広島大学

Basic Information

Academic Degrees

• HOKKAIDO UNIVERSITY
• HOKKAIDO UNIVERSITY

Research Fields

• Engineering;Integrated engineering;Aerospace engineering
• Engineering;Mechanical engineering;Materials / Mechanics of materials

Affiliated Academic Societies

• The Japan Society of Naval Architects and Ocean Engineers
• American Institute of Aeronautics and Astronautics
• Japanese Society of Mechanical Engineers

Educational Activity

Course in Charge

1. 2024, Liberal Arts Education Program1, 4Term, Science of Vehicle and Transportation
2. 2024, Undergraduate Education, 3Term, Structural Analysis and Design
3. 2024, Undergraduate Education, 2Term, Theory of Elasticity
4. 2024, Undergraduate Education, Year, Graduation Thesis
5. 2024, Graduate Education (Master's Program) , 1Term, Special Exercises on Transportation and Environmental Systems A
6. 2024, Graduate Education (Master's Program) , 2Term, Special Exercises on Transportation and Environmental Systems A
7. 2024, Graduate Education (Master's Program) , 3Term, Special Exercises on Transportation and Environmental Systems B
8. 2024, Graduate Education (Master's Program) , 4Term, Special Exercises on Transportation and Environmental Systems B
9. 2024, Graduate Education (Master's Program) , Academic Year, Special Study on Transportation and Environmental Systems
10. 2024, Graduate Education (Master's Program) , 1Term, Advanced composite materials engineering
11. 2024, Graduate Education (Doctoral Program) , Academic Year, Special Study on Transportation and Environmental Systems

