Can a smart greenhouse be integrated into a microgrid for sustainable agriculture?This approach offers an effective solution for achieving near-zero energy consumption in sustainable agriculture, with scalability for various greenhouse types and sizes. This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
How are smart grids transforming Switzerland's electricity network?The growing amount of decentralised electricity production combined with the need to increase energy efficiency in Switzerland is creating new challenges for the electricity network. Smart grids are helping to meet these challenges.
Can a smart greenhouse optimize energy and microclimate management for sustainable agriculture?Abstract: This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
What are the benefits of smart grids & control systems?For example, intelligent control systems can regulate fluctuating electricity production from renewable energy sources, as well as electricity consumption. Smart grids ensure that systems and grids operate safely, efficiently and reliably and help to reduce the need to expand the electricity network.
Can SGIM achieve near-zero energy consumption in sustainable agriculture?Simulations revealed that the SGIM met over 83% of its energy needs through local generation, with only 3.8% sourced from the external grid. This approach offers an effective solution for achieving near-zero energy consumption in sustainable agriculture, with scalability for various greenhouse types and siz
To accelerate carbon management innovation, Switzerland has launched a call for tenders of technologies that can capture and store CO₂, aiming to store 500,000 tonnes of CO₂ by 2030. In January 2025, Switzerland
Our Smart Energy Management System tackles both issues. On one hand we maximise the end-user self consumption with our smartbox that has the capability to connect and control any
So a home can only be smart if the necessary infrastructure – the grid – can keep pace with digitalisation and the transformation of the energy system. You can find out how smart homes,
It has also drawn up both a smart grid strategy and a smart grid roadmap for Switzerland. This road map includes a schedule and sets out the available options for developing the electricity
To accelerate carbon management innovation, Switzerland has launched a call for tenders of technologies that can capture and store CO₂, aiming to store 500,000 tonnes of
A microgrid, regarded as one of the cornerstones of the future smart grid, uses distributed generations and information technology to create a widely distributed automated energy
This work relies on several interviews of Swiss stakeholders and a literature review that allowed us to identify value propositions and barriers to deployment of microgrids in the Swiss context.
So a home can only be smart if the necessary infrastructure – the grid – can keep pace with digitalisation and the transformation of the energy system. You can find out how
Here we evaluate a territorial net-zero carbon dioxide emissions energy scenario for Switzerland coupled with life cycle assessment to quantify non-domestic environmental burdens.
Intelligent grid components (smart grid) ensure that the energy balance remains balanced and that voltage stability is guaranteed in the microgrid. Various techniques such as demand-side management (DSM),
This work relies on several interviews of Swiss stakeholders and a literature review that allowed us to identify value propositions and barriers to deployment of microgrids in the
This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
Intelligent grid components (smart grid) ensure that the energy balance remains balanced and that voltage stability is guaranteed in the microgrid. Various techniques such as demand-side
This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
The Swiss city of Zurich is implementing a net-zero neighbourhood in the Binz and Alt-Wiedikon area where residents and businesses can test new climate-friendly approaches.
This approach offers an effective solution for achieving near-zero energy consumption in sustainable agriculture, with scalability for various greenhouse types and sizes. This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
The growing amount of decentralised electricity production combined with the need to increase energy efficiency in Switzerland is creating new challenges for the electricity network. Smart grids are helping to meet these challenges.
Abstract: This paper presents a novel smart greenhouse integrated into a microgrid (SGIM) designed to optimize energy and microclimate management for sustainable agriculture.
For example, intelligent control systems can regulate fluctuating electricity production from renewable energy sources, as well as electricity consumption. Smart grids ensure that systems and grids operate safely, efficiently and reliably and help to reduce the need to expand the electricity network.
Simulations revealed that the SGIM met over 83% of its energy needs through local generation, with only 3.8% sourced from the external grid. This approach offers an effective solution for achieving near-zero energy consumption in sustainable agriculture, with scalability for various greenhouse types and sizes.
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