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(Created claim: summary (P836): Keywords: Adhesive manufacturing, Smart functionality, Composite, Nanomodified plastic. The code for the statistical classification of the economic activities of the project (NACE Rev. 2), according to the expected results of the project and the objective pursued, shall be: NACE2 # "22.2. Plastics production"adivity manufacturing (AR) technology allows manufacturers to produce smart composite structures with additional functionalities, e.g. defo...) |
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Keywords: Adhesive manufacturing, Smart functionality, Composite, Nanomodified plastic. The code for the statistical classification of the economic activities of the project (NACE Rev. 2), according to the expected results of the project and the objective pursued, shall be: NACE2 # "22.2. Plastics production"adivity manufacturing (AR) technology allows manufacturers to produce smart composite structures with additional functionalities, e.g. deformation detection; Active heating and de-icing process; Improved passive cooling; Electrostatic discharge; Electromagnetic radiation shielding, etc. A 3D printer with a double nozzle provides object printing with two materials (isolator and conductive nanoparticle-filled plastic), where a network of 3D conductive tracks has been introduced purposefully. The overall objective of the project is to establish a science-based information platform for users using additive manufacturing (AR) for the production of nanomodified structures for industry 4.0. The established platform will allow creating a smart multifunctional product with optimal design and assessing its durability, thus increasing the product’s efficiency. The specific objective of the project is to demonstrate the Solution Tool (RR) for the production of smart polymer nanocomposite structures using additive manufacturing. RI will include:1.a material database with physical and mechanical properties of materials used for simulation; 2.simulation Module:2.1.application with thermoplastic cord melting technology (Fused deposition Modelling, FDM) for the preparation of final element models of products manufactured by the simulation and simulation of physical and mechanical properties taking into account the printing parameters and microstructure of the printed material using open source and/or proprietary final element software (e.g. software for physical and mechanical properties (e.g. CalAS) and microstructure of the printed material using open source and/or patented final elements software (e.g., CalAS) Code; 2.2.applications for preparation of final element models and simulation/optimisation of physical and mechanical properties for products with built-in electrical conductive tracks; 2.3. advanced functionality of applications for preparation of the final elements of the body prototype and simulation of properties.3. The guide.The project is an industrial cross-sector study that is not economic in nature and it corresponds to the following fields of science (according to the OECD FOS classification of scientific disciplines) 2. Engineering and Technology subsectors: 2.3. Mechanical engineering; 2.5. Material engineering; 2.10. Nanotechnology.The project includes the following activities: The technical specification; Technology; Characterisation of 3D nanocomposites; Modelling properties; Development of a solution tool; Dissemination of results and public engagement. Expected results: 1. A knowledge database containing information on the physical and mechanical properties of the various printed materials.2. Solution tool – a set of tools for optimal design of electrical conductive products made with 3D printing technology and systematised set of practical information based on scientific research results describing guidelines for manufacturing of intelligent polymer composite materials.3. Original scientific articles based on results obtained during the project, which will be submitted for publication.The project will be implemented in cooperation with partner RITEC SIA and BALTIC Scientific INSTRUMENTS SIA. The Latvian Association of Chemical and Pharmaceutical Entrepreneurs confirms its opinion on the importance of the project with the Opinion. Total cost of the project: EUR 645000.00, public funding amount – EUR 596625.00 (92.5 %), co-financing – EUR 48375.00 (7.5 %). Planned duration of the project: 36 months (01.07.2020.-30.06.2023).The workload of the scientific staff involved in the project in full-time equivalent terms (FTE) during the project implementation period will be 5.55 FLE, of which not less than 26.1 % of the total project staff will be students and candidates (1.45 PLE), young scientists 27.0 % (1.50 PLE), who will improve competence within the project, including career development and personnel renewal processes. During the implementation of the project, the new researcher will be involved in the workload of 0.5 FTE. (English) | |||||||||||||||
