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Composite Structure Formation Method, Pre-formed Controlled Particles Formed of Fine Particles Non-chemically Bonded Together, and Composite Structure Formation System Involving Controlled Particles
| Content Provider | The Lens |
|---|---|
| Abstract | A composite structure formation method includes the steps of storing a plurality of pre-formed controlled particles in a storage mechanism, supplying the controlled particles from the storage mechanism to an aerosolation mechanism constantly, disaggregating the supplied controlled particles into a plurality of the fine particles in the aerosolation mechanism to form an aerosol in which an entire contents of the controlled particles including the fine particles are dispersed in the gas; and spraying all of the fine particles in the aerosol toward the substrate to form a composite structure of the structure and the substrate. The controlled particles are controlled so that bonding strength between the fine particles includes a mean compressive fracture strength sufficient to substantially avoid disaggregation during the supply step, but which permits the controlled particles to be substantially completely disaggregated in the disaggregation step. |
| Related Links | https://www.lens.org/lens/patent/009-992-580-769-571/frontpage |
| Language | English |
| Publisher Date | 2017-02-21 |
| Access Restriction | Open |
| Content Type | Text |
| Resource Type | Patent |
| Jurisdiction | United States of America |
| Date Applied | 2016-06-28 |
| Agent | Carrier Blackman & Associates, P.c. Joseph P. Carrier William D. Blackman |
| Applicant | Toto Ltd |
| Application No. | 201615195096 |
| Claim | A composite structure formation method based on an aerosol deposition method by which an aerosol with brittle material fine particles dispersed in a gas is sprayed toward a substrate to form a structure made of the brittle material fine particles, the composite structure formation method comprising the steps of: storing a plurality of pre-formed controlled particles in a storage mechanism, each of the controlled particles consists essentially of a plurality of the brittle material fine particles which have been intentionally packed together, each of the brittle material fine particles in each said controlled particle is not chemically bonded together with the other brittle material fine particles in the controlled particle, the controlled particles being formed by using the fine particles whose mean primary particle diameter is 0.1 μm or more and 5 μm or less, the controlled particles have a mean circle-equivalent diameter of 20 μm or more and 500 μm or less, and each of the controlled particles has a mean compressive fracture strength of 0.47 MPa or less; supplying the controlled particles from the storage mechanism to an aerosolation mechanism constantly; disaggregating the supplied controlled particles into a plurality of the fine particles in the aerosolation mechanism to form an aerosol in which an entire contents of the controlled particles including the fine particles are dispersed in the gas; and spraying all of the fine particles in the aerosol toward the substrate to form a composite structure of the structure and the substrate, wherein the controlled particles are controlled so that bonding strength between the fine particles includes a mean compressive fracture strength sufficient to substantially avoid disaggregation during the supply step, but which permits the controlled particles to be substantially completely disaggregated in the disaggregation step. The composite structure formation method according to claim 1 , further comprising the step of: mixing the controlled particles with a gas introduced from a gas supply mechanism to produce a solid-gas mixed phase flow; and supplying the solid-gas mixed phase flow to the aerosolation mechanism. The composite structure formation method according to claim 1 , wherein the mean compressive fracture strength is controlled by manufacturing the controlled particles by adding the fine particles with at least one of water and a binder. The composite structure formation method according to claim 1 , wherein the controlled particles are disaggregated by mechanical impact applied in the aerosolation mechanism. The composite structure formation method according to claim 1 , wherein the mean compressive fracture strength of the controlled particles is 0.34 MPa or less. The composite structure formation method according to claim 1 , wherein the mean compressive fracture strength of the controlled particles is 0.015 MPa or more. The composite structure formation method according to claim 1 , wherein the controlled particles has a mean circularity of 0.65 or more. The composite structure formation method according to claim 1 , wherein the controlled particles have a D10 of 6.6 μm or more. The composite structure formation method according to claim 1 , wherein the controlled particles have a particle size distribution deviation ratio of 0.59 or less. The composite structure formation method according to claim 1 , wherein the controlled particles have an angle of repose of 48 degrees or less. |
| CPC Classification | PROCESSES FOR APPLYING FLUENT MATERIALS TO SURFACES; IN GENERAL SPRAYING APPARATUS;ATOMISING APPARATUS;NOZZLES COATING METALLIC MATERIAL;COATING MATERIAL WITH METALLIC MATERIAL;SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE; BY CHEMICAL CONVERSION OR SUBSTITUTION;COATING BY VACUUM EVAPORATION; BY SPUTTERING; BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION; IN GENERAL TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION Chemical Or Physical Processes; E.G. Catalysis Or Colloid Chemistry;Their Relevant Apparatus CRUSHING; PULVERISING; OR DISINTEGRATING IN GENERAL;MILLING GRAIN SHAPING CLAY OR OTHER CERAMIC COMPOSITIONS;SHAPING SLAG;SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL; e.g. PLASTER |
| Examiner | Ronak Patel |
| Extended Family | 082-231-007-558-430 121-235-739-378-348 009-577-346-374-258 031-285-069-170-726 051-884-792-154-952 045-016-914-093-522 009-992-580-769-571 109-862-972-703-088 123-566-069-908-459 013-297-321-208-569 135-486-704-379-88X 003-951-802-548-792 064-573-233-111-490 101-633-816-899-998 014-950-808-118-595 084-270-104-584-045 150-995-894-943-806 131-624-565-231-902 042-831-757-909-71X |
| Patent ID | 9573149 |
| Inventor/Author | Hatono Hironori Mizukane Masahiro Okamoto Osamu |
| IPC | B32B5/16 B01J2/16 B02C19/00 B05B7/14 B05B12/08 B05D1/12 B28B19/00 C23C24/04 |
| Status | Inactive |
| Simple Family | 082-231-007-558-430 121-235-739-378-348 009-577-346-374-258 051-884-792-154-952 031-285-069-170-726 045-016-914-093-522 135-486-704-379-88X 109-862-972-703-088 123-566-069-908-459 013-297-321-208-569 009-992-580-769-571 003-951-802-548-792 064-573-233-111-490 101-633-816-899-998 014-950-808-118-595 084-270-104-584-045 150-995-894-943-806 042-831-757-909-71X 131-624-565-231-902 |
| CPC (with Group) | B05D1/12 B05B7/1404 C23C24/04 Y10T428/25 Y10T428/2982 B05B7/144 B01J2/16 B02C19/0043 B02C19/065 B02C19/066 B05B7/1445 B05B12/085 B28B19/00 |
| Issuing Authority | United States Patent and Trademark Office (USPTO) |
| Kind | Patent/New European patent specification (amended specification after opposition procedure) |
