Saved in:
Bibliographic Details
Main Authors: Malacek, Simon, Portela, José, Werner, Yannick Marcus, Wogrin, Sonja
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.05427
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910934264446976
author Malacek, Simon
Portela, José
Werner, Yannick Marcus
Wogrin, Sonja
author_facet Malacek, Simon
Portela, José
Werner, Yannick Marcus
Wogrin, Sonja
contents Despite various efforts, decarbonizing the heating sector remains a significant challenge. To tackle it by smart planning, the availability of highly resolved heating demand data is key. Several existing models provide heating demand only for specific applications. Typically, they either offer time series for a larger area or annual demand data on a building level, but not both simultaneously. Additionally, the diversity in heating demand across different buildings is often not considered. To address these limitations, this paper presents a novel method for generating temporally resolved heat demand time series at the building level using publicly available data. The approach integrates a thermal building model with stochastic occupancy simulations that account for variability in user behavior. As a result, the tool serves as a cost-effective resource for cross-sectoral energy system planning and policy development, particularly with a focus on the heating sector. The obtained data can be used to assess the impact of renovation and retrofitting strategies, or to analyze district heating expansion. To illustrate the potential applications of this approach, we conducted a case study in Puertollano (Spain), where we prepared a dataset of heating demand with hourly resolution for each of 9,298 residential buildings. This data was then used to compare two different pathways for the thermal renovation of these buildings. By relying on publicly available data, this method can be adapted and applied to various European regions, offering broad usability in energy system optimization and analysis of decarbonization strategies.
format Preprint
id arxiv_https___arxiv_org_abs_2503_05427
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Generating Building-Level Heat Demand Time Series by Combining Occupancy Simulations and Thermal Modeling
Malacek, Simon
Portela, José
Werner, Yannick Marcus
Wogrin, Sonja
Systems and Control
Despite various efforts, decarbonizing the heating sector remains a significant challenge. To tackle it by smart planning, the availability of highly resolved heating demand data is key. Several existing models provide heating demand only for specific applications. Typically, they either offer time series for a larger area or annual demand data on a building level, but not both simultaneously. Additionally, the diversity in heating demand across different buildings is often not considered. To address these limitations, this paper presents a novel method for generating temporally resolved heat demand time series at the building level using publicly available data. The approach integrates a thermal building model with stochastic occupancy simulations that account for variability in user behavior. As a result, the tool serves as a cost-effective resource for cross-sectoral energy system planning and policy development, particularly with a focus on the heating sector. The obtained data can be used to assess the impact of renovation and retrofitting strategies, or to analyze district heating expansion. To illustrate the potential applications of this approach, we conducted a case study in Puertollano (Spain), where we prepared a dataset of heating demand with hourly resolution for each of 9,298 residential buildings. This data was then used to compare two different pathways for the thermal renovation of these buildings. By relying on publicly available data, this method can be adapted and applied to various European regions, offering broad usability in energy system optimization and analysis of decarbonization strategies.
title Generating Building-Level Heat Demand Time Series by Combining Occupancy Simulations and Thermal Modeling
topic Systems and Control
url https://arxiv.org/abs/2503.05427