California's All-Renewable Energy Future

Introducing Passive House Plus and Premium

Figure 1. Renewable energy sources are incentivized with PER factors (Logo use with permission, PHI. Original Illustration by author.)

 
If you’ve been puzzled by the proliferation of ‘net,’ ‘nearly’ and ‘almost ready’ Zero Energy definitions and standards and have wondered just how net or nearly they truly are, take heart.  The Passive House Institute (PHI) has introduced an equitable assessment of energy use to help guide us toward the 100% renewable energy future our State—and planet—must rapidly achieve.

Figure 2. Passive House counts generation losses, transmission losses and seasonal generation. (Original Illustration by author.)

Inspired in part by the impressive leaps in the efficiencies of renewable energy generation, coupled with the urgency of meeting global climate change goals, PHI initiated a review of non-renewable energy use in buildings in 2013.  They recognized that their previous calculations for Primary Energy needed updating, especially as they favored the use of natural gas over electricity. (Primary Energy accounts for all the source energy used by a building, including the amount of energy it takes to generate and transmit power to the building site.)   PHI recognized that non-renewable forms of energy use by buildings needed to be rapidly phased out, so they devised a method to incentivize the use of renewable forms of energy in buildings.  Their research resulted in the overhaul of the existing Passive House ‘Classic’ standard and the introduction of two new standards: Passive House Plus and Passive House Premium.

Figure 2. Passive House counts generation losses, transmission losses and seasonal generation. (Original Illustration by author.)

Primary Energy Renewable ‘Factors’ and how they work

All of the new Passive House standards now calculate Primary Energy using Primary Energy Renewable (PER) factors.  These are designed to encourage the use of renewable energy sources and create either incentives, or disincentives, for installing various types of mechanical equipment in Passive House buildings.  For example, in San Francisco,  using a heat pump water heater to produce hot water will result in lower Primary Energy requirement numbers than using a gas tank water heater would, making it easier to meet the certification target.  (A heat pump water heater has a PER factor of 1.25 versus the 1.75 factor for a gas-fired water heater.)

PER factor calculations are based not only on fuel source, but also on site-specific load profiles calculated on an hourly basis. In this way, variations in regional utility grid source energy and typical time-of-day use profiles, which impact the availability of renewable energy to meet a utility’s load, for the local climate and region are factored into these calculations.  As a result, the PER factors can vary from city to city in California.  For example, the electricity PER factor for heating demand via heat pumps is 1.80 in Sacramento.  This relatively high PER factor incentivizes reducing heating demand in winter, when renewable energy supplies are low. In San Diego the comparable PER factor is set at 1.30, where the climate is milder and cooling is typically a greater peak load issue. 

Crediting renewable energy equitably

Conventionally, calculations of net zero depend on the difference between a building’s annual energy demand and annual on-site renewable energy production. These calculations penalize tall buildings with small roof areas, buildings with no solar access, or buildings that opt to use their roof area for green space or as active living spaces.  PHI took a major deviation from such traditional methods for crediting renewable energy supply to buildings, recognizing that all sites are not created equal in this regard.  PHI’s approach uses the following principles:

  • Renewable offsets are calculated as a function of Projected Building Footprint (PBF) rather than total floor area. PBF is more proportional to available roof area than total floor area, which means multi-story buildings may achieve the Plus and Premium standards.
  • Buildings with no solar access on site may purchase off-site renewable energy facilities to achieve Plus or Premium certification.
  • PH ‘Classic’ Buildings with no on-site or off-site renewable energy supply are still optimized for efficiency first and a future grid supply of all renewable energy. 

 

Figure 3. Tall and shaded buildings are not penalized by the PER calculation. (Original illustration by author.)

 

Biofuels, Microgrids, and Battery Storage

While biofuels are considered a renewable energy source, they carry a penalty for replacing food production. Their burning also generates particulate matter that is both unhealthy and emits carbon. For these reasons, the use of biofuels is allowed, but has been capped to limit its use. 

The most intriguing areas of innovation with regards to manifesting the 100% renewable energy future currently look to be in developing our capacity to store renewable energy.  We’re excited by the contributions being made right here in California to develop technologies that are contributing to our new energy future. Existing storage capacity from hydroelectric schemes is now being joined by a growing array of affordable short- and long-term battery storage options.  Converting renewable energy into methane gas is another rapidly developing technology that could increase the viability of renewable energy by allowing us to store it for longer. 

Remarkably, these options are all currently supported by the Primary Energy Renewable calculations embedded in the Plus, Premium, and Passive House Classic standards. Indeed, the ‘Classic’ standard at the heart of all of them remains the foundation that most equitably supports an all-renewable energy future.  The Classic standard ensures that these buildings are optimized to become batteries themselves: they’ve been proven to retain an unprecedented level of thermal comfort while eliminating peak loads. This optimization ensures that even without the addition of ‘active’ power, their passive capacity is what is literally doing the heavy lifting.  These buildings enable occupants to survive in adequate comfort for very lengthy periods of time without any active energy inputs.  This quality offers economic benefits to both the utilities and microgrid designs of renewable energy storage systems that extend well beyond comfort.  Just imagine what we could do with renewable energy if we didn’t need so much of it to simply operate buildings?  The possibilities are boundless.

 

Bronwyn Barry, CPHD

August 2016

 

This article was first published by Low Carbon Productions in the print copy of ‘Passive House Buildings: California’s Energy Future,’ produced in collaboration with Passive House California.  Additional articles and California project examples may be viewed in the free e-book here. 

References:

·      http://passipedia.org/certification/passive_house_categories/per#the_per_sustainability_assessment.

·      https://passipedia.org/basics/passive_house_-_assuring_a_sustainable_energy_supply/passive_house_the_next_decade

 

Appendix:

Figure 4. PER demand and generation results table showing Certification Classifications (Taken from the PHPPv.9 - Copyright Passive House Institute)

 

Figure 5: PER factors for California's largest cities sourced from PHPP v.9

 

Figure 6. Electricity use allocation showing direct consumption, storage and conversion potentials. (Copyright - Passive House Institute)