2 are pressed and held by the heat dissipating body 25 of the sheet pressing body 19 in the welding position, the infrared laser beam irradiated from the laser device 16 is passed through the heat dissipating body 25 and the fluororesin sheet S1. -The storage part 2 is formed by acting on the interface of S2.

  The sheet table 18 includes a table body 20 and a table base 21 that supports the table body 20. The table base 21 is supported by the scanning structure 17 provided on the base 14 so that the table main body 20 can be displaced with respect to the laser nozzle 37. As shown in FIG. 3, the heat radiator 25 is formed of a single crystal silicon plate and covers the entire fluororesin sheets S <b> 1 and S <b> 2 placed on the table body 20.

  The sheet table 18 includes a table body 20 and a table base 21 that supports the table body 20. The table base 21 is supported by the scanning structure 17 provided on the base 14 so that the table main body 20 can be displaced with respect to the laser nozzle 37. As shown in FIG. 8, the radiator 25 is formed of a single crystal silicon plate and covers only the planned welding positions of the fluororesin sheets S <b> 1 and S <b> 2 placed on the table body 20.

  As shown in FIG. 10, a hinge 29 that supports the sheet pressing body 19 so as to be able to swing open and close and an opening / closing actuator 49 that opens and closes the sheet pressing body 19 are arranged between the table base 21 and the sheet pressing body 19. . In a state where the sheet pressing body 19 is in the welding posture, the heat radiating body 25 presses and holds the fluororesin sheets S <b> 1 and S <b> 2 by the closing operation force of the opening / closing actuator 49.

  The cryopreservation bag manufacturing apparatus according to the present invention includes a sheet table 18, a sheet pressing body 19, a laser device 16, a scanning structure 17, and the like. When manufacturing the cryopreservation bag, the laser device 16 irradiates the interface between the two-layered fluororesin sheets S1 and S2 with the laser device 16 while relatively moving the sheet table 18 and the laser device 16 with the scanning structure 17. The two sheets S1 and S2 are integrated with the outer bead 1 to form the accommodating portion 2 for accommodating the living tissue. Further, the sheet table 18 is provided with a thermally conductive metal table body 20 having a flush mounting surface, and the fluorine resin sheets S1 and S2 are placed on the surface thereof. Furthermore, the sheet pressing body 19 is composed of the heat radiating body 25 made of a solid material rich in infrared transmission and heat conduction, and the pressing frame 26. The laminated fluororesin sheets S1 and S2 were pressed and held, and an infrared laser beam was applied to the interface between the fluororesin sheets S1 and S2.

  According to the cryopreservation bag manufacturing apparatus configured as described above, the outer bead 1 is formed by irradiating the infrared laser beam while moving the sheet table 18 and the laser device 16 relative to each other by the scanning structure 17. The housing part 2 can be formed automatically. Further, in the process of forming the outer bead 1, the heat generated near the irradiated surface is quickly diffused and cooled by the heat radiating body 25 with high thermal conductivity by the laser absorption applied to the surface of the fluororesin sheets S1 and S2. By doing so, the welding trace (thermal damage) was prevented from reaching the sheet surface, and the outer bead 1 was formed only at the interface between the fluororesin sheets S1 and S2. According to such a cryopreservation bag manufacturing apparatus, the welding operation of the two-layered fluororesin sheets S1 and S2 can be performed automatically and accurately, so that the operator can set the fluororesin sheets S1 and S2. A cryopreservation bag can be mass-produced by simply removing the welded bag blank. Furthermore, by realizing mass production of the cryopreservation bags, the cryopreservation bags made of the fluororesin sheets S1 and S2, which are difficult to heat-process, can be reduced in cost and widely spread.

  Since the table base 21 which is smaller and lighter than the laser device 16 is supported by the scanning structure 17 and the table main body 20 is displaced with respect to the laser nozzle 37, the scanning structure 17 can be simplified. Further, the outer bead 1 can be automatically formed at the interface between the sheets S1 and S2 by displacing the fluororesin sheets S1 and S2 with respect to the infrared laser beam. At this time, when the entire fluororesin sheets S1 and S2 are covered with the heat dissipating body 25 formed of a single crystal silicon plate, a cryopreservation bag having different outer shapes and sizes of the accommodating portion 2 and the entrance / exit 3 is manufactured. Even if it exists, the sheet pressing body 19 can be used as it is. Accordingly, it is possible to quickly manufacture a cryopreservation bag having a different external shape and size without the need for setup replacement, and to reduce the cost of the cryopreservation bag accordingly. Furthermore, since the entire fluororesin sheets S1 and S2 are covered with the heat radiating body 25 having excellent thermal conductivity, the heat of welding when forming the outer bead 1 is effectively absorbed and diffused by the heat radiating body 25. It is possible to reliably prevent the surface of the fluororesin sheets S1 and S2 facing the outer wire bead 1 from being overheated.

