A Building Science Dive into the Hill Country Wine Cave

The Hill Country Wine Cave, a distinctive architectural endeavor by Clayton Korte Architects, is intricately integrated into the natural landscape of the Texas Hill Country. This private subterranean structure is carved into the north face of a solid limestone hillside, designed to nearly vanish into its surroundings. Completed in 2020, the 1,405 square meter facility encompasses a tasting lounge, a bar, a restroom, and a dedicated wine cellar capable of storing approximately 4,000 bottles.

Wine Storage, Mechanical Design, Indoor Air Quality, HVAC, Heat Pumps, Architectural DesignPositive EnergyMay 28, 2025Hill Country Wine Cave, Clayton Korte Architects, subterranean architecture, Texas Hill Country, wine cellar, tasting lounge, bar, restroom, limestone hillside, excavated tunnel, board-formed concrete portal, white oak, Douglas fir, shotcrete-lined walls, steel and wood windows, building science, thermal stability, moisture intrusion, MEP engineering, Positive Energy, high-end residential architecture, human-centered design, Kristof Irwin, heat, air, moisture flow, thermal performance, moisture control, earth's thermal buffer, subsurface temperatures, Lawrence Berkeley National Laboratory (LBNL), National Renewable Energy Laboratory (NREL), Underground Thermal Energy Storage (UTES), Aquifer Thermal Energy Storage (ATES), passive thermal control, high-efficiency mechanical systems, temperature delta, above-grade environments, temperature fluctuation, energy demand, thermal mass effect, external environmental influence, "ship in a bottle" enclosure strategy, 3D scan, waterproof environment, drainage, water entry, moisture accumulation, sweating, moisture ingress, rainwater, groundwater, air transport, vapor diffusion, Building Science Corporation (BSC), Phius, RDH, source control, dampproofing, waterproofing, control layers, Water Resistive Barrier (WRB), air barrier, vapor retarder/barrier, drainage plane/cavity, rainscreen system, continuous insulation, SEER, HSPF heat pump, Goldilocks scenario, cooling, dehumidification, ASHRAE guidelines, indoor air quality (IAQ), humidity control, Volatile Organic Compounds (VOCs), wine preservation, corks, off-gassing, ventilation, filtration, ASHRAE Standards 62.1, ASHRAE Standards 62.2, system thinking, high-performance design, collaborative design

Recirculating Hoods and Indoor-Air Quality

A few years ago, Fine Homebuilding published a very energy-efficient house that had a recirculating range hood. The reason for the recirculating hood was to avoid punching an additional hole in the air barrier and to avoid the need for makeup air, if my memory serves me. Now I’m faced with a similar decision. Seems recirculating hoods won’t remove moisture from the kitchen—do they at least do an adequate job of filtering the air?

Designing Healthier Homes by Eliminating Fossil Gas Appliance Emissions

Architects, as the primary designers of our built environment, hold a profoundly influential position in shaping the health and well-being of building occupants. Beyond the critical considerations of aesthetics, structural integrity, and energy performance, a deep understanding of the invisible forces at play within a building's envelope is increasingly paramount. This report aims to equip architects with the essential knowledge to proactively design for superior indoor air quality (IAQ), particularly concerning emissions from common household gas appliances. The decisions made during the design phase, from material selection to mechanical system integration, directly influence the indoor environment and, by extension, the health outcomes of those who inhabit these spaces. This effectively positions architects as critical guardians of public well-being within the built space, expanding their traditional role to encompass a vital public health responsibility.

