New consumer awareness is shifting industry towards more sustainable practices, creating a virtuous cycle between producers and consumers enabled by eco-labelling. Eco-labelling informs consumers of specific characteristics of products and has been used to market greener products. Eco-labelling in the food industry has yet been mostly focused on promoting organic farming, limiting the scope to the agricultural stage of the supply chain, while carbon labelling informs on the carbon footprint throughout the life cycle of the product. These labelling strategies help value products in the eyes of the consumer. Because of this, decision makers are motivated to adopt more sustainable models. In the food industry, this has led to important environmental impact improvements at the agricultural stage, while most other stages in the Food Supply Chain (FSC) have continued to be designed inefficiently. The objective of this work is to define a framework showing how carbon labelling can be integrated into the design process of the FSC. For this purpose, the concept of Green Supply Chain Network Design (GSCND) focusing on the strategic decision making for location and allocation of resources and production capacity is developed considering operational, financial and environmental (CO2 emissions) issues along key stages in the product life cycle. A multi-objective optimization strategy implemented by use of a genetic algorithm is applied to a case study on orange juice production. The results show that the consideration of CO2 emission minimization as an objective function during the GSCND process together with techno-economic criteria produces improved FSC environmental performance compared to both organic and conventional orange juice production. Typical results thus highlight the importance that carbon emissions optimization and labelling may have to improve FSC beyond organic labelling. Finally, CO2 emission-oriented labelling could be an important tool to improve the effects eco-labelling has on food product environmental impact going forward.
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Design educators and industry partners are critical knowledge managers and co-drivers of change, and design graduate and post-graduate students can act as catalysts for new ideas, energy, and perspectives. In this article, we will explore how design advances industry development through the lens of a longitudinal inquiry into activities carried out as part of a Dutch design faculty-industry collaboration. We analyze seventy-five (75) Master of Science (MSc) thesis outcomes and seven (7) Doctorate (PhD) thesis outcomes (five in progress) to identify ways that design activities have influenced advances in the Dutch aviation industry over time. Based on these findings, we then introduce an Industry Design Framework, which organizes the industry/design relationship as a three-layered system. This novel approach to engaging industry in design research and design education has immediate practical value and theoretical significance, both in the present and for future research. https://doi.org/10.1016/j.sheji.2019.07.003 LinkedIn: https://www.linkedin.com/in/christine-de-lille-8039372/
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Size measurement plays an essential role for micro-/nanoparticle characterization and property evaluation. Due to high costs, complex operation or resolution limit, conventional characterization techniques cannot satisfy the growing demand of routine size measurements in various industry sectors and research departments, e.g., pharmaceuticals, nanomaterials and food industry etc. Together with start-up SeeNano and other partners, we will develop a portable compact device to measure particle size based on particle-impact electrochemical sensing technology. The main task in this project is to extend the measurement range for particles with diameters ranging from 20 nm to 20 um and to validate this technology with realistic samples from various application areas. In this project a new electrode chip will be designed and fabricated. It will result in a workable prototype including new UMEs (ultra-micro electrode), showing that particle sizing can be achieved on a compact portable device with full measuring range. Following experimental testing with calibrated particles, a reliable calibration model will be built up for full range measurement. In a further step, samples from partners or potential customers will be tested on the device to evaluate the application feasibility. The results will be validated by high-resolution and mainstream sizing techniques such as scanning electron microscopy (SEM), dynamic light scattering (DLS) and Coulter counter.
By transitioning from a fossil-based economy to a circular and bio-based economy, the industry has an opportunity to reduce its overall CO2 emission. Necessary conditions for effective and significant reductions of CO2-emissions are that effective processing routes are developed that make the available carbon in the renewable sources accessible at an acceptable price and in process chains that produce valuable products that may replace fossil based products. To match the growing industrial carbon demand with sufficient carbon sources, all available circular, and renewable feedstock sources must be considered. A major challenge for greening chemistry is to find suitable sustainable carbon that is not fossil (petroleum, natural gas, coal), but also does not compete with the food or feed demand. Therefore, in this proposal, we omit the use of first generation substrates such as sugary crops (sugar beets), or starch-containing biomasses (maize, cereals).
In de automotive sector vindt veel onderzoek en ontwikkeling plaats op het gebied van autonome voertuigtechnologie. Dit resulteert in rijke open source software oplossingen voor besturing van robotvoertuigen. HAN heeft met haar Streetdrone voertuig reeds goede praktijkervaring met dergelijke software. Deze oplossingen richten zich op een Operational Design Domain dat uitgaat van de publieke verkeersinfrastructuur met daarbij de weggebruikers rondom het robotvoertuig. In de sectoren agrifood en smart industry is een groeiende behoefte aan automatisering van mobiele machinerie, versterkt door de actuele coronacrisis. Veel functionaliteit van bovengenoemde automotive software is inzetbaar voor mobiele robotica in deze sectoren. De toepassingen zijn enerzijds minder veeleisend - denk aan de meer gestructureerde omgeving, lagere snelheden en minder of geen ‘overige weggebruikers’ – en anderzijds heel specifiek als het gaat over routeplanning en (indoor) lokalisatie. Vanwege dit specifiek karakter is de bestaande software niet direct inzetbaar in deze sectoren. Het MKB in deze sectoren ervaart daarom een grote uitdaging om dergelijke complexe autonome functionaliteit beschikbaar te maken, zonder dat men kan voorbouwen een open, sectorspecifieke softwareoplossing. In Automotion willen de aangesloten partners vanuit bestaande kennis en ervaring tot een eerste integratie en demonstratie komen van een beschikbare automotive open source softwarebibliotheek, aangepast en specifiek ingezet op rijdende robots voor agrifood en smart industry, met focus ‘pickup and delivery’ scenario’s. Hierbij worden de aanpassingen - nieuwe en herschreven ‘boeken’ in de ‘bibliotheek’ - weer in open source gepubliceerd ter versterking van het MKB en het onderwijs. Parallel hieraan willen de partners ontdekken welke praktijkvragen uit dit proces voortvloeien en welke onderliggende kennislacunes in de toekomst moeten worden ingevuld. Via open workshops met uitnodigingen in diverse netwerken worden vele partijen uitgenodigd om gezamenlijk aan de hand van de opgedane ervaringen van gedachten te wisselen over actuele kennisvragen en mogelijke gezamenlijke toekomstige beantwoording daarvan.
Lectoraat, onderdeel van NHL Stenden Hogeschool