Property / summary: Keywords: Adhesive manufacturing, Smart functionality, Composite, Nanomodified plastic. The code for the statistical classification of the economic activities of the project (NACE Rev. 2), according to the expected results of the project and the objective pursued, shall be: NACE2 # "22.2. Plastics production"adivity manufacturing (AR) technology allows manufacturers to produce smart composite structures with additional functionalities, e.g. deformation detection; Active heating and de-icing process; Improved passive cooling; Electrostatic discharge; Electromagnetic radiation shielding, etc. A 3D printer with a double nozzle provides object printing with two materials (isolator and conductive nanoparticle-filled plastic), where a network of 3D conductive tracks has been introduced purposefully. The overall objective of the project is to establish a science-based information platform for users using additive manufacturing (AR) for the production of nanomodified structures for industry 4.0. The established platform will allow creating a smart multifunctional product with optimal design and assessing its durability, thus increasing the product’s efficiency. The specific objective of the project is to demonstrate the Solution Tool (RR) for the production of smart polymer nanocomposite structures using additive manufacturing. RI will include:1.a material database with physical and mechanical properties of materials used for simulation; 2.simulation Module:2.1.application with thermoplastic cord melting technology (Fused deposition Modelling, FDM) for the preparation of final element models of products manufactured by the simulation and simulation of physical and mechanical properties taking into account the printing parameters and microstructure of the printed material using open source and/or proprietary final element software (e.g. software for physical and mechanical properties (e.g. CalAS) and microstructure of the printed material using open source and/or patented final elements software (e.g., CalAS) Code; 2.2.applications for preparation of final element models and simulation/optimisation of physical and mechanical properties for products with built-in electrical conductive tracks; 2.3. advanced functionality of applications for preparation of the final elements of the body prototype and simulation of properties.3. The guide.The project is an industrial cross-sector study that is not economic in nature and it corresponds to the following fields of science (according to the OECD FOS classification of scientific disciplines) 2. Engineering and Technology subsectors: 2.3. Mechanical engineering; 2.5. Material engineering; 2.10. Nanotechnology.The project includes the following activities: The technical specification; Technology; Characterisation of 3D nanocomposites; Modelling properties; Development of a solution tool; Dissemination of results and public engagement. Expected results: 1. A knowledge database containing information on the physical and mechanical properties of the various printed materials.2. Solution tool – a set of tools for optimal design of electrical conductive products made with 3D printing technology and systematised set of practical information based on scientific research results describing guidelines for manufacturing of intelligent polymer composite materials.3. Original scientific articles based on results obtained during the project, which will be submitted for publication.The project will be implemented in cooperation with partner RITEC SIA and BALTIC Scientific INSTRUMENTS SIA. The Latvian Association of Chemical and Pharmaceutical Entrepreneurs confirms its opinion on the importance of the project with the Opinion. Total cost of the project: EUR 645000.00, public funding amount – EUR 596625.00 (92.5 %), co-financing – EUR 48375.00 (7.5 %). Planned duration of the project: 36 months (01.07.2020.-30.06.2023).The workload of the scientific staff involved in the project in full-time equivalent terms (FTE) during the project implementation period will be 5.55 FLE, of which not less than 26.1 % of the total project staff will be students and candidates (1.45 PLE), young scientists 27.0 % (1.50 PLE), who will improve competence within the project, including career development and personnel renewal processes. During the implementation of the project, the new researcher will be involved in the workload of 0.5 FTE. (English) / rank | |||||||||||||||
