Simulation of demand response on buildings and district heating production

被引：1

作者：

Ju, Yuchen ^{[1
,2
]}

Lindholm, Joakim ^{[1
]}

Verbeck, Moritz ^{[3
,4
]}

Jokisalo, Juha ^{[1
,2
]}

Kosonen, Risto ^{[1
,2
,5
]}

Janssenc, Philipp ^{[3
,4
]}

Li, Yantong ^{[6
]}

Schaefers, Hans ^{[3
,4
]}

Nord, Natasa ^{[6
]}

机构：

[1] Aalto Univ, Dept Mech Engn, Espoo, Finland

[2] TalTech, FinEst Ctr Smart Cities, Tallinn, Estonia

[3] Hamburg Univ Appl Sci, Dept Environm Engn, Hamburg, Germany

[4] Competence Ctr Renewable Energy & Energy Efficien, Hamburg, Germany

[5] Nanjing Tech Univ, Coll Urban Construct, Nanjing, Peoples R China

[6] Norwegian Univ Sci & Technol, Dept Energy & Proc Engn, Trondheim, Norway

来源：

BUILDSIM NORDIC 2022 | 2022年 / 362卷

关键词：

ENERGY FLEXIBILITY; STORAGE; SYSTEMS; MASS;

D O I：

10.1051/e3sconf/202236213002

中图分类号：

TU [建筑科学];

学科分类号：

0813 ;

摘要：

Demand response (DR) has effectively maximized renewable energies integrated into energy supply systems. This paper investigated DR benefits on three building types and the district heating (DH) production of a community consisted by these buildings in German conditions. Firstly, the buildings and the DH production were simulated without DR by tools IDA-ICE and HGSO, separately. Secondly, the three buildings were simulated by a rule-based DR control. After that, the tool HGSO calculated the total production costs and CO2 emissions based on the power demand with DR. The results show 2.8%-4.8% heating cost savings by DR for different building types. For DH producers, DR application reduces the total DH demand and CO2 emissions by 3.8% and 32.3 %, respectively.

引用

页数：7

共 50 条

[41] Results of a literature review on methods for estimating buildings energy demand at district level
Ferrari, Simone
Zagarella, Federica
Caputo, Paola
D'Amico, Antonino
ENERGY, 2019, 175 : 1130 - 1137
[42] Holistic Operational Signatures for an energy-efficient district heating substation in buildings
Hong, Yejin
Yoon, Sungmin
ENERGY, 2022, 250
[43] Would employees accept curtailments in heating and air conditioning, and why? An empirical investigation of demand response potential in office buildings
Sloot, Daniel
Lehmann, Nico
Ardone, Armin
ENERGY POLICY, 2023, 181
[44] Storage influence in a combined biomass and power-to-heat district heating production plant
Lamaison, Nicolas
Collette, Simon
Vallee, Mathieu
Baviere, Roland
ENERGY, 2019, 186
[45] Geospatial Analysis of the Building Heat Demand and Distribution Losses in a District Heating Network
Toernros, Tobias
Resch, Bernd
Rupp, Matthias
Guendra, Hartmut
ISPRS INTERNATIONAL JOURNAL OF GEO-INFORMATION, 2016, 5 (12):
[46] Strengths, weaknesses, opportunities and threats of demand response in district heating and cooling systems. From passive customers to valuable assets
Marszal-Pomianowska, Anna
Motoasca, Emilia
Pothof, Ivo
Felsmann, Clemens
Heiselberg, Per
Cadenbach, Anna
Leusbrock, Ingo
'Donovan, Keith
Petersen, Steffen
Schaffer, Markus
SMART ENERGY, 2024, 14
[47] Integrated demand response in district electricity-heating network considering double auction retail energy market based on demand-side energy stations
Wang, Dan
Hu, Qing'e
Jia, Hongjie
Hou, Kai
Du, Wei
Chen, Ning
Wang, Xudong
Fan, Menghua
APPLIED ENERGY, 2019, 248 : 656 - 678
[48] Quantifying flexibility potential on district heating local thermal substations
Zouloumis, Leonidas
Ploskas, Nikolaos
Panaras, Giorgos
SUSTAINABLE ENERGY GRIDS & NETWORKS, 2023, 35
[49] Utilization of District Heating Networks to Provide Flexibility in CHP Production
Korpela, Timo
Kaivosoja, Jyri
Majanne, Yrjo
Laakkonen, Leo
Nurmoranta, Maria
Vilkko, Matti
15TH INTERNATIONAL SYMPOSIUM ON DISTRICT HEATING AND COOLING (DHC15-2016), 2017, 116 : 310 - 319
[50] RESIDENTIAL DOMESTIC HOT WATER CONSUMPTION ANALYSIS FOR MULTIFAMILY BUILDINGS SUPPLIED BY DISTRICT HEATING
Vamos, Viktoria
Horvath, Miklos
THERMAL SCIENCE, 2022, 26 (02): : 1267 - 1276

← 1 2 3 4 5 →