Research Activities

Academic Papers

1. Invar alloy metallization of Al2O3 substrate by friction stirring, Ceramics International, 49(11), 18624-18628, 202306
2. Analysis of Periodicity of Passenger Aircraft Orders by using Fourier Transform, Journal of the Japanese Society for Experimental Mechanics, 23(1), 22-30, 20230410
3. Effects of stacking sequences of non-hydrophobic cellulose nanofiber dispersion layer on impact properties of carbon fiber/cellulose nanofiber reinforced epoxy composite, Mechanics of Advanced Materials and Structures, 30(3), 582-591, 20230201
4. Optimization of CFRP skeletal structure of morphing wings and manufacturing by electrodeposition ..., AIAA SCITECH 2023 Forum, 2023, 1708, 20230123
5. Manufacturability and Deformation Performances of CFRP Twist Morphing Wing Structure with Applying the Electrodeposition Resin Molding Method, PROCEEDINGS OF THE 2021 ASIA-PACIFIC INTERNATIONAL SYMPOSIUM ON AEROSPACE TECHNOLOGY (APISAT 2021), VOL 1, 912, 879-891, 2023
6. Manufacturing of morphing wings for long-range flight UAVs and its aerodynamic properties, Proceedings of the 2022 Asia-Pacific International Symposium on Aerospace Technology, 202210
7. Laser butt joining of Al2O3 ceramic plates metallized by friction stir welding, Ceramics International, 48(16), 23381-23386, 202208
8. Estimation of damping characteristics and optimization of curvilinear fiber shapes for composites fabricated by electrodeposition resin molding, Mechanics of Advanced Materials and Structures, 20220712
9. Impact properties of carbon fiber/cellulose nanofiber reinforced epoxy composite using asymmetric stacking sequence of non-hydrophobic cellulose nanofiber dispersion layer, MECHANICS OF ADVANCED MATERIALS AND STRUCTURES, 202206
10. Manufacturing Method of CFRP by Electrodeposition Resin Molding Method, 機能材料, 42(4), 30-37, 202204
11. Mechanical properties of the skeletal structure for UAV morphing wing by using CFRP with applying the electrodeposition resin molding method, AIAA SCITECH 2022 Forum, 20220103
12. Deformation of the skeletal structure for UAV morphing wing by CFRP with applying the additive manufacturing method, Proceedings of 12th Asia-Pacific International Symposium on Aerospace Technology (APISAT 2021), P00117, 20211115
13. MANUFACTURING METHOD OF THE MORPHING WING STRUCTURE FOR UAV BY CFRP WITH APPLYING THE ELECTROFORMED RESIN MOLDING METHOD, American Society for Composites 2021, 1, 3-10, 20210920
14. Effects of cellulose nanofiber content on impact properties of carbon fiber reinforced epoxy composites with the cellulose nanofiber dispersion layer, Mechanics of Advanced Materials and Structures, 29(27), 6087-6095, 2021
15. Enhancement of impact properties of CFRP by inserting the non-hydrophobized cellulose nanofiber dispersion layer using an aqueous solution of epoxy resin, Mechanics of Advanced Materials and Structures, 29(26), 5350-5359, 2021
16. Enhancement method of CFRP with the non-hydrophobized cellulose nanofibers using aqueous electrodeposition solution, Mechanics of Advanced Materials and Structures, 29(26), 4631-4638, 2021
17. Tensile strength of CFRP with curvilinearly arranged carbon fiber along the principal stress direction fabricated by the electrodeposition resin molding, Composites Part A: Applied Science and Manufacturing, 143, 106271-106271, 202101
18. Metallization of Al2O3 ceramic with Mg by friction stir spot welding, Ceramics International, 47(9), 12789-12794, 202105
19. Enhancement of the bending strength of I-shaped cross-sectional beam of CFRP by dispersing cellulose nanofibers without hydrophobic treatment on the surface, Mechanics of Advanced Materials and Structures, 28(11), 1089-1097, 202106
20. Vibration characteristics of carbon fiber reinforced composites fabricated by electrodeposition molding method,, Proceedings of the 15th International Conference on Motion and Vibration Control (MoViC2020), 10018, 20201208
21. An Efficient Manufacturing method of CFRP Lattice Structures by using the Electrodeposition Resin Impregnation Method, Proceedings of 16th Asia-Pacific Conference on Fracture and Strength 2020 (APCFS2020), 00097, 20201103
22. Effects of the Cellulose Nanofiber/Resin Layer Inserted in CFRP on the Charpy Impact and Bending Properties, Proceedings of 16th Asia-Pacific Conference on Fracture and Strength 2020 (APCFS2020), 00053, 20201103
23. Fabrication of a cylindrical lattice structure by using the electrodeposition resin molding method and its compression properties, Proceedings of ICCS23 - 23rd International Conference on Composite Structures & MECHCOMP6 - 6th International Conference on Mechanics of Composites, 2523, 20200903
24. Lap joint formed by friction stir spot welding between SiC and magnesium alloy containing aluminum, Ceramics International, 46(6), 7654-7658, 202004
25. Facile synthesis of MgO-modified mesoporous silica and its application to a CoMo-based ammonia decomposition catalyst, 大日本窯業協會雑誌, 128(2), 84-91, 20200201
26. Fabrication of the twist morphing wing for the UAV by CFRP with applying the electrodeposition resin molding method, AIAA Scitech 2020 Forum, 1 PartF, AIAA 2020-0883, 20200106
27. Manufacturing method of the heat-storable carbon fiber reinforced plastics with applying trans-1,4-polybutadiene by using cellulose nanofibers and electrodeposition solution, Journal of Energy Storage, 31, 101636-101636, 202010
28. An efficient manufacturing method for I-shaped cross-sectional CFRP beam with arbitrary arrangement of carbon fiber using electro-activated resin molding, Mechanics of Advanced Materials and Structures, 27(18), 1541-1550, 20200915
29. Dissimilar welds between Al2O3 and AZX612-Mg alloy by friction stir spot welding, JOURNAL OF THE CERAMIC SOCIETY OF JAPAN, 127(12), 939-941, 20191201
30. Finite element analysis of the effects of cellulose nanofibers on the bending properties of the CFRP I-shaped cross-sectional beam, Proceedings of International Conference on Advanced Technology in Experimental Mechanics 2019, JSME, 201911
31. Fabrication of the CFRP with carbon fibers arranged in principal stress direction using the electro-activated deposition resin molding method and its mechanical properties, Proceedings of International Conference on Advanced Technology in Experimental Mechanics 2019, JSME, 201911
32. Experimental fabrication of the morphing wing for UAVs by using the electrodeposition resin molding method, KOREA-JAPAN JOINT SEMINAR ON ADVANCED STRUCTURES AND MATERIALS FOR MORPHING TECHNOLOGY IN FUTURE AIRCRAFTS, 201911