  When only the position where the fluororesin sheets S1 and S2 placed on the table body 20 are covered with the radiator 25 made of a single crystal silicon plate, the area of the pressing frame 26 in plan view is the area of the radiator 25. It can be larger enough. Therefore, the weight of the sheet pressing body 19 is increased by an amount corresponding to the increased area, and the fluorine-based resin sheets S1 and S2 placed on the table main body 20 can be firmly adhered and fixed to the table main body 20 by the sheet pressing body 19. Moreover, compared with the heat radiator 25 formed in a disk shape, the labor required for mirror processing applied to the upper and lower surfaces of the heat radiator 25 can be reduced, and the processing cost of the heat radiator 25 can be reduced accordingly. The heat radiator 25 having a small area also has an advantage of improving durability by reducing the degree of occurrence of damage accidents.

  When the hinge 29 and the opening / closing actuator 49 are arranged between the table base 21 and the sheet pressing body 19, the heat-dissipating body 25 presses the fluororesin sheets S 1 and S 2 with certainty using the closing operation force of the opening / closing actuator 49. Therefore, it is possible to improve the welding strength of the outer bead 1 by further accurately welding the two resin sheets S1 and S2.

It is a vertical side view of the manufacturing apparatus of the cryopreservation bag according to the present invention. It is a schematic front view of the manufacturing apparatus of the cryopreservation bag. It is a top view of the manufacturing apparatus of the bag for cryopreservation. It is a side view which shows the movement operation | movement of an operation structure. It is sectional drawing which shows the formation condition of a welding bead. It is a front view of the manufactured cryopreservation bag. It is the sectional view on the AA line in FIG. It is a top view which shows another Example of a sheet | seat press body. It is the BB sectional view taken on the line in FIG. It is a vertical side view which shows another Example of the opening / closing structure of a sheet | seat presser.

  1 to 7 show an embodiment of a cryopreservation bag manufacturing apparatus according to the present invention. In the present invention, “front / rear”, “left / right”, and “up / down” follow the cross arrows shown in FIGS. In the manufacturing apparatus according to the present invention, for example, a cryopreservation bag having the structure shown in FIG. 6 can be manufactured, and the structure of the cryopreservation bag will be briefly described before the description of the manufacturing apparatus.

  6 and 7, the cryopreservation bag irradiates two layers of the fluororesin sheets S1 and S2 with an infrared laser beam, and draws a one-stroke outline bead on the interface between the sheets S1 and S2. 1 is formed, and a housing part 2 for housing a living tissue is formed between both sheets S1 and S2 surrounded by an outer bead 1 and an entrance / exit 3 continuous to the housing part 2 is formed. The outer bead 1 that divides the housing portion 2 includes a pair of upper and lower parallel bead portions 4 and 5, a pair of left and right parallel bead portions 6 and 7, and bead portions 4 to 7. The four corner bead portions 8 are formed at the adjacent corner portions of the first and second corner bead portions 8, so that the accommodating portion 2 is formed in a vertically long rectangular shape with four corners dropped. The entrance / exit 3 is formed at the left and right center of the upper bead portion 4. By providing the corner bead portion 8, it is possible to eliminate the formation of a right-angle inner corner in the housing portion 2, and to take out the living tissue housed in the housing portion 2 without any excess.

  The fluorine-based resin sheets S1 and S2 are formed as a transparent sheet that allows transmission of an infrared laser using any one of a fully fluorinated resin, a partially fluorinated resin, and a fluorinated resin copolymer as a forming material. is there. Specific forming materials include polytetrafluoroethylene (PTFE), polychlorotrifluoroethylene (PCTFE), polyvinylidene fluoride (PVDF), polyvinyl fluoride (PVF), perfluoroalkoxy fluorine-based resin (PFA), four fluorine. Ethylene / hexafluoropropylene copolymer (FEP), ethylene / tetrafluoroethylene copolymer (ETFE), chlorotrifluoroethylene copolymer (ECTFE), and the like. In this embodiment, the fluororesin sheets S1 and S2 are formed of a sheet made of a tetrafluoroethylene / hexafluoropropylene copolymer having a thickness of 100 μm, and both sheets S1 and S2 are irradiated with an infrared laser beam. Thus, a cryopreservation bag was formed.

