Research Tracker

This research will examine several high aspect ratio (15:1) cylinders, (smooth, roughened and grooved) in a wind tunnel test that specifically measures dynamic response to simulated boundary layer flow. Both along- and cross-wind response will be measured for a range of wind speeds to determine the nature of the loading and in particular the effect of the grooves on the loading and axial wind speeds. This will provide the necessary data to develop a full proposal to study the bio-mimicry aspects of this work to the aerodynamics of tall buildings.

SWA will work with NYCHA to identify a subset of building typologies that represent its broader portfolio and are also relevant to other NY housing stocks. SWA will assess the representative properties and identify pathways for achieving DERs. SWA will review existing physical needs assessments plans (PNA) and meet with the NYCHA capital planning team to understand the existing long term capital needs and approach to capital planning. SWA will develop potential long term plans for each building typology to realize deep energy reductions that build on existing capital plans and needs.

FXFOWLE Architects will undertake a research study to determine the viability of implementing the Passivhaus standard on tall residential buildings in New York State. Using a 25 story multifamily project currently in design as a base building, the study will investigate the detailed implications of adapting a typical tall residential building to meet the Passivhaus standard. This work will analyze the impacts from architectural, structural, enclosure detailing, materials, mechanical, zoning, financial, marketability, and constructability perspectives. Market barriers and opportunities will be identified and addressed. In addition, the study will evaluate how applying the Passivhaus standard to a tall multifamily residential building can affect resiliency and security issues

CNSE and EYP Architecture and Engineering will evaluate the energy and demand benefits from smart controls that integrate various systems to enable more holistic operation of a building. The systems to be controlled include digital addressable LED lighting system with day-lighting controls, automated window covering system, occupancy RFID tracking system, submetered energy monitoring and utility meter data, PLC-based HVAC controls, fuel cell, PV array and task lighting.

Taitem Engineering will evaluate the Dutch program for deep energy retrofits of residential buildings known as Energiesprong. The objectives of this study are as follows: gain an in-depth understanding of the solutions implemented under the Energiesprong program, confirm the cost and performance of the implemented retrofits; assess transferability to NYS building stock (e.g. wood-frame vs. concrete frame) and assess transferability to NYS different climate zones.