33. Enhancement of the bending strength of I-shaped cross-sectional beam of CFRP by dispersing cellulose nanofibers without hydrophobic treatment on the surface, Mechanics of Advanced Materials and Structures, 20190627
34. Development of a Heat-storable CFRP by incorporating trans-1,4-polybutadiene for the Thermal Management of Small Artificial Satellite, Proceedings of 32nd International Symposium on Space Technology and Science & 9th Nano-Satellite Symposium, a90345, 201906
35. Interface microstructure observation for welds of an alumina ceramics and an aluminum alloy with friction stir spot welding, JOURNAL OF THE CERAMIC SOCIETY OF JAPAN, 127(2), 127-130, 201902
36. Enhancement of mechanical properties of CFRP manufactured by using electro-activated deposition resin molding method with the application of CNF without hydrophobic treatment, Composites Science and Technology, 169, 203-208, 20190105
37. The effects of the addition of calcium phosphate on catalytic activities for ammonia decomposition on CoMo-based catalysts, Journal of the Ceramic Society of Japan, 127(11), 802-809, 2019
38. The bending properties of CFRP I-shaped cross-sectional beam with dispersing cellulose nanofibers on the surface, Proceedings of the American Society for Composites - 34th Technical Conference, ASC 2019, 2019
39. Enhancement of the mechanical properties of the CFRP by cellulose nanofiber sheets using the electro-activated deposition resin molding method, Composites Part A: Applied Science and Manufacturing, 123, 320-326, 201908
40. EVALUATION OF POWER GENERATION FROM BIOMASS USING SOLID OXIDE FUEL CELL (SOFC) AND DOWNDRAFT GASIFIERS, PROCEEDINGS OF THE 42ND INTERNATIONAL CONFERENCE ON ADVANCED CERAMICS AND COMPOSITES: CERAMIC ENGINEERING AND SCIENCE PROCEEDINGS, VOL 39, ISSUE 3, 39(3), 245-257, 2019
41. CFRP manufacturing method by using electro-activated deposition and the effect of reinforcement with carbon fiber circumferentially around the hole, Composite Structures, 207, 658-664, 20190101
42. Fabrication of heat-storable CFRP by incorporating trans-1,4-polybutadiene with the application of the electrodeposition resin molding method, Journal of Energy Storage, 26, 100980-100980, 201912
43. Efficient manufacturing method of CFRP corrugation by using electro-Activated deposition resin molding, 33rd Technical Conference of the American Society for Composites 2018, 5, 2819-2831, 2018
44. Resin molding by using electro-activated deposition for efficient manufacturing of carbon fiber reinforced plastic, Composite Structures, 182, 666-673, 20171215
45. CFRP manufacturing method using electrodeposition resin molding for curvilinear fiber arrangements, Composites Part A: Applied Science and Manufacturing, 102, 108-116, 201711
46. IGBT cooling system using high thermal conductive aluminum based composite containing VGCF-CNT network, 51st AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition 2013, 2013
47. Improvements of thermal conductivity of aluminum based composites containing VGCF-CNT network by heat treatments of CNT, 50th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition, 2012
48. Correlations between Thermal Conductivity and Inelastic Deformation of Aluminum Based Composites Containing VGCF-CNT Network, Journal of Solid Mechanics and Materials Engineering, 6(7), 801-813, 2012
49. High Thermal Conductive Composite Containing a Network of Vapor Grown Carbon Fiber and Carbon Nanotube in Aluminum Matrix, Proceedings of 49th AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition, AIAA2011-254, 201101
50. High-Temperature Strength Property of VGCF-Al Composite Materials Having High Thermal Conductivity, TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A, 77(779), 1037-1040, 2011
51. Aluminium based high thermal conductive composites containing CNT and VGCF-deformation dependence of thermal conductivity, Procedia Engineering, 10, 912-917, 2011
52. Strength of VGCF/Al Composites for High Thermal Conductivity, Journal of Solid Mechanics and Materials Engineering, 4(8), 1273-1281, 2010
53. Effect of CNT addition on thermal properties of VGCF/aluminum composites, Nihon Kikai Gakkai Ronbunshu, A Hen/Transactions of the Japan Society of Mechanical Engineers, Part A, 75(1), 27-33, 2009
54. Effect of CNT Addition on Thermal Properties of VGCF/Aluminum Composites, TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A, 75(749), 27-33, 2009
55. Thermal and mechanical properties of VGCF-containing aluminum, Nihon Kikai Gakkai Ronbunshu, A Hen/Transactions of the Japan Society of Mechanical Engineers, Part A, 74(5), 655-661, 20080525
56. Numerical simulations of strength of VGCF/Aluminum composite materials, Progress of Composites 2008 in Asia and Australasia - Proceedings of the 6th Asian-Australasian Conference on Composite Materials, ACCM 2008, 60-63, 2008
57. Effect of CNT addition on thermal conductivity of VGCF/Aluminum composite materials, Progress of Composites 2008 in Asia and Australasia - Proceedings of the 6th Asian-Australasian Conference on Composite Materials, ACCM 2008, 76-79, 2008
58. Thermal and Mechanical Properties of VGCF-Containing Aluminum, TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A, 74(741), 655-661, 20080525
59. Stiffness and thermal conductivity of carbon nanotube containing aluminum, PROGRESSES IN FRACTURE AND STRENGTH OF MATERIALS AND STRUCTURES, 1-4, 353-358(PART 1), 587-590, 2007
60. Effects of Nucleus Pulposus on Loading Response of the Lumbar Intervertebral Disc, Hokkaido Univ., 199903
61. Intradiscal Pressure Response to Low-Frequency Cyclic Loading., JSME International Journal Series C, 42(3), 583-589, 1999
62. Measurement of Intradiscal Pressure Response to Low-frequency Cyclic Loading., TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A, 64(625), 2429-2434, 19980925
63. A "follower load" increases the load carrying capacity of the lumbar spine in axial compression, American Society of Mechanical Engineers, Bioengineering Division (Publication) BED, 35, 437-438, 1997
64. A constitutive modeling of the human lumbar intervertebral disc and forward-backward bending simulation, Bio-Medical Materials and Engineering, 7(3), 179-191, 1997
65. Effects of degeneration on the elastic modulus distribution in the lumbar intervertebral disc, Spine, 21(7), 811-820, 1996