  In FIG. 2, the cryopreservation bag manufacturing apparatus irradiates an infrared laser beam toward the sheet fixing structure 15 on the base 14 and the two-layered fluororesin sheets S1 and S2 supported by the sheet fixing structure 15. And a scanning structure 17 for moving the sheet fixing structure 15 with respect to the infrared laser beam.

  The sheet fixing structure 15 supports the fluorine resin sheets S1 and S2 stacked in two sheets, and holds the fluorine resin sheets S1 and S2 placed on the sheet table 18 and a rectangular sheet table 18 that is long in the front and back. And the sheet pressing body 19 to be configured. The sheet table 18 includes a table body 20 made of aluminum having high thermal conductivity and a table base 21 that fixes and supports the table body 20, and hinges 29 described later are mounted on the left and right of the rear end of the table base 21. A bracket 22 for projecting is projected upward (see FIG. 3). The upper surface (mounting surface) of the table main body 20 on which the fluorine resin sheets S1 and S2 are mounted is finished as a flush horizontal surface.

  The sheet pressing body 19 includes a heat radiating body 25 made of a solid material rich in infrared transmission and good heat conduction, and a steel pressing frame 26 that supports the heat radiating body 25. As a solid material for forming the radiator 25, any of infrared transmitting radiators such as zinc selenide, zinc sulfide, silicon, germanium and the like that are transparent to the infrared laser is used because of the welding process using a carbon dioxide gas laser. In this embodiment, the heat radiator 25 is formed of a single crystal silicon disk. As shown in FIG. 3, the pressing frame 26 is made of an octagonal metal frame wider than the sheet table 18, a circular laser window 27 is opened at the center, and a circular mounting seat 28 is formed on the lower surface side of the window 27. It is formed. The heat dissipating body 25 is fitted into the mounting seat 28 and fixed with an adhesive.

  By connecting the rear portion of the pressing frame 26 and the bracket 22 of the table base 21 with a pair of left and right hinges 29, the entire sheet pressing body 19 is supported by the sheet table 18 so as to be swingable up and down. The sheet pressing body 19 can be displaced between the welding posture shown in FIGS. 3 and 4 and the standby posture shown in FIG. 1, and when the sheet pressing body 19 is in the welding posture, a part of the heat radiating body 25 is It protrudes from the left and right side edges of the sheet table 18 (see FIG. 3). In order to facilitate the opening and closing operation of the sheet pressing body 19, a handle 30 is provided in the center of the front portion of the pressing frame 26. Further, the rubber block 31 provided at the center of the rear portion of the sheet pressing body 19 is received by a stopper 32 fixed to the bracket 22, so that the sheet pressing body 19 that has been opened to the standby position is held in a backward tilted position. I can do it. In this state, the two-layered fluororesin sheets S 1 and S 2 can be placed on the table body 20, or the blank body of the cryopreservation bag after the welding process can be taken out from the table body 20.

  The laser device 16 is a commercially available carbon dioxide laser unit, and an irradiation tube 34 is projected from the side end of a rectangular box-like case that is long on the right and left, and the laser beam output from the resonator inside the case is irradiated. After turning downward by a turning mirror 35 disposed inside the tip of the tube 34, the light is squeezed by a condenser lens 36 provided inside the laser head and irradiated from a laser nozzle 37. The laser device 16 is supported by a laser base 38 fixed on the base 14 and a height adjustment structure 39 provided on the laser base 38. The laser nozzle 37 in this state is located above the sheet fixing structure 15, and its center is located on a vertical line passing through the center of the heat dissipating body 25 in the welding posture. The height adjustment structure 39 is configured by assembling a plurality of link pairs in an X shape. By rotating the adjustment screw shaft 40 arranged at the upper and lower centers of the link pairs, the height adjustment structure 39 The vertical height of the laser device 16 can be adjusted by changing the crossing angle to large or small. The height adjustment by the height adjustment structure 39 may be performed only once, and for example, it is not necessary to adjust the height each time the laser device 16 is used.