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Property / summary: Keywords: Adhesive manufacturing, Smart functionality, Composite, Nanomodified plastic. The code for the statistical classification of the economic activities of the project (NACE Rev. 2), according to the expected results of the project and the objective pursued, shall be: NACE2 # "22.2. Plastics production"adivity manufacturing (AR) technology allows manufacturers to produce smart composite structures with additional functionalities, e.g. deformation detection; Active heating and de-icing process; Improved passive cooling; Electrostatic discharge; Electromagnetic radiation shielding, etc. A 3D printer with a double nozzle provides object printing with two materials (isolator and conductive nanoparticle-filled plastic), where a network of 3D conductive tracks has been introduced purposefully. The overall objective of the project is to establish a science-based information platform for users using additive manufacturing (AR) for the production of nanomodified structures for industry 4.0. The established platform will allow creating a smart multifunctional product with optimal design and assessing its durability, thus increasing the product’s efficiency. The specific objective of the project is to demonstrate the Solution Tool (RR) for the production of smart polymer nanocomposite structures using additive manufacturing. RI will include:1.a material database with physical and mechanical properties of materials used for simulation; 2.simulation Module:2.1.application with thermoplastic cord melting technology (Fused deposition Modelling, FDM) for the preparation of final element models of products manufactured by the simulation and simulation of physical and mechanical properties taking into account the printing parameters and microstructure of the printed material using open source and/or proprietary final element software (e.g. software for physical and mechanical properties (e.g. CalAS) and microstructure of the printed material using open source and/or patented final elements software (e.g., CalAS) Code; 2.2.applications for preparation of final element models and simulation/optimisation of physical and mechanical properties for products with built-in electrical conductive tracks; 2.3. advanced functionality of applications for preparation of the final elements of the body prototype and simulation of properties.3. The guide.The project is an industrial cross-sector study that is not economic in nature and it corresponds to the following fields of science (according to the OECD FOS classification of scientific disciplines) 2. Engineering and Technology subsectors: 2.3. Mechanical engineering; 2.5. Material engineering; 2.10. Nanotechnology.The project includes the following activities: The technical specification; Technology; Characterisation of 3D nanocomposites; Modelling properties; Development of a solution tool; Dissemination of results and public engagement. Expected results: 1. A knowledge database containing information on the physical and mechanical properties of the various printed materials.2. Solution tool – a set of tools for optimal design of electrical conductive products made with 3D printing technology and systematised set of practical information based on scientific research results describing guidelines for manufacturing of intelligent polymer composite materials.3. Original scientific articles based on results obtained during the project, which will be submitted for publication.The project will be implemented in cooperation with partner RITEC SIA and BALTIC Scientific INSTRUMENTS SIA. The Latvian Association of Chemical and Pharmaceutical Entrepreneurs confirms its opinion on the importance of the project with the Opinion. Total cost of the project: EUR 645000.00, public funding amount – EUR 596625.00 (92.5 %), co-financing – EUR 48375.00 (7.5 %). Planned duration of the project: 36 months (01.07.2020.-30.06.2023).The workload of the scientific staff involved in the project in full-time equivalent terms (FTE) during the project implementation period will be 5.55 FLE, of which not less than 26.1 % of the total project staff will be students and candidates (1.45 PLE), young scientists 27.0 % (1.50 PLE), who will improve competence within the project, including career development and personnel renewal processes. During the implementation of the project, the new researcher will be involved in the workload of 0.5 FTE. (English) / qualifier | |||||||||||||||
point in time: 15 July 2021
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Revision as of 12:35, 15 July 2021
