Het platform voor open praktijkgericht onderzoek

Producten 82

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Robotic Platform Research PP presentation

Greenhouses are in need of new monitoring tools, as they size grow bigger and bigger but still using old labour intensive methods ways of caring for the crop. HiPerGreen is set out to create a new tool, which can drive onto the pre-existing heating pipes to provide a birds eye perspective for image analysis purposes. However, clear images are necessary for consistent usable data. This presentation resumes the steps taken during the reporting: the optimisation of a rail based system towards clear images. This is done through analysis of resulting images, understanding vibrations and oscillations, and finally presents results based on prototyping. Moreover, a re-design of the electronics and hardware was also introduce to facilitate prototyping. The results are promising, laying within the requirements.

DOCUMENT

Robotic Platform Research PP presentation

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Towards Climate Resilient Freight Transport in Europe

Abstract: Climate change is related with weather extremes, which may cause damages to infrastructure used by freight transport services. Heavy rainfall may lead to flooding and damage to railway lines, roads and inland waterways. Extreme drought may lead to extremely low water levels, which prevent safe navigation by inland barges. Wet and dry periods may alternate, leaving little time to repair damages. In some Western and Middle-European countries, barges have a large share in freight transport. If a main waterway is out of service, then alternatives are called for. Volume- and price-wise, trucking is not a viable alternative. Could railways be that alternative? The paper was written after the unusually long dry summer period in Europe in 2022. It deals with the question: If the Rhine, a major European waterway becomes locally inaccessible, could railways (temporarily) play a larger role in freight transport? It is a continuation of our earlier research. It contains a case study, the data of which was fed into a simulation model. The model deals with technical details like service specification route length, energy consumption and emissions. The study points to interesting rail services to keep Europe’s freight on the move. Their realization may be complex especially in terms of logistics and infrastructure, but is there an alternative?

MULTIFILE

Towards Climate Resilient Freight Transport in Europe

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Digital Sustainability Practices: a Research Agenda

Expectations are high for digital technologies to address sustainability related challenges. While research into such applications and the twin transformation is growing rapidly, insights in the actual daily practices of digital sustainability within organizations is lacking. This is problematic as the contributions of digital tools to sustainability goals gain shape in organizational practices. To bridge this gap, we develop a theoretical perspective on digital sustainability practices based on practice theory, with an emphasis on the concept of sociomateriality. We argue that connecting meanings related to sustainability with digital technologies is essential to establish beneficial practices. Next, we contend that the meaning of sustainability is contextspecific, which calls for a local meaning making process. Based on our theoretical exploration we develop an empirical research agenda.

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Digital Sustainability Practices: a Research Agenda

Personen 1

persoon

Gerard Schepers

Professor

Projecten 8

project

CARB-HUB: Climate-Adaptive Resilient and Balanced Mobility Hubs

The Dutch Environmental Vision and Mobility Vision 2050 promote climate-neutral urban growth around public transport stations, envisioning them as vibrant hubs for mobility, community, and economy. However, redevelopment often increases construction, a major CO₂ contributor. Dutch practice-led projects like 'Carbon Based Urbanism', 'MooiNL - Practical guide to urban node development', and 'Paris Proof Stations' explore integrating spatial and environmental requirements through design. Design Professionals seek collaborative methods and tools to better understand how can carbon knowledge and skills be effectively integrated into station area development projects, in architecture and urban design approaches. Redeveloping mobility hubs requires multi-stakeholder negotiations involving city planners, developers, and railway managers. Designers act as facilitators of the process, enabling urban and decarbonization transitions. CARB-HUB explores how co-creation methods can help spatial design processes balance mobility, attractiveness, and carbon neutrality across multiple stakeholders. The key outputs are: 1- Serious Game for Co-Creation, which introduces an assessment method for evaluating the potential of station locations, referred to as the 4P value framework. 2-Design Toolkit for Decarbonization, featuring a set of Key Performance Indicators (KPIs) to guide sustainable development. 3- Research Bid for the DUT–Driving Urban Transitions Program, focusing on the 15-minute City Transition Pathway. 4- Collaborative Network dedicated to promoting a low-carbon design approach. The 4P value framework offers a comprehensive method for assessing the redevelopment potential of station areas, focusing on four key dimensions: People, which considers user experience and accessibility; Position, which examines the station's role within the broader transport network; Place-making, which looks at how well the station integrates into its surrounding urban environment; and Planet, which addresses decarbonization and climate adaptation. CARB-HUB uses real cases of Dutch stations in transition as testbeds. By translating abstract environmental goals into tangible spatial solutions, CARB-HUB enables scenario-based planning, engaging designers, policymakers, infrastructure managers, and environmental advocates.