  The scanning structure 17 is configured as an XY stage with a Y-axis slider 43 fixed on the base 14 and an X-axis slider 44 fixed to a moving table 45 of the Y-axis slider 43. The Y-axis slider 43 and the X-axis slider 44 are each composed of a commercially available ball screw type electric slider (actuator), and are arranged in a state orthogonal to each other. The table 21 of the sheet table 18 is fixed to the moving table 46 of the X-axis slider 44. Thus, by supporting the table base 21 with the XY stage provided on the base 14, the table main body 20 can be freely displaced with respect to the laser nozzle 37. Thus, both the Y-axis slider 43 and the X-axis slider 44 are moved according to the preset XY coordinates while irradiating the fluororesin sheets S1 and S2 with infrared laser beams. A weld bead having an arbitrary shape can be formed at the interface between the sheets S1 and S2. In FIG. 2, reference numeral 47 is a control device that controls the operating state of the laser device 16 and the scanning structure 17. In the process of manufacturing the cryopreservation bag, there is a risk that the infrared laser emitted from the laser device 16 may leak. In order to prevent exposure by such leaked laser light, the outer surface space of the entire manufacturing device is imagined in FIG. It is covered with a protective wall as shown by the line.

  The manufacturing procedure of the cryopreservation bag will be described below. The laser device 16 adjusts the focus of the condensing lens 36 in advance so as to focus on the interface between the fluorine resin sheets S1 and S2 in which two infrared laser beams are overlapped. As shown in FIG. 1, after the sheet pressing body 19 is opened to the standby posture, the fluororesin sheets S <b> 1 and S <b> 2 are placed in the center of the table body 20. At this time, after positioning the resin sheets S1 and S2 so that the long side portion thereof is parallel to the center of the Y-axis slider 43 and the centers of the fluorine resin sheets S1 and S2 coincide with the center of the table body 20. Thus, the sheet pressing body 19 is lowered and swung to a welding position. In this state, the fluorine resin sheets S <b> 1 and S <b> 2 are in close contact with the table main body 20 due to the weight of the pressing frame 26 and the radiator 25.

  When the above welding preparation work is completed, as shown in FIGS. 4 and 5, the scanning structure 17 is operated so that the welding start position coincides with the irradiation position of the infrared laser beam, and the laser device 16 and the scanning structure 17 are simultaneously operated. Then, the outer bead 1 is formed in a single stroke on the interface between the fluororesin sheets S1 and S2. At this time, since the radiator 25 transmits the infrared laser, it does not generate heat by itself absorbing the infrared laser. Also, when forming the outer bead 1, the heat of welding is conducted around the bead formation position, but the heat generated by the absorption of the laser energy reaching the surface of the fluororesin sheet S1 near the resin surface is Then, it is absorbed and diffused by the heat dissipating body 25 having excellent thermal conductivity. Further, the laser energy that reaches the bonding surface of the fluorine-based resins S1 and S2 is converted into thermal energy, which melts the resin and contributes to welding. This is because the fluororesin has a large infrared absorption, so that the laser energy does not penetrate deep into the resin. Therefore, as shown in FIG. 5, only the interface between the fluorine resin sheets S1 and S2 is welded, and the surface state of the fluorine resin sheets S1 and S2 can be maintained in a smooth state. By irradiating the infrared laser beam from the welding start position to the welding end position, as shown in FIG. 6, a housing portion 2 for housing a living tissue between both sheets S1 and S2 surrounded by the outer bead 1; The entrance / exit 3 which continues to the accommodating part 2 can be formed.

  When the welding operation by the infrared laser is completed as described above, the sheet pressing body 19 is opened to the standby posture, and the bag blank on the table main body 20 is taken out. Thereafter, a large number of bag blanks can be manufactured by repeating the above operation. The blank body of the obtained bag can be obtained by cutting the surrounding portion along the cutting line indicated by the imaginary line in FIG. 6 to obtain a shaped cryopreservation bag.

  According to the cryopreservation bag manufacturing apparatus configured as described above, when manufacturing a cryopreservation bag made of a fluororesin that is difficult to heat, the placement of the fluororesin sheets S1 and S2 and the bag A series of welding operations excluding taking out the blank body can be performed automatically and accurately. Further, by covering the whole of the fluororesin sheets S1 and S2 placed on the table body 20 with the heat dissipating body 25 formed of a single crystal silicon plate, the heat of welding when forming the outer bead 1 is dissipated. It is possible to reliably prevent the surface of the fluorine-containing resin sheets S1 and S2 that are absorbed effectively and directly above or below the outer bead 1 from being overheated. Accordingly, it is possible to prevent the resin sheet in the vicinity of the outer bead 1 from being deteriorated due to the welding operation using the infrared laser, and to deteriorate the physical characteristics, and to have sufficient resistance against severe freezing storage. A cryopreservation bag can be obtained. Further, the obtained cryopreservation bag is smooth without any damage to the resin surface, and is therefore suitable for a medical bag.

