Abstract

Given the enormous impact of buildings on energy consumption, it is important to continue the development of net-zero energy districts. Opportunities exist for energy efficiency and renewable energy on a district level that may not be feasible in individual buildings. Due to the intermittent nature of many renewable energy sources, net-zero energy districts are dependent on the energy grid. The novelty of this work is to quantify and optimize the economic cost and grid independence of a net-zero energy district using the National Western Center (NWC) in Denver, CO, USA as a case study. The NWC is a 100+ ha campus undergoing a major redevelopment process with a planned 170,000 m2 of total building space, an emphasis on sustainability, and a net-zero energy goal. Campus plans, building energy models, and renewable energy performance models of on-site solar, biomass, and thermal renewable energy sources are analyzed in multiple energy scenarios to achieve net-zero energy with and without on-site energy storage. Levelized cost of energy (LCOE) is optimized as a function of variables defining the energy and economic relationship with the grid. Discussion herein addresses trade-offs between net-zero energy scenarios in terms of energy load, LCOE, storage, and grid dependence.

Highlights

  • The Levelized cost of energy (LCOE) is calculated with the corresponding technology solutions compared for scenarios successfully achieving net-zero energy

  • An interesting opportunity for renewable energy penetration is the development of net-zero energy districts

  • The work leverages detailed building energy modeling coupled with energy-generation modeling to evaluate the ability for different renewable energy system configurations to meet National Western Center (NWC)’s net-zero energy target, and quantify their economic viability and their level of grid dependence

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Summary

Introduction

Sustainable energy building design has been a growing focus in the last couple decades. Design includes performance goals such as net-zero energy, where efficiency gains are implemented such that the balance of the energy needs can be offset by renewable technologies [2]. Zero energy has been expanded to “communities” [3], noting that larger districts provide opportunities for energy efficiency and renewable energy penetration that may not be feasible in individual buildings [1]. Zero energy district design principles have been outlined as a priority of maximizing: (1) building efficiency, (2) solar potential, (3) renewable thermal energy, and (4) load control [1]. While the goals may be consistent, how zero energy strategies play out in terms of technology and design are unique to each district

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