In voorbereiding

project

CHANGE

To reach the European Green Deal by 2050, the target for the road transport sector is set at 30% less CO2 emissions by 2030. Given the fact that heavy-duty commercial vehicles throughout Europe are driven nowadays almost exclusively on fossil fuels it is obvious that transition towards reduced emission targets needs to happen seamlessly by hybridization of the existing fleet, with a continuously increasing share of Zero Emission vehicle units. At present, trailing units such as semitrailers do not possess any form of powertrain, being a missed opportunity. By introduction of electrically driven axles into these units the fuel consumption as well as amount of emissions may be reduced substantially while part of the propulsion forces is being supplied on emission-free basis. Furthermore, the electrification of trailing units enables partial recuperation of kinetic energy while braking. Nevertheless, a number of challenges still exist preventing swift integration of these vehicles to daily operation. One of the dominating ones is the intelligent control of the e-axle so it delivers right amount of propulsion/braking power at the right time without receiving detailed information from the towing vehicle (such as e.g. driver control, engine speed, engine torque, or brake pressure, …etc.). This is required mainly to ensure interoperability of e-Trailers in the fleets, which is a must in the logistics nowadays. Therefore the main mission of CHANGE is to generate a chain of knowledge in developing and implementing data driven AI-based applications enabling SMEs of the Dutch trailer industry to contribute to seamless energetic transition towards zero emission road freight transport. In specific, CHANGE will employ e-Trailers (trailers with electrically driven axle(s) enabling energy recuperation) connected to conventional hauling units as well as trailers for high volume and extreme payload as focal platforms (demonstrators) for deployment of these applications.

Lopend

project

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Road freight transport contributes to 75% of the global logistics CO2 emissions. Various European initiatives are calling for a drastic cut-down of CO2 emissions in this sector [1]. This requires advanced and very expensive technological innovations; i.e. re-design of vehicle units, hybridization of powertrains and autonomous vehicle technology. One particular innovation that aims to solve this problem is multi-articulated vehicles (road-trains). They have a smaller footprint and better efficiency of transport than traditional transport vehicles like trucks. In line with the missions for Energy Transition and Sustainability [2], road-trains can have zero-emission powertrains leading to clean and sustainable urban mobility of people and goods. However, multiple articulations in a vehicle pose a problem of reversing the vehicle. Since it is extremely difficult to predict the sideways movement of the vehicle combination while reversing, no driver can master this process. This is also the problem faced by the drivers of TRENS Solar Train’s vehicle, which is a multi-articulated modular electric road vehicle. It can be used for transporting cargo as well as passengers in tight environments, making it suitable for operation in urban areas. This project aims to develop a reverse assist system to help drivers reverse multi-articulated vehicles like the TRENS Solar Train, enabling them to maneuver backward when the need arises in its operations, safely and predictably. This will subsequently provide multi-articulated vehicle users with a sustainable and economically viable option for the transport of cargo and passengers with unrestricted maneuverability resulting in better application and adding to the innovation in sustainable road transport.

