公开(公告)号：EP3257912A1

公开(公告)日：2017-12-20

申请号：EP16749254.5

申请日：2016-02-09

申请人： Mitsubishi Heavy Industries, Ltd. ,  Akita University ,  Tsuchiya Co., Ltd.

发明人： TAKAYANAGI, Toshiyuki ,  ISHIKAWA, Naomoto ,  HORIZONO, Hideki ,  KAMIHARA, Nobuyuki ,  MURAOKA, Mikio ,  HAYASHI, Hiroaki ,  YOSHIDA, Osamu ,  TSUJI, Kotaro

IPC分类号： C09J201/00 ,  B29C65/48 ,  C09J11/04

CPC分类号： C09J11/04 ,  B29C65/3612 ,  B29C65/3676 ,  B29C65/48 ,  B29C65/481 ,  B29C66/7212 ,  C08K3/08 ,  C08K2003/0831 ,  C09J5/06 ,  C09J201/00 ,  C09J2205/31 ,  C09J2471/006 ,  C09J2481/006

摘要： Provided are an adhesive that makes it possible to bond thermoplastic resins to each other in a short time and to obtain excellent adhesive strength, a structure bonded by this adhesive, and a bonding method using this adhesive. The adhesive bonds a first member (11) containing a thermoplastic resin or a thermoplastic resin reinforced by carbon fibers and a second member (12) containing this thermoplastic resin or this thermoplastic resin reinforced by carbon fibers. The adhesive has a thermoplastic resin as the base material and contains a metallic nano material that generates heat by absorbing electromagnetic waves, in this base material.

摘要翻译： 本发明提供一种粘合剂，其能够在短时间内使热塑性树脂彼此粘合并且获得优异的粘合强度，由该粘合剂粘合的结构体以及使用该粘合剂的粘合方法。 粘合剂粘合含有热塑性树脂或由碳纤维增强的热塑性树脂的第一构件（11）和含有该热塑性树脂或由碳纤维增强的该热塑性树脂的第二构件（12）。 粘合剂具有热塑性树脂作为基材，并且在该基材中含有通过吸收电磁波而产生热量的金属纳米材料。

公开(公告)号：EP3257977B1

公开(公告)日：2020-01-01

申请号：EP16749233.9

申请日：2016-02-09

申请人： Mitsubishi Heavy Industries, Ltd. ,  Akita University ,  Tsuchiya Co., Ltd.

发明人： MURAOKA, Mikio ,  KAMIHARA, Nobuyuki ,  ISHIKAWA, Naomoto ,  TAKAYANAGI, Toshiyuki ,  HORIZONO, Hideki ,  HAYASHI, Hiroaki ,  YOSHIDA, Osamu ,  TSUJI, Kotaro

IPC分类号： D01F9/08 ,  B22F3/11 ,  H01B13/00 ,  H01F41/04 ,  B22F1/00 ,  B22F1/02 ,  C23C14/20 ,  C23C14/34 ,  C23C14/58 ,  D01D5/00 ,  D01F6/14

公开(公告)号：EP3257977A1

公开(公告)日：2017-12-20

申请号：EP16749233.9

申请日：2016-02-09

申请人： Mitsubishi Heavy Industries, Ltd. ,  Akita University ,  Tsuchiya Co., Ltd.

发明人： MURAOKA, Mikio ,  KAMIHARA, Nobuyuki ,  ISHIKAWA, Naomoto ,  TAKAYANAGI, Toshiyuki ,  HORIZONO, Hideki ,  HAYASHI, Hiroaki ,  YOSHIDA, Osamu ,  TSUJI, Kotaro

IPC分类号： D01F9/08 ,  B22F3/11 ,  H01B13/00 ,  H01F41/04 ,  B22F1/00

摘要： Provided is a method for producing a metal nanocoil, which has excellent mass productivity and is capable of reducing the production cost. This method for producing a metal nanocoil comprises: a step wherein a metal thin film is formed on the surface of a core that is formed of a nanofiber of a polymer in a state where a tension is applied to the core, thereby producing a metal-coated nanofiber; a step wherein the tension applied to the metal-coated nanofiber is relaxed; and a step wherein the metal-coated nanofiber is heated to a temperature that is equal to or higher than the boiling point or the thermal decomposition temperature of the polymer and equal to or lower than the melting point of the metal thin film in a state where the tension is relaxed, so that the core is vaporized and the thin film is shrunk into a coil shape, thereby forming a hollow metal nanocoil.

