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EnergyX DY-Building

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EnergyX DY-Building
에너지엑스 DY빌딩
General information
Address152, Hyanggiro, Hyangdong-dong, Deokyang-gu, Goyang-si, Gyeonggi-do, Korea
Year(s) built2023
Technical details
Floor count7
Floor area3,274.87㎡

EnergyX DY-Building (Korean에너지엑스 DY빌딩) is a zero-energy building located at 505, Hyangdong-dong, Deokyang-gu, Goyang-si, Gyeonggi Province, South Korea. The building has a total floor area of 3274.87 m² and consists of seven floors, commercial building. The name DY-Building is derived from "Dynamic Yield".[1]

EnergyX DY-Building is the first plus-zero-energy commercial building in Korea. From the initial design phase, the goal was to implement PEB (Plus Energy Building) concepts by minimizing energy demands through passive design and active system technologies while maximizing energy production using renewable energy sources. The building achieved an energy self-sufficiency rate of 121.7%, producing more energy than it consumes. This earned the building recognition as a "small power plant" and made it the first commercial building in South Korea to receive the highest Zero Energy Building (ZEB) certification (Grade 1) from the government.[2]

Applied technologies

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Passive design

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Passive design strategies refer to a set of design approaches that focus on utilizing the natural environment to provide heating, cooling, ventilation, and lighting to a building. Unlike active design strategies that rely on mechanical systems and processes, passive design strategies depend on the laws of nature. Passive design strategies aim to create a comfortable and energy-efficient indoor environment while minimizing the use of mechanical systems and reducing the building's energy consumption. They take advantage of the climate, site conditions, and materials to create a building that functions in harmony with the environment.[2]

To minimize the energy demand of the Energy X DY Building, high-performance insulation and window systems were applied. The thermal insulation performance of the exterior walls was designed to be 0.152W/m²K, which is 37% higher than the 0.240W/m²K standard for Climate Zone 2 in the Building Energy Saving Design Criteria.[3] Additionally, 42mm low-emissivity (Low-E) triple glazing was installed to minimize the effects of solar radiation, including solar heat gain and window thermal transmittance.[4]

Active system

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Active systems refer to the mechanical and electrical design phase aimed at handling the loads required to maintain a comfortable indoor environment, including cooling, heating, hot water, lighting, and ventilation.[5]

The heating and cooling source for the Energy X DY Building is an Electric Heat Pump (EHP), while the hot water supply is provided by electric water heaters. A total of 11 EHP units have been installed, with an average Coefficient of Performance (COP) of 3.54 for cooling and 3.72 for heating, utilizing first-grade energy efficiency products. To enhance indoor air quality and comfort, a ventilation system has been introduced, and 39 total heat exchangers have been installed across various zones. The minimum effective heat exchange efficiency has been set to over 50% for cooling and over 70% for heating to reduce energy consumption.[3]

For lighting, high-efficiency energy-certified LED lighting products were selected for each zone, with a lighting control system installed to reduce operational energy consumption. The lighting system is integrated with the Building Energy Management System (BEMS), and the control system is configured to adjust indoor LED lighting brightness in three levels.

Photovoltaic system

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A photovoltaic system, also called a PV system or solar power system, is an electric power system designed to supply usable solar power by means of photovoltaics.

The PV modules have been installed on the roof and sloped areas. A total of 81 kW of PV modules have been installed, with 63 kW placed horizontally on the roof and 18 kW installed on the sloped areas of the roof.

Building Integrated Photovoltaic System

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Building-integrated photovoltaics (BIPV) are photovoltaic materials that are used to replace conventional building materials in parts of the building envelope such as the roof, skylights, or façades.[6]

To achieve energy self-sufficiency, simply covering all available building façade spaces with solar panels would be the easiest approach, but this would compromise the building's design. To address this, the Building-Integrated Photovoltaic (BIPV) system was developed. This system replaces conventional building materials with photovoltaic modules that not only serve as the exterior cladding but also generate electricity.[3]

In the case of the Energy X DY Building, the façade was designed using a curtain wall system, and the solar modules were planned as follows: BIPV-1 (spandrel panels), BIPV-2 (vision area), and BIPV-3 (opaque cladding materials). This integration allows the building to maintain both aesthetic appeal and energy efficiency.[4]

Solar Installation Locations and Capacity for the Energy X DY Building

Category Section Area(m²) Capacity(kW)
PV Rooftop Horizontal Surface 298.98 63.00
Sloped Roof Surface 85.42 18.00
BIPV-1 SKALA Façade (West, South, Southwest) 453.12 60.20
BIPV-2 VISION 440.82 21.35
BIPV-3 POWERMAX Façade (Southeast) 168.60 24.00
Total 1,446.94 186.55
Final ZEB Certification Self-Sufficiency Rate 121.7%

Records

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  • South Korea's First Commercial Plus Zero Energy Building[7]
  • Achieved Building Energy Efficiency Rating 1+++
  • Attained Energy Self-Sufficiency Rate of 121.7%[8]

References

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  1. ^ 이, 선희 (2023-12-10). "에너지엑스 '에너지엑스 DY빌딩' 비·햇빛·바람 고려한 설계 … 제로에너지 빌딩 표본". 매일경제 (in Korean). Retrieved 2024-09-30 – via Naver News.
  2. ^ a b "Significance of Passive Design Strategies for Architecture in 2024". www.novatr.com. Retrieved 2024-10-21.
  3. ^ a b c Hong, Tom; Lee, Du-Hwan (2024). "Engineering Report | Introduction to the Completion and Key Technologies of the Energy X DY Building Achieving Plus Energy Building (PEB) : 엔지니어링 리포트 | 플러스에너지빌딩(PEB)를 달성한 에너지엑스 DY빌딩의 준공 및 주요 기술 소개". Journal of the Architectural Institute of Korea (in Korean). 68 (1): 50–54. ISSN 1225-1666.
  4. ^ a b Lee, Du-hwan (2024). "Energy X's Platform Service for ESG and Sustainable Architecture(ESG와 지속가능한 건축을 위한 에너지엑스의 플랫폼 서비스)". Construction Engineering and Management.
  5. ^ Sungjin, Park (2023-04-30). 제로 에너지 건축물과 BIPV [Zero Energy Buildings and BIPV] (in Korean) (1st ed.). Korea: 신구문화사. p. 169. ISBN 9788976682758.
  6. ^ Petter Jelle, Bjørn; Breivik, Christer; Drolsum Røkenes, Hilde (2012-05-01). "Building integrated photovoltaic products: A state-of-the-art review and future research opportunities". Solar Energy Materials and Solar Cells. Photovoltaics, Solar Energy Materials, and Technologies: Cancun 2010. 100: 69–96. Bibcode:2012SEMSC.100...69P. doi:10.1016/j.solmat.2011.12.016. hdl:11250/2436844. ISSN 0927-0248.
  7. ^ "에너지엑스, 에너지자립률 121.7%… 국내 최초 플러스 제로에너지빌딩 준공". 인더스트리뉴스 (in Korean). 2023-10-13. Retrieved 2024-10-21.
  8. ^ "[현장르포] 국내 최초 플러스에너지빌딩 'DY빌딩'". 기계설비신문 (in Korean). 2024-06-17. Retrieved 2024-10-21.