  Since the table base 21 which is smaller and lighter than the laser device 16 is supported by the scanning structure 17 and the table main body 20 is displaced with respect to the laser nozzle 37, the scanning structure 17 can be simplified. In addition, since the whole of the fluororesin sheets S1 and S2 placed on the table body 20 is covered with the disc-like heat radiating body 25, an infrared laser beam is radiated to an arbitrary position of the circular heat radiating body 25 so as to form an outline. A bead 1 can be formed. Therefore, even when the outer shape and size of the accommodating portion 2 and the entrance / exit 3 are different, the sheet pressing body 19 can be used as it is to manufacture a cryopreservation bag. Therefore, it is possible to quickly manufacture a cryopreservation bag having a different external shape and size without the need to replace the sheet pressing body 19, and to reduce the cost of the cryopreservation bag accordingly.

  8 and 9 show another embodiment of the sheet pressing body 19. In this case, the radiator 25 is formed in the same shape as the outer shape of the outer bead 1 so that only the planned positions of the fluororesin sheets S1 and S2 placed on the table body 20 are covered with the radiator 25. The width of the radiator 25 is set to be sufficiently larger than the width of the outer bead 1. Others are the same as those of the sheet pressing body 19 described in FIGS. 1 to 4, and thus the same members are denoted by the same reference numerals and description thereof is omitted. As described above, if only the planned welding positions of the fluorine-based resin sheets S1 and S2 are covered with the radiator 25, the area of the pressing frame 26 in plan view can be sufficiently larger than the area of the radiator 25. By increasing the weight of the pressing body 19, the fluororesin sheets S <b> 1 and S <b> 2 placed on the table main body 20 can be firmly adhered and fixed to the table main body 20 by the sheet pressing body 19. Moreover, compared with the heat radiator 25 formed in a disk shape, the labor required for mirror finishing applied to the upper and lower surfaces of the heat radiator 25 can be reduced, and the cost of the heat radiator 25 can be reduced accordingly. Furthermore, the radiator 25 having a small area also has an advantage that the degree of occurrence of damage accidents can be reduced and durability can be improved.

  FIG. 10 shows another embodiment of the opening / closing structure of the sheet pressing body 19. There, the table base 21 and the sheet pressing body 19 are connected by a hinge 29 so that they can be opened and closed, and two air cylinders (opening / closing actuators) 49 are provided between the table base 21 and the sheet pressing body 19. The sheet pressing body 19 can be automatically opened and closed. Specifically, the cylinder bracket 50 is fixed to the left and right of the rear portion of the bracket 22 of the table base 21, and the connecting arms 51 are fixed to the left and right of the rear portion of the pressing frame 26, and the air cylinder 49 is connected to both 50 and 51. The air cylinder 49 is a double action type cylinder, and the sheet pressing body 19 can be slowly moved up and down as well as the sheet pressing body 19 is moved down and swinged to place fluorine on the table body 20. The system resin sheets S1 and S2 can be pressed against the table body 20. In addition, in the state where the sheet pressing body 19 is in the welding position, the fluorine resin sheets S1 and S2 can be firmly pressed and held by continuing to apply the closing operation force of the air cylinder 49 to the heat radiating body 25. Therefore, even when the pressing frame 26 is made of aluminum having a small specific gravity, for example, the fluororesin sheets S1 and S2 can be reliably pressed and fixed. As the opening / closing actuator 49, an opening / closing structure including a motor, a screw shaft that is rotationally driven by the motor, and a female screw body may be applied in addition to the air cylinder.

  As described above, when the sheet pressing body 19 is automatically opened and closed by the air cylinder 49, the cryopreservation bag can be manufactured with less effort. Further, when the operation of placing the fluororesin sheets S1 and S2 on the table body 20 and the operation of taking out the blank body of the bag are performed by the robot hand, the series of operations are completely automated, and the bag for cryopreservation is obtained. Can be mass-produced efficiently.

