Energy Efficiency In Boston’s Art And Culture Institutions: Strategies For Sustainability – Northeastern University Interdisciplinary Science and Engineering Complex, Boston, MA How do you design a laboratory that combines energy efficiency with high performance?

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Energy Efficiency In Boston’s Art And Culture Institutions: Strategies For Sustainability

Provided comprehensive strategies for Northeastern University’s new Interdisciplinary Science and Engineering Complex (ISEC). This LEED Gold-certified, 234,000-ft

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The facility includes a variety of laboratories and other research support spaces aimed at fostering collaboration and innovation in the fields of computer science, basic science, health science and engineering.

In addition to helping Northeastern raise its profile in the scientific community and attract new talent, the project provides a pedestrian footbridge—an important new nodal link between the main campus, ISEC, and the communities of Fenway and Roxbury.

Collaborated with Payette on both the new building and footbridge, providing services including structural, geotechnical, MEP/FP engineering, facade and lighting design consulting.

Our involvement in the ISEC project began in 2013 when we were selected by Payette and Northeastern to provide a range of services for the new complex, including mechanical, electrical and plumbing engineering, energy modeling, facade consulting, sustainability consulting and lighting design. It was important to the client that ISEC embodied the North East’s commitment to sustainability. And Payette collaborated closely throughout the design process to deliver a remarkable and highly energy-efficient building on a tight schedule.

Boston City Hall

In the early stages of the project, we developed a 3D Revit model of the building system that allowed the team to quickly assess the impacts of a range of configurations in real time. The model enabled us to efficiently adapt to the changing requirements of the client and the architect and facilitated the identification of strategies that delivered the best in form and function. A 3D Revit model was also used as the backbone of our energy modeling, daylight modeling, CFD studies and facade analysis.

Developed several innovative solutions that increased the project’s sustainability and helped increase its overall value to the university and the larger community.

A defining characteristic of ISEC is its complex façade. Bronze, curved wings march over the curved office block, undulating in plan and dividing in height to create free-form shapes. Payette relied heavily on modeling to achieve ISEC’s elegant, organic look and technical challenges.

Our Revit model was particularly useful in determining how to seamlessly integrate wings into building engineering in a way that optimizes energy performance. The fins contribute to the lighting and thermal strategy, and reduce the direct solar energy from the southwest to exit the views and add light during the day. In combination with the high-performance glazed curtain wall and the building’s mechanical system, the thermal, daylighting, and comfort performance requirements of the wing facade. They also mask walkways for maintenance, protect insulated triple-glazed office units from direct exposure to the elements and hang important cantilevers.

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The cascade air system developed by ISEC was the largest contributor to energy savings. The system works by retrieving conditioned air from ISEC’s offices and atrium and then transferring it to the laboratory. In addition to delivering significant energy savings over standard laboratory HVAC systems, cascade air systems help reduce operations and capital costs by reducing return ductwork. Since ventilation loads are the main energy consumption in laboratories, active chilled beams are used to provide additional cooling in place of air cooling. Because chilled beams have no moving parts, they are a low-energy, low-maintenance alternative to fan coil units. To enhance heating, we designed a hydronic run-around coil system that recovers energy from laboratory exhaust air and pre-conditions outdoor air used for heating. A heat recovery chiller was also used to divert the normally rejected heat to the cooling towers to meet the summer heat demand in the building.

Our sustainable lighting and daylighting strategies were instrumental in enhancing the efficiency of the architectural design. The six-story central atrium was carefully designed with pavettes to introduce views of the sky and allow for ample daylight, while also managing visual comfort in the adjacent laboratory and support spaces. The result is an interior glazed facade that puts researchers on full display from the atrium space. The electric lighting design compliments the building’s design strategy using integrated lamps on lab benches and indirect lighting for ambient light levels, primarily in research areas.

The campus provides an important link between the ISEC complex directly to the south and the neighborhoods of Fenway and Roxbury. The bridge not only increases accessibility, but also provides an important feeder to the nearby MBTA Orange Line and bus station.

Our structural designers helped Payet realize the dramatic form of the bridge, which uses weathering steel plates. The bridge’s most prominent features are the two asymmetrical parapet barriers that flank the structure on its western and eastern edges. Both parapets lean out 10 degrees to provide a view to the sky. The high western parapet slopes gently to the south side of the bridge to a height of 18 feet. Constructed from overlapping panels of solid weathering steel plate, the barrier serves to mask the ugly infrastructure to the west and direct east toward ISEC and the Boston skyline. Due to the special steel’s corrosion resistance, the bridge does not require frequent painting throughout its life, resulting in lower operating costs and fewer disruptions to rail service.

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Our bridge lighting scheme continues the narrative of integrated design that blends beautifully with the structural form of the bridge to create an inviting, safe and elegant nighttime experience. The main span of the bridge was assembled in a lay-down area adjacent to the ISEC and dramatically lifted over the railroad tracks in one piece to minimize disruption to MBTA and Amtrak rail service.

The close collaboration between Payette and the Northeast was critical to helping achieve Northeastern’s ambitious aesthetic and performance goals for this project. The result is a Harleston Parker Medal-winning, LEED-Gold certified “Temple of Science” that surpasses Massachusetts’ strict stretch energy code requirements for new buildings by 20%.

“This complex is a statement that this city, this state, thrives on discovery, research, learning” Joseph Aun President, Northeastern University Closed-Form Expression for the Symbol Error Probability in a Full-Duplex Spatial Modulation Relay System and Its Optimal Power Allocation application

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Josip Lorincz Josip Lorincz Scilit Preprints.org Google Scholar 1, * , by Antonio Capone Antonio Capone Scilit Preprints.org Google Scholar 2 and Jinsong Wu Jinsong Wu Scilit Preprints.org Google Scholar 3

Department of Electronics and Computing, Faculty of Electrical Engineering, Mechanical Engineering and Naval Architecture (FESB), University of Split, 21000 Split, Croatia

Although information and communication technologies (ICTs) have the potential to enable powerful social, economic and environmental benefits, ICT systems contribute insignificantly to global electricity consumption and carbon dioxide (CO).

) footprint. This contribution will continue as the increasing demand for user connectivity and the explosion of traffic volumes necessitates the continuous expansion of existing ICT services and the deployment of new infrastructure and technologies to ensure the desired user experience and performance. In this paper, a cost analysis for global annual energy consumption of telecommunication networks, estimates of CO in the ICT sector

Northeast Energy Efficiency Partnership

Energy consumption footprint contributions and projections of all connected user-related devices and equipment are presented for the period 2011-2030. Presented projections of network energy consumption trends for the main communication sectors until 2030 show that the largest contribution to global energy consumption will come from wireless access networks and data centers (DCs), the rest of the paper analyzes the technologies and concepts that can contribute to energy. – Improving the efficiency of these two areas. More specifically, different paradigms for wireless access networks such as millimeter-wave communications, long-term evolution in unlicensed spectrum, ultra-dense

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