Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating

Mikel Lumbreras; Roberto Garay

doi:10.26868/25222708.2019.210282

Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating

Mikel Lumbreras, Roberto Garay

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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Abstract

This paper presents a theoretical simulation of thermal and economical assessment of façade integrated Solar Thermal (ST) in combination with Ultra Low Temperature (ULT) District-Heating (DH). This paper is in line with existing R&D activities for the integration of unglazed systems in building envelopes, where facades provide an almost unexplored area for increasing solaractivated building envelopes. The combination of building-integrated solar systems with DH networks avoids the use of local storage and allows a novel combination of heat directionality, both from building to the heat grid and vice versa. A control algorithm for heat supply is presented, so that the performance of the overall system is the optimal. Energetic results from solar simulations and economic assessment derived from the balance of building energy demand and solar production are presented. Over a fullyear period the proposed unglazed system produces as much as 50% additional heat when compared with an isolated ST system and profitable economic metrics are reached over a simulation time of 20 years. Finally, it is concluded the heat sink nature of a DH network, for as many as 25-35% of the buildings connected to the DH includes ST system.

Original language	English
Title of host publication	16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019
Editors	Vincenzo Corrado, Enrico Fabrizio, Andrea Gasparella, Francesco Patuzzi
Publisher	International Building Performance Simulation Association
Pages	4401-4408
Number of pages	8
Volume	16
ISBN (Electronic)	9781713809418
ISBN (Print)	978-171380941-8
DOIs	https://doi.org/10.26868/25222708.2019.210282
Publication status	Published - 2019
Event	16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019 - Rome, Italy Duration: 2 Sept 2019 → 4 Sept 2019

Publication series

Name	Building Simulation Conference Proceedings
Volume	7
ISSN (Print)	2522-2708

Conference

Conference	16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019
Country/Territory	Italy
City	Rome
Period	2/09/19 → 4/09/19

Keywords

Ultra Low Temperature
Solar Thermal
Façade
Building envelopes

Project and Funding Information

Project ID
info:eu-repo/grantAgreement/EC/H2020/768567/EU/REnewable Low TEmperature District/RELaTED
Funding Info
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 768567.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.26868/25222708.2019.210282

BS2019 210282 Final published version, 647 KB

Cite this

Lumbreras, M., & Garay, R. (2019). Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating. In V. Corrado, E. Fabrizio, A. Gasparella, & F. Patuzzi (Eds.), 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019 (Vol. 16, pp. 4401-4408). (Building Simulation Conference Proceedings; Vol. 7). International Building Performance Simulation Association. https://doi.org/10.26868/25222708.2019.210282

Lumbreras, Mikel ; Garay, Roberto. / Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating. 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019. editor / Vincenzo Corrado ; Enrico Fabrizio ; Andrea Gasparella ; Francesco Patuzzi. Vol. 16 International Building Performance Simulation Association, 2019. pp. 4401-4408 (Building Simulation Conference Proceedings).

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abstract = "This paper presents a theoretical simulation of thermal and economical assessment of fa{\c c}ade integrated Solar Thermal (ST) in combination with Ultra Low Temperature (ULT) District-Heating (DH). This paper is in line with existing R&D activities for the integration of unglazed systems in building envelopes, where facades provide an almost unexplored area for increasing solaractivated building envelopes. The combination of building-integrated solar systems with DH networks avoids the use of local storage and allows a novel combination of heat directionality, both from building to the heat grid and vice versa. A control algorithm for heat supply is presented, so that the performance of the overall system is the optimal. Energetic results from solar simulations and economic assessment derived from the balance of building energy demand and solar production are presented. Over a fullyear period the proposed unglazed system produces as much as 50% additional heat when compared with an isolated ST system and profitable economic metrics are reached over a simulation time of 20 years. Finally, it is concluded the heat sink nature of a DH network, for as many as 25-35% of the buildings connected to the DH includes ST system.",

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Lumbreras, M & Garay, R 2019, Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating. in V Corrado, E Fabrizio, A Gasparella & F Patuzzi (eds), 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019. vol. 16, Building Simulation Conference Proceedings, vol. 7, International Building Performance Simulation Association, pp. 4401-4408, 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019, Rome, Italy, 2/09/19. https://doi.org/10.26868/25222708.2019.210282

Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating. / Lumbreras, Mikel; Garay, Roberto.
16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019. ed. / Vincenzo Corrado; Enrico Fabrizio; Andrea Gasparella; Francesco Patuzzi. Vol. 16 International Building Performance Simulation Association, 2019. p. 4401-4408 (Building Simulation Conference Proceedings; Vol. 7).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Lumbreras, Mikel

AU - Garay, Roberto

PY - 2019

Y1 - 2019

N2 - This paper presents a theoretical simulation of thermal and economical assessment of façade integrated Solar Thermal (ST) in combination with Ultra Low Temperature (ULT) District-Heating (DH). This paper is in line with existing R&D activities for the integration of unglazed systems in building envelopes, where facades provide an almost unexplored area for increasing solaractivated building envelopes. The combination of building-integrated solar systems with DH networks avoids the use of local storage and allows a novel combination of heat directionality, both from building to the heat grid and vice versa. A control algorithm for heat supply is presented, so that the performance of the overall system is the optimal. Energetic results from solar simulations and economic assessment derived from the balance of building energy demand and solar production are presented. Over a fullyear period the proposed unglazed system produces as much as 50% additional heat when compared with an isolated ST system and profitable economic metrics are reached over a simulation time of 20 years. Finally, it is concluded the heat sink nature of a DH network, for as many as 25-35% of the buildings connected to the DH includes ST system.

AB - This paper presents a theoretical simulation of thermal and economical assessment of façade integrated Solar Thermal (ST) in combination with Ultra Low Temperature (ULT) District-Heating (DH). This paper is in line with existing R&D activities for the integration of unglazed systems in building envelopes, where facades provide an almost unexplored area for increasing solaractivated building envelopes. The combination of building-integrated solar systems with DH networks avoids the use of local storage and allows a novel combination of heat directionality, both from building to the heat grid and vice versa. A control algorithm for heat supply is presented, so that the performance of the overall system is the optimal. Energetic results from solar simulations and economic assessment derived from the balance of building energy demand and solar production are presented. Over a fullyear period the proposed unglazed system produces as much as 50% additional heat when compared with an isolated ST system and profitable economic metrics are reached over a simulation time of 20 years. Finally, it is concluded the heat sink nature of a DH network, for as many as 25-35% of the buildings connected to the DH includes ST system.

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KW - Building envelopes

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KW - Façade

KW - Building envelopes

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BT - 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019

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A2 - Fabrizio, Enrico

A2 - Gasparella, Andrea

A2 - Patuzzi, Francesco

PB - International Building Performance Simulation Association

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Y2 - 2 September 2019 through 4 September 2019

ER -

Lumbreras M, Garay R. Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating. In Corrado V, Fabrizio E, Gasparella A, Patuzzi F, editors, 16th International Conference of the International Building Performance Simulation Association, Building Simulation 2019. Vol. 16. International Building Performance Simulation Association. 2019. p. 4401-4408. (Building Simulation Conference Proceedings). doi: 10.26868/25222708.2019.210282

Simulation of unglazed solar thermal systems integrated into façade & combined with ultra-low temperature district heating

Abstract

Publication series

Conference

Keywords

Project and Funding Information

UN SDGs

Access to Document

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