摘要翻译： 本发明提供一种批量生产性优异且能够降低制造成本的金属纳米线圈的制造方法。 该金属纳米线圈的制造方法包括：在对芯施加张力的状态下，在由聚合物的纳米纤维形成的芯的表面形成金属薄膜的工序， 涂层纳米纤维; 其中施加于金属涂覆的纳米纤维的张力被松弛的步骤; 以及将金属被覆纳米纤维加热到聚合物的沸点或热分解温度以上的温度且在金属薄膜的熔点以下的状态 松弛张力，使芯部气化并将薄膜收缩成线圈状，由此形成中空的金属纳米线圈。

公开(公告)号：EP3733385A1

公开(公告)日：2020-11-04

申请号：EP19747065.1

申请日：2019-01-31

申请人： MITSUBISHI HEAVY INDUSTRIES, LTD. ,  Akita University

发明人： KAMIHARA, Nobuyuki ,  TAKAGI, Kiyoka ,  ABE, Toshio ,  MURAOKA, Mikio ,  TAKAYANAGI, Toshiyuki ,  ISHIKAWA, Naomoto ,  NISHIMURA, Wataru ,  KAMO, Sota ,  DENGO, Tomoharu ,  ISHIDA, Takashi ,  YOSHIDA, Yukihiro

IPC分类号： B29C70/10 ,  B29C43/02 ,  C08J5/04

摘要： Provided are a method for molding a composite material, whereby the occurrence of temperature unevenness in the composite material during heating is reduced, a composite material, a pressing head, and a device for molding a composite material. The method for molding a composite material has an electroconductive wire-shaped material arranging step and a magnetic field application step. The electroconductive wire-shaped material arranging step comprises arranging, in an unreacted composite material 10 having reinforcing fibers 12, a plurality of electroconductive wire-shaped materials 16 at an interval wider than the interval between the reinforcing fibers 12 along a direction intersecting with the reinforcing fibers 12 in the plane in which the reinforcing fibers 12 are aligned. The magnetic field application step comprises applying a magnetic field 42 in a direction intersecting with the plane in which the reinforcing fibers 12 are aligned.

公开(公告)号：EP3885111A1

公开(公告)日：2021-09-29

申请号：EP20749433.7

申请日：2020-01-16

申请人： MITSUBISHI HEAVY INDUSTRIES, LTD. ,  Akita University

发明人： TAKAYANAGI, Toshiyuki ,  ISHIKAWA, Naomoto ,  NISHIMURA, Wataru ,  KAMIHARA, Nobuyuki ,  KAMO, Sota ,  TAKAGI, Kiyoka ,  ISHIDA, Takashi ,  DENGO, Tomoharu ,  MURAOKA, Mikio ,  YOSHIDA, Yukihiro

IPC分类号： B29C70/20 ,  B29C70/40

摘要： A composite material forming method that reduces the occurrence of temperature unevenness in a composite material during heating is provided. The composite material forming method is a method for forming a composite material 10 including reinforcing fibers 12, and includes an equipotential-material connecting step and a magnetic-field applying step. The equipotential-material connecting step is a step of connecting end portions of the reinforcing fibers 12 with equipotential materials 16 to form an electroconductive loop including the reinforcing fibers 12 in the composite material 10 before reaction. The magnetic-field applying step is a step of applying a magnetic field 42 in a direction intersecting a plane formed by the electroconductive loop.