Project Q3056443 in Latvia
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English | No label defined |
Project Q3056443 in Latvia |
Statements
372,810.0 Euro
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645,000.0 Euro
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1 July 2020
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30 June 2023
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LATVIJAS UNIVERSITĀTE
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Atslēgas vārdi: Aditīvā ražošana, Viedā funkcionalitāte, Kompozīts, Nanomodificēta plastmasa. Projekta saimnieciskās darbības statistiskās klasifikācijas (NACE 2. red.) kods, saskaņā ar projektā plānotajiem rezultātiem un sasniedzamo mērķi, ir: NACE2 # "22.2. Plastmasas izstrādājumu ražošana"Aditīvās ražošanas (AR) tehnoloģija ļauj ražotājiem izgatavot viedās kompozīta struktūras ar papildus funkcionalitātēm, piem. deformācijas detektēšana; aktīvā karsēšana un atledošanas process; uzlabota pasīvā dzesēšana; elektrostatiskā izlāde; elektromagnētisko starojumu ekranējums utt. 3D printeris ar divkāršo sprauslu nodrošina objekta drukāšanu ar diviem materiāliem (izolators un elektrovadošā ar nanodaļiņām pildīta plastmasa), kur ir mērķtiecīgi ievadīti 3D elektrovadošu celiņu tīkls. Projekta vispārējais mērķis ir izveidot zinātniski balstītu informācijas platformu lietotājiem, kas izmanto aditīvo ražošanu (AR) nanomodificētu struktūru izgatavošanai Industrijai 4.0. Izveidotā platforma ļaus izveidot viedo daudzfunkcionālo produktu ar optimālo dizainu un novērtēt tā ilgizturību, tādā veidā palielinot produkta efektivitāti. Projekta specifiskais mērķis ir izstādāt Risinājuma Rīks (RR) viedo polimēra nanokompozīta struktūru izgatavošanai, izmantojot aditīvo ražošanu. RI sevī ietvers:1.materiālu datubāzi ar simulācijā izmantojamo materiālu fizikālajām un mehāniskajām īpašībām;2.simulācijas moduli:2.1.aplikāciju ar termoplastikāta auklas kausēšanas tehnoloģiju (Fused Deposition Modelling, FDM) izgatavoto izstrādājumu galīgo elementu modeļu sagatavošanai un fizikālo un mehānisko īpašību simulācijai ņemot vērā drukāšanas parametrus un izdrukātā materiāla mikrostruktūru, izmantojot atvērtā koda un/vai patentētu galīgo elementu programmatūru (piemēram, Calculix, Code_Aster vai Ansys); 2.2.aplikāciju galīgo elementu modeļu sagatavošanai un fizikālo un mehānisko īpašību simulācijai/optimizācijai izstrādājumiem ar iestrādātiem elektrovadošiem celiņiem;2.3.aplikāciju uzlabotas funkcionalitātes korpusa prototipa galīgo elementu modeļa sagatavošanai un īpašību simulācijai.3.Rokasgrāmatu.Projekts ir rūpniecisks starpnozaru pētījums, kam nav ekonomiska rakstura un tas atbilst sekojošām zinātnes nozarēm (pēc OECD zinātņu nozaru FOS klasifikācijas) 2. Inženierija un Tehnoloģija apakšnozares: 2.3. Mehāniskas inženierija; 2.5. Materiālu inženierija; 2.10. Nanotehnoloģija.Projektā ir plānotas sekojošās darbības: Tehniskā specifikācija; Tehnoloģija; 3D nanokompozītu raksturojums; Īpašību modelēšana; Risinājumu instrumenta izstrāde; Rezultātu izplātīšana un sabiedrības iesaistīšanās. Sagaidāmie rezultāti: 1. Zināšanu datu bāze, kas satur informāciju par dažādu drukāto materiālu fizikālajām un mehāniskajām īpašībām.2. Risinājuma rīks – instrumentu kopums ar 3D drukas tehnoloģiju izgatavotu elektrovadošu izstrādājumu optimālai projektēšanai un praktiskās informācijas sistematizēts kopums, kas ir balstīts uz zinātnisko pētījumu rezultātiem, kas apraksta viedo polimēru kompozītmateriālu struktūru izgatavošanas vadlīnijas.3. Oriģināli zinātniski raksti balstītie uz projekta laikā iegūtiem rezultātiem, kas būs iesniegti publicēšanai.Projekts būs īstenots sadarbībā ar partneri RITEC SIA un BALTIC SCIENTIFIC INSTRUMENTS SIA. Latvijas Ķīmijas un Farmācijas uzņēmēju asociācija apliecina savu viedokli par projekta nozīmīgumu ar Atzinumu. Kopējās projekta izmaksas: 645 000,00 EUR, publiskā finansējuma apjoms – 596625,00 EUR (92,5%), līdzfinansējums – 48375,00 EUR (7,5%). Plānotais projekta īstenošanas ilgums: 36 mēneši (01.07.2020.-30.06.2023).Projektā iesaistīto zinātnisko darbinieku noslodze pilna laika ekvivalenta izteiksmē (PLE) projekta īstenošanas periodā sastādīs 5.55 PLE, no kuriem ne mazāk kā 26.1% no visas projekta īstenošanas personāla būs studenti un zinātniskā grāda pretendenti (1.45 PLE), jaunie zinātnieki 27.0% (1.50 PLE), kas projekta ietvaros pilnveidos kompetenci, ieskaitot karjeras izaugsmi un personāla atjaunotnes procesus. Projekta īstenošanas laikā uz 0.5PLE slodzi tiks iesaistīts jaunais pētnieks. (Latvian)