  In the above-described embodiment, the scanning structure 17 is configured by the Y-axis slider 43 and the X-axis slider 44 each configured by an electric slider, but this is not necessary. For example, the scanning structure 17 can be configured using an electric cylinder, a linear actuator, or the like as an operation element. If necessary, the contour line bead 1 can be formed on the stationary fluororesin sheets S1 and S2 by mounting the laser device 16 on the scanning structure 17. After placing the fluororesin sheets S1 and S2 having a large area on the table main body 20 and forming a plurality of outline bead 1, blank bags of individual bags are punched and shaped into a cryopreservation bag. Can be obtained. The cryopreservation bag does not need to be configured by forming a one-stroke outline line bead 1 on the two-layered fluororesin sheets S1 and S2, but by forming a plurality of outline line beads 1 that intersect. It may be configured.

  In the above embodiment, the sheet pressing body 19 is swingably opened and closed with respect to the table main body 20, but this is not necessary. For example, a holder that can swing horizontally with respect to the table main body 20 is provided, and the sheet pressing body 19 is supported by a guide shaft provided on the holder so as to be movable up and down. It can be made to be able to be displaced between the welding posture and the standby posture. In that case, the sheet pressing body 19 may be pressed by an actuator provided between the sheet pressing body 19 and the holder and held in the welding posture. The hinge 29 can be constituted by a hinge with a built-in damper that prevents a sudden downward swing.

DESCRIPTION OF SYMBOLS 15 Sheet fixing structure 16 Laser apparatus 17 Scanning structure 18 Sheet table 19 Sheet pressing body 20 Table main body 25 Radiator 26 Press frame 36 Condensing lens 37 Laser nozzle 43 Y-axis slider 44 X-axis slider

Claims (4)

A sheet table (18) for supporting two fluorine resin sheets (S1, S2) stacked on the base (14), and a fluorine resin sheet (S1, S2) placed on the sheet table (18) Any one of a sheet pressing body (19) for pressing and holding, a laser device (16) for irradiating an infrared laser beam toward the fluororesin sheet (S1, S2), a sheet table (18), and a laser device (16) A scanning structure (17) for moving one of them,
While the sheet table (18) and the laser device (16) are moved relative to each other by the scanning structure (17), a welded portion is formed by irradiation with an infrared laser beam at the interface of the fluororesin sheets (S1 and S2). An apparatus for producing a cryopreservation bag, in which a sheet (S1, S2) is integrated with an outer bead (1) to form a housing part (2) for housing a living tissue,
The sheet table (18) includes a metal table body (20) that is provided with a flush mounting surface and has high thermal conductivity.
The sheet pressing body (19) includes a heat dissipating body (25) composed of a solid material rich in infrared transmission and good heat conduction, and a pressing frame (26) that supports the heat dissipating body (25).
The sheet pressing body (19) is supported by the sheet table (18) so as to be opened and closed, and is welded to press and hold the fluororesin sheets (S1, S2) placed on the table body (20) with the heat radiating body (25). It can be displaced between the posture and the standby posture in which the radiator (25) separates from the fluororesin sheet (S1, S2),
In the state where the fluororesin sheets (S1 and S2) are pressed and held by the radiator (25) of the sheet pressing body (19) in the welding position, the infrared laser beam irradiated from the laser device (16) 25) An apparatus for manufacturing a cryopreservation bag that forms the accommodating portion (2) by acting on the interface of the fluorine-based resin sheets (S1, S2) via 25). The sheet table (18) includes a table body (20) and a table base (21) that supports the table body (20).
The table base (21) is supported by the scanning structure (17) provided on the base (14), and the table body (20) is provided so as to be able to be displaced with respect to the laser nozzle (37).
The cryopreservation bag according to claim 1, wherein the radiator (25) is formed of a single crystal silicon plate and covers the entire fluororesin sheet (S1, S2) placed on the table body (20). manufacturing device. The sheet table (18) includes a table body (20) and a table base (21) that supports the table body (20).
The table base (21) is supported by the scanning structure (17) provided on the base (14), and the table body (20) is provided so as to be able to be displaced with respect to the laser nozzle (37).
The cryopreservation according to claim 1, wherein the heat dissipating body (25) is formed of a single crystal silicon plate and covers only the planned welding position of the fluororesin sheet (S1, S2) placed on the table body (20). Bag manufacturing equipment. Between the table base (21) and the sheet pressing body (19), a hinge (29) for supporting the sheet pressing body (19) so as to be swingable and openable, and an opening / closing actuator for opening and closing the sheet pressing body (19) 49) is arranged,
The heat radiating body (25) presses and holds the fluororesin sheet (S1, S2) by the closing operation force of the opening / closing actuator (49) in a state where the sheet pressing body (19) is in the welding position. The manufacturing apparatus of the bag for cryopreservation as described in any one of these.

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