公开(公告)号：EP3835762A1

公开(公告)日：2021-06-16

申请号：EP19864020.3

申请日：2019-09-20

申请人： MITSUBISHI HEAVY INDUSTRIES, LTD. ,  Akita University

发明人： KAMIHARA, Nobuyuki ,  ISHIKAWA, Naomoto ,  TAKAGI, Kiyoka ,  KAMO, Sota ,  YAMAGUCHI, Makoto ,  JIKEI, Mitsutoshi ,  MATSUMOTO, Kazuya ,  MURAOKA, Mikio

IPC分类号： G01N21/65

摘要： Provided are a crystallinity measurement device, a resin-containing material manufacturing device, a crystallinity measurement method, and a resin-containing material manufacturing method capable of calculating crystallinity easily and accurately even when materials other than crystalline thermoplastic resin are included in addition to crystalline thermoplastic resin. A crystallinity measurement device 10 includes a Raman spectroscopy unit 11 and an analysis unit 13. The Raman spectroscopy unit 11 acquires a Raman spectrum of resin-containing material 1 including crystalline thermoplastic resin. The analysis unit 13 calculates the crystallinity of the crystalline thermoplastic resin based on the intensity of a low-wavenumber spectrum that is a spectrum in a region of less than 600 cm -1 , in the Raman spectrum.

公开(公告)号：EP3733390A1

公开(公告)日：2020-11-04

申请号：EP18903832.6

申请日：2018-12-10

申请人： MITSUBISHI HEAVY INDUSTRIES, LTD. ,  Akita University

发明人： KAMIHARA, Nobuyuki ,  YAMAGUCHI, Kengo ,  TAKAGI, Kiyoka ,  ABE, Toshio ,  MURAOKA, Mikio

IPC分类号： B29C70/54 ,  B29C43/36 ,  B29C70/06 ,  B29C70/42 ,  H05B6/10

摘要： Provided are a compression head for reducing the occurrence of temperature unevenness in a composite material during heating, a composite-material molding device, and a composite-material molding method. A compression head 20 is provided on the other side of a pre-reaction composite material 2 from a magnetic field coil 30 provided on one side of the composite material 2, the compression head 20 facing the magnetic field coil 30 via the composite material 2. The compression head 20 has a compression head body 22 and a high-thermal-conductivity-material layer 24. The compression head body 22 is formed from a material that is transparent to a magnetic field 32 applied by the magnetic field coil 30. The high-thermal-conductivity-material layer 24 is formed on the side of the compression head body 22 that faces the composite material 2, and is transparent to the magnetic field 32 applied by the magnetic field coil 30 and is formed from a material having higher thermal conductivity than the composite material 2.

公开(公告)号：EP3584054A1

公开(公告)日：2019-12-25

申请号：EP18766890.0

申请日：2018-03-16

申请人： Mitsubishi Heavy Industries, Ltd.

发明人： KAMIHARA, Nobuyuki ,  ABE, Toshio ,  ISHIKAWA, Naomoto ,  TAKAYANAGI, Toshiyuki ,  MURAOKA, Mikio

IPC分类号： B29C43/52 ,  B29C43/02 ,  B29C70/10 ,  B32B5/02 ,  B32B15/08 ,  B64C1/00 ,  B64D15/12

摘要： Provided are a method for manufacturing a resin sheet 10 capable of substantially transmitting heat, the resin sheet 10, a method for manufacturing a structural body using the resin sheet 10, the structural body, and an airframe of an aircraft. The method for manufacturing the resin sheet 10 comprises: a coating step; a heating step; and a pressurizing step. In the coating step, linear metal nanomaterial 14 is coated on a surface of a resin film 12 having thermal plasticity. In the heating step, the resin film 12 having the linear metal nanomaterial 14 coated on the surface thereof is heated and softened. In the pressurizing step, the resin film 12 having the linear metal nanomaterial 14 coated on the surface thereof is pressurized to press the linear metal nanomaterial 14 along a direction orthogonal to the surface on which the linear metal nanomaterial 14 is coated. Thus, the coated linear metal nanomaterial 14 is caused to penetrate the resin film 12 to obtain the resin sheet 10 containing the linear metal nanomaterial 14.