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Open-source models for holistic building energy system design at scale

Buildings and cities are becoming increasingly integrated into the energy supply system, creating a need for transparent, trustworthy, and holistic information for potential prosumers. This project is building the foundation for easy-to-access and automate building energy models to support distributed decision making and the energy transition.

Background

The need to improve energy efficiency and manage supply in buildings and cities is a core aspect of many climate change mitigation and sustainability scenarios. Demand for prosumer technologies, such as solar photovoltaics (PV), batteries, and electric vehicles (EV), is growing rapidly. At the same time, electrified heating already places a large demand on the electricity grid, therefore guiding a diverse set of citizens towards the best technical, economic, and social solution for the energy system is a challenge.

There is a long history of research in urban building energy models (UBEM) and several closed- and open-source software packages have been developed. These tools are typically used by researchers, city planners and policymakers, whereas the ones actually taking decisions – the building owners – typically get their information through commercial channels where biases and information asymmetry can create sub-optimal outcomes.

Solar maps are a good example of a public facing information source, where users can see the potential of their roofs for solar PV generation without needing to go through a salesperson. The utility of solar maps was boosted by our recently concluded project , where the tools provide an analysis and specific recommendation with the same detail as a solar installer. Advances in data collection, geographic information systems, and machine learning make this possible, and this project aims to bring this same functionality to all aspects of building energy systems in support of prosumers contributing to the energy transition.

Aim and objectives

This project aims to democratize energy system design and empower building owners with trustworthy information for holistic analysis of sustainable technologies.

  • Identify the minimum viable dataset required to adopt and apply the proposed models
  • Build an integrated prosumer energy systems model which can automatically design and recommend a holistic solution considering demand and supply
  • Create an open-source code base that can be easily transferred to any municipality in Sweden

Project partners

rebase.energy, AIT Austrian Institute of Technology, Karlstads Energi, Karlstad Kommun

Funding is provided by the Swedish Energy Agency’s E2B2 program (project number P2022-00903).

Timeframe: January 2023 – December 2024

Publications

Coming soon

Contact person

Nelson Sommerfeldt
Nelson Sommerfeldt researcher
Sustainable Geothermal Energy for the Future: AI in ATES
Warm water systems, losses and Legionella
PARMENIDES – Plug & plAy EneRgy ManagEmeNt for hybriD Energy Storage
HYSTORE - Hybrid services from advanced thermal energy storage systems
Open-source models for holistic building energy system design at scale
Tank to Grave Management of new Low-GWP Refrigerants (Hantering av nya låg-GWP köldmedier från installation till destruktion)
Novel tool and guidelines for designing ground source heat pumps (GSHPs) in densely populated areas
Data driven lab for building energy systems
Long-term performance measurement of GSHP systems serving commercial, institutional and multi-family buildings
Open-source models for holistic building energy system design at scale
Control systems for hybrid solutions based on biomass fueled Stirling engines, solar and wind for rural electrification
Prosumer-Centric Communication for Solar PV Diffusion (completed)
Towards Sustainable (Fossil-free) Heating System in Small Residential Buildings
Solar energy and ground source heat pumps for Swedish multi-family housing (completed)
Solar photovoltaic systems in Swedish cooperative housing (completed)
Smart Control Strategies for Heat Pump Systems (completed)
Creating and Understanding Smart Innovation in Cities
Building heating solutions in China
Accelerating innovation in buildings
High-Resolution GIS District Heating Source-Load Mapping
Digitalization and IoT technologies for Heat Pump systems
Sustainable combined systems for heating of buildings (completed)
Cost- and Energy-Efficient Control Systems for Buildings
Situation of Opportunity in the Growth and Change of three Stockholm City Districts (completed)
Wuxi Sino-Swedish Eco-City Project (completed)
Smart Renovation Strategies for Sustainable Electrification
Future Secondary Fluids for indirect refrigeration systems
Smart Fault Detection and Diagnosis for Heat Pumps
Performance indicators for energy efficient supermarket buildings
Magnetic Refrigeration
High-Resolution GIS District Heating Source-Load Mapping
Smart Solar Hybrid Solutions for Sustainable European Buildings (completed)
Building state-of-the-art (SotA) supermarket: Putting theory into practice
Efficient utilization of industrial waste heat by low temperature heat driven power cycles – an integrated approach for Swedish Industry
Cooperation between Supermarkets and Real Estate Owners; Energy Efficiency and Business Models
Digitalization and IoT technologies for Heat Pump systems
Capacity control in Heat Pump systems
Alternative secondary fluids
Functional surface coatings for energy efficient heat pumps
Two-phase flow in flat channels
Two phase heat transfer & pressure drop with new environment friendly refrigerants in minichannels (completed)
Numerical Study on flow boiling in micro/mini channels (completed)
Distributed Cold Storages in District Cooling
Integrating Latent Heat Storage into Residential Heating Systems
Simulation of temperature distribution in borehole thermal storages supported by fiber optic temperature measurements (completed)
Solar energy and ground source heat pumps for Swedish multi-family housing (completed)
Neutrons for Heat Storage, NHS, (completed)
4D Monitoring of BTES (completed)
Aquifer Thermal Energy Storage (completed)
Deep Borehole Heat Exchanger (completed)
Combined Heat and Power plants in combination with borehole thermal energy storage (completed)
Improved borehole technology for Geothermal Heat Pumps development (completed)
Compact Minichannel Latent Energy Storage for Air Related Cold Storage Applications
Building heating solutions in China
Toward Sustainable (Fossil-free) Heating System in Small Residential Buildings
Renewable Energy Park, RE-Park (completed)
Efficient use of energy wells for heat pumps (completed)
Efficient design of geothermal heating systems (completed)
SPF (completed)