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Keywords: Adhesive manufacturing, Smart functionality, Composite, Nanomodified plastic. The code for the statistical classification of the economic activities of the project (NACE Rev. 2), according to the expected results of the project and the objective pursued, shall be: NACE2 # "22.2. Plastics production"adivity manufacturing (AR) technology allows manufacturers to produce smart composite structures with additional functionalities, e.g. deformation detection; Active heating and de-icing process; Improved passive cooling; Electrostatic discharge; Electromagnetic radiation shielding, etc. A 3D printer with a double nozzle provides object printing with two materials (isolator and conductive nanoparticle-filled plastic), where a network of 3D conductive tracks has been introduced purposefully. The overall objective of the project is to establish a science-based information platform for users using additive manufacturing (AR) for the production of nanomodified structures for industry 4.0. The established platform will allow creating a smart multifunctional product with optimal design and assessing its durability, thus increasing the product’s efficiency. The specific objective of the project is to demonstrate the Solution Tool (RR) for the production of smart polymer nanocomposite structures using additive manufacturing. RI will include:1.a material database with physical and mechanical properties of materials used for simulation; 2.simulation Module:2.1.application with thermoplastic cord melting technology (Fused deposition Modelling, FDM) for the preparation of final element models of products manufactured by the simulation and simulation of physical and mechanical properties taking into account the printing parameters and microstructure of the printed material using open source and/or proprietary final element software (e.g. software for physical and mechanical properties (e.g. CalAS) and microstructure of the printed material using open source and/or patented final elements software (e.g., CalAS) Code; 2.2.applications for preparation of final element models and simulation/optimisation of physical and mechanical properties for products with built-in electrical conductive tracks; 2.3. advanced functionality of applications for preparation of the final elements of the body prototype and simulation of properties.3. The guide.The project is an industrial cross-sector study that is not economic in nature and it corresponds to the following fields of science (according to the OECD FOS classification of scientific disciplines) 2. Engineering and Technology subsectors: 2.3. Mechanical engineering; 2.5. Material engineering; 2.10. Nanotechnology.The project includes the following activities: The technical specification; Technology; Characterisation of 3D nanocomposites; Modelling properties; Development of a solution tool; Dissemination of results and public engagement. Expected results: 1. A knowledge database containing information on the physical and mechanical properties of the various printed materials.2. Solution tool – a set of tools for optimal design of electrical conductive products made with 3D printing technology and systematised set of practical information based on scientific research results describing guidelines for manufacturing of intelligent polymer composite materials.3. Original scientific articles based on results obtained during the project, which will be submitted for publication.The project will be implemented in cooperation with partner RITEC SIA and BALTIC Scientific INSTRUMENTS SIA. The Latvian Association of Chemical and Pharmaceutical Entrepreneurs confirms its opinion on the importance of the project with the Opinion. Total cost of the project: EUR 645000.00, public funding amount – EUR 596625.00 (92.5 %), co-financing – EUR 48375.00 (7.5 %). Planned duration of the project: 36 months (01.07.2020.-30.06.2023).The workload of the scientific staff involved in the project in full-time equivalent terms (FTE) during the project implementation period will be 5.55 FLE, of which not less than 26.1 % of the total project staff will be students and candidates (1.45 PLE), young scientists 27.0 % (1.50 PLE), who will improve competence within the project, including career development and personnel renewal processes. During the implementation of the project, the new researcher will be involved in the workload of 0.5 FTE. (English)
15 July 2021
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Jelgavas iela 3, Rīga, LV-1004
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Gustava Zemgala gatve 71A, Rīga, LV-1039
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Rāmuļu iela 3, Rīga, LV-1005
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Identifiers
1.1.1.1/19/A/031
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