Afgerond

project

Hold your breath: Tracking the footprint of an invisible killer - air pollution in the port city of Rotterdam

The reclaiming of street spaces for pedestrians during the COVID-19 pandemic, such as on Witte de Withstraat in Rotterdam, appears to have multiple benefits: It allows people to escape the potentially infected indoor air, limits accessibility for cars and reduces emissions. Before ordering their coffee or food, people may want to check one of the many wind and weather apps, such as windy.com: These apps display the air quality at any given time, including, for example, the amount of nitrogen dioxide (NO2), a gas responsible for an increasing number of health issues, particularly respiratory and cardiovascular diseases. Ships and heavy industry in the nearby Port of Rotterdam, Europe’s largest seaport, exacerbate air pollution in the region. Not surprisingly, in 2020 Rotterdam was ranked as one of the unhealthiest cities in the Netherlands, according to research on the health of cities conducted by Arcadis. Reducing air pollution is a key target for the Port Authority and the City of Rotterdam. Missing, however, is widespread awareness among citizens about how air pollution links to socio-spatial development, and thus to the future of the port city cluster of Rotterdam. To encourage awareness and counter the problem of "out of sight - out of mind," filmmaker Entrop&DeZwartFIlms together with ONSTV/NostalgieNet, and Rotterdam Veldakademie, are collaborating with historians of the built environment and computer science and public health from TU Delft and Erasmus University working on a spatial data platform to visualize air pollution dynamics and socio-economic datasets in the Rotterdam region. Following discussion of findings with key stakeholders, we will make a pilot TV-documentary. The documentary, discussed first with Rotterdam citizens, will set the stage for more documentaries on European and international cities, focusing on the health effects—positive and negative—of living and working near ports in the past, present, and future.

Afgerond

project

TRAILS: TRacking Ameland Inlet Living Lab Sediment - Novel tools to assess ecosystem and societal responses to nature-based coastal management

Nature-based coastal management is mainstream in the Netherlands. About 12 Mm3 of sand is added annually to the coast to compensate coastal erosion and maintain high safety levels against flooding. This amount will likely increase to compensate for accelerated sea level rise. (Mega-)Nourishments may also strengthen and support biodiversity and recreational values of the coastal zone and associated wetland areas. However, the ecological and societal impacts of mega-nourishments on open coasts are not well established, hampering comparison of pros and cons of different nourishment strategies. This knowledge gap is largely due to the lack of suitable methods to monitor and predict the spreading of nourishment sand along the coast and into tidal basins. Ameland Inlet provides us with a unique opportunity to develop and test novel approaches to fill this knowledge gap in close collaboration with our consortium and stakeholders. In 2018 the first tidal inlet mega-nourishment (5 Mm3) was placed in the Ameland Inlet ebb-tidal delta, and geomorphic and biotic responses nearby are closely monitored in the Kustgenese 2.0 and SEAWAD programmes. Our research builds on the insights gained, will gather new data to investigate off-site effects (linked with SIBES/SIBUS sampling), and build a common knowledge-base with stakeholders. We will develop novel luminescence-based methods to monitor the temporal and spatial dispersal of nourishment sand. These insights will be combined with an inventory of off-site biotic responses to nourishment and the role biota play in the mixing of nourishment sand with natural sediments. Combined results will be used to develop and validate models to trace transport paths of individual grains and improve morphodynamic predictions. Throughout the project, we will collaborate and interact intensely with coastal managers and (local) stakeholders to address concerns and exchange insights, creating a platform for co-assessment and optimization of nourishment designs and strategies.