Invited Lecture, Oral Presentation, Poster Presentation

1. Development of heat storage CFRP by using solid phase heat storage material, Kazuaki Katagiri, 2021/12/17, With Invitation
2. Aircraft Technology Innovation and Economic progress, Kazuaki Katagiri, JSME Kansai branch, With Invitation, Japanese
3. Intradiscal Pressure Response to Low-frequency Cyclic Loading, Kazuaki Katagiri, Loyola University Thesis Day Lecture, With Invitation, English

Awards

1. 2019/01, Third Place of the Best Paper Awards, The American Ceramics Society

Patented

1. JP第6864346号, 2021/04/06, ヒートシンク及びヒートシンクの製造方法
2. JP6664732, 2020/02/21
3. 炭素繊維強化プラスチックの製造方法
4. JP第5569839号, 2014/07/04, 炭素繊維配向シート製造方法
5. JP第5500710号, 2014/03/20, 高熱伝導性複合材料及びその製造方法
6. JP第5388654号, 2013/10/18, 高熱伝導性複合材料及びその製造方法
7. JP第5288441号, 2013/06/14, 高熱伝導複合材料とその製造方法
8. JP第5229934号, 2013/03/29, 高熱伝導性複合材料
9. JP第5116082号, 2012/10/26, 高熱伝導複合材料
10. 炭素繊維配向シート製造方法
11. 高熱伝導性複合材料及びその製造方法
12. 高熱伝導性複合材料及びその製造方法
13. JP第4593472号, 2010/09/24, カーボンナノチューブ分散複合材料の製造方法並びにその適用物
14. JP第4593473号, 2010/09/24, カーボンナノチューブ分散複合材料の製造方法
15. 均熱板並びにこれを使用した基板加熱装置及び基板冷却装置
16. 高熱伝導性複合材料
17. 高熱伝導複合材料
18. カーボンナノチューブ分散複合材料の製造方法
19. 高熱伝導複合材料とその製造方法
20. カーボンナノチューブ分散複合材料の製造方法
21. カーボンナノチューブ分散複合材料の製造方法
22. カーボンナノチューブ分散複合材料とその製造方法並びにその適用物
23. カーボンナノチューブ分散複合材料とその製造方法並びにその適用物
24. 炭素アルミニウム複合材料または炭化珪素アルミニウム複合材料に金属を接合したハイブリッド材料および該ハイブリッド材料を用いた熱交換器用部品

External Funds

Acceptance Results of Competitive Funds

1. Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (B), Innovative manufacturing of advanced composites using electrodeposition resin molding and vibration optimization, 2020/04/01, 2024/03/31
2. Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (B), Development of the manufacturing method of CFRP lattice structure by using electrodeposition resin impregnation method and its application technology, 2020/04/01, 2023/03/31
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3. Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (C), 3D molding of CFRP by impregnation of electrodeposited resin on non crimp carbon fabric with curved carbon fiber, 2017/04/01, 2020/03/31
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4. JAXA aerospace technology innovation fund, Development of design and manufacturing method for a morphing wing by applying CFRP, 2018/10, 2019/03
5. JAXA aerospace technology innovation fund, Development of resin impregnation technology of CFRP by electrodeposition method for aircraft parts, 2016/10, 2017/03