Lopend

project

Trenergy: Trailer Design Assessment for optimizing energy consumption

To meet the European Green Deal, new CO2 emission standards for Heavy-Duty-Vehicles (HDV) have been set. The amended Regulation EU-2019/1242 has a wider scope, covering not only lorries but also trailers. From 2030 on (semi-)trailers must reduce their emissions by 10%, even though trailers generally do not emit any CO2-emissions. But how can a trailer save CO2? To calculate emissions, the European Commission has developed VECTO, the Vehicle Energy Consumption Calculation TOol. It is a standardized framework designed to determine fuel consumption and CO2-emissions of HDVs. Analysis show that the two main focus points for CO2 reduction, based on VECTO, are weight reduction and improved aerodynamics. However, equipping trailers with aerodynamic devices or making them lighter isn’t straightforward. Trailers lead a rough life and the industry is adapted to the current trailer designs. Lightweight constructions might harm the lifetime of a trailer and trailers with protruding aerodynamic parts won’t fit on a train anymore. Besides, both solutions have a major influence on the vehicle (roll-over) stability and therefore safety. It is not that evident for a trailer manufacturer to design a (new) trailer that 1) fulfills the CO2 regulations, 2) complies with the constructional requirements and 3) remains safe and stable. This 3-step-approach is really missing for trailer manufacturers, and this is endorsed by Burgers Carrosserie: “How can we validate (upfront) that the trailer is still as “strong” and “safe” if we apply the weight reduction that shows sufficient CO2 saving in VECTO?”. The answer was simple, it isn’t. It is the aim of Trenergy to develop this 3-step approach with complementary simulation tools, where trailer manufacturers can validate their design(s) for CO2 Savings, Construction and Safety. It is intended to make the developed models/tools open source for the Logistic Industry.

Lopend

Producten 82

product

Robotic Platform Research PP presentation

DOCUMENT

product

Towards Climate Resilient Freight Transport in Europe

MULTIFILE

product

Digital Sustainability Practices: a Research Agenda

MULTIFILE

Personen 1

persoon

Gerard Schepers

Professor

Projecten 8

project

CARB-HUB: Climate-Adaptive Resilient and Balanced Mobility Hubs

In voorbereiding

project

CHANGE

Lopend

project

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Afgerond

project

Hold your breath: Tracking the footprint of an invisible killer - air pollution in the port city of Rotterdam

Afgerond

project

TRAILS: TRacking Ameland Inlet Living Lab Sediment - Novel tools to assess ecosystem and societal responses to nature-based coastal management

Lopend

project

Trenergy: Trailer Design Assessment for optimizing energy consumption

Lopend

Zoekresultaten

Producten 82

Robotic Platform Research PP presentation

Towards Climate Resilient Freight Transport in Europe

Digital Sustainability Practices: a Research Agenda

HiPerGreen newsletter 4

A Multiagent System for Monitoring Health

Designing for dementia

Improving User’s Confidence to Act When Using Advice Algorithms Through Interactive Use of Counterfactuals

Development of health impact assessment in the Netherlands

Enhancing process model visualisation to facilitate the understanding of stakeholders

Personen 1

Gerard Schepers

Projecten 8

CARB-HUB: Climate-Adaptive Resilient and Balanced Mobility Hubs

CHANGE

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Hold your breath: Tracking the footprint of an invisible killer - air pollution in the port city of Rotterdam

Mobi Dick

TRAILS: TRacking Ameland Inlet Living Lab Sediment - Novel tools to assess ecosystem and societal responses to nature-based coastal management

Trenergy: Trailer Design Assessment for optimizing energy consumption

WALK-IN (acronym): Widening sustAinable mobiLity networKs: Impact on Nodes

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Producten 82

Robotic Platform Research PP presentation

Towards Climate Resilient Freight Transport in Europe

Digital Sustainability Practices: a Research Agenda

HiPerGreen newsletter 4

A Multiagent System for Monitoring Health

Designing for dementia

Improving User’s Confidence to Act When Using Advice Algorithms Through Interactive Use of Counterfactuals

Development of health impact assessment in the Netherlands

Enhancing process model visualisation to facilitate the understanding of stakeholders

Personen 1

Gerard Schepers

Projecten 8

CARB-HUB: Climate-Adaptive Resilient and Balanced Mobility Hubs

CHANGE

Enable MULti-ArticulaTed vehicle rEversing (EMULATE)

Hold your breath: Tracking the footprint of an invisible killer - air pollution in the port city of Rotterdam

Mobi Dick

TRAILS: TRacking Ameland Inlet Living Lab Sediment - Novel tools to assess ecosystem and societal responses to nature-based coastal management

Trenergy: Trailer Design Assessment for optimizing energy consumption

WALK-IN (acronym): Widening sustAinable mobiLity networKs: Impact on Nodes