Indoor Air Quality, HVAC, Electrification, Architectural Design, Building Enclosure, Code, Filtration, Healthy Home, High Performance Homes, VentilationPositive EnergyMay 22, 2025Designing healthier homes, eliminating fossil gas appliance emissions, indoor environmental quality, architect's role, indoor air quality, gas appliances impact on home health, combustion byproducts, hazardous air pollutants, synthesizing scientific findings, actionable strategies for architectural practice, pollutants emitted by gas appliances, health effects, design and engineering solutions, fundamentals of indoor air quality, source control, ventilation, filtration, temperature and relative humidity levels, building as a dynamic system, geographic site, local climate, physical structure, HVAC, construction techniques, contaminant sources, occupants' activities and behaviors, air exchange pathways, mechanical ventilation systems, infiltration, air pressure differences, building envelope, "Building Tight, Ventilate Right" imperative, energy consumption, pollutant concentration, energy efficiency, ventilation strategies, indoor air pollutants exceed outdoor levels, internal pollutant sources, "concentration trap", managing and removing internal contaminants, key pollutants from gas appliances, nitrogen dioxide, carbon monoxide, particulate matter, volatile organic compounds, moisture, respiratory irritation, asthma exacerbation, infection risk, decreased lung function, fatigue, chest pain, impaired vision, headaches, dizziness, confusion, nausea, DNA damage, mortality, transmission of airborne pathogens, organ damage, allergic reactions, cancer, dampness, mold growth, electric coil burners, high-dose exposure, pulmonary edema, diffuse lung injury, bronchitis, ambient air quality standards, carboxyhemoglobin, unvented gas space heaters, gas stoves, back-drafting, angia, poor ventilation, ultrafine particles, respirable particulate matter, cooking emissions, airborne particles, pathogens, respiratory aerosols, formaldehyde, benzene, unburned natural gas leakage, environmental tobacco smoke, automobile exhaust, sensory irritation, carcinogens, moisture load, human respiration and perspiration, bathing, washing, plants, pets, appliance selection, all-electric homes, electronic ignitions, proper appliance installation and maintenance, ducted range hoods, capture efficiency, airflow requirements, multi-family homes, whole-house ventilation strategies, tighter building envelopes, backdrafting risks, make-up air systems, targeted spot exhaust, bathroom fan, high-efficiency filtration, MERV-13, infectious aerosol exposure, cost-benefit analysis, air cleaning, indoor particle concentrations, semivolatile organic compounds, monitoring and alarms, carbon monoxide alarms, advanced IAQ monitors, PM2.5 sources, collaboration with MEP engineers, certified technicians, health impacts, continuous leakage, moisture byproduct, all-electric transition, building a healthier future, works cited, RMI, ASHRAE, EPA, LBNL, ventilation and air cleaning, envelope leakage, hazardous air pollutant emissions, residential ventilation requirements.

Breathing Easy: The Case for a National Indoor Air Quality Code in the United States

The United States faces a significant, yet largely unregulated, public health challenge: the quality of the air inside its buildings. Americans spend approximately 90% of their time indoors , breathing air that can be two to five times, and occasionally more than 100 times, more polluted than outdoor air. Despite this reality, the nation lacks a comprehensive federal code specifically governing indoor air quality (IAQ), relying instead on a fragmented system of state regulations, voluntary guidelines, and limited occupational standards. This regulatory gap results in inconsistent protection and contributes to a silent epidemic of health problems—ranging from asthma and allergies to cardiovascular disease, cognitive impairment, and cancer—and imposes a substantial economic burden through healthcare costs and lost productivity, estimated in the tens to hundreds of billions of dollars annually.

CodePositive EnergyMay 1, 2025Indoor Air Quality (IAQ), national IAQ code, public health, building codes, regulations, ventilation, filtration, source control, pollutants, health effects, respiratory illnesses, allergies, cardiovascular disease, cognitive impairment, economic burden, healthcare costs, lost productivity, EPA recommendations, ASHRAE standards, WHO guidelines, implementation challenges, legislative action, phased implementation, research, workforce development, public-private partnerships, Clean Air Act, National Ambient Air Quality Standards (NAAQS), Model Clean Indoor Air Quality Act (MCIAA), California Title 24, Occupational Safety and Health Administration (OSHA), General Duty Clause, Particulate Matter (PM), Volatile Organic Compounds (VOCs), carbon monoxide (CO), radon, nitrogen dioxide (NO2), ozone (O3), formaldehyde, mold, biological contaminants, asthma, COPD, sick building syndrome, structural codes, fire codes, electrical codes, plumbing codes, information asymmetry, market efficiency, negative externalities, energy efficiency, MERV 13 filters, monitoring protocols, maintenance, schools, healthcare facilities, workplaces, cost-benefit analysis, financial assistance, tax incentives, utility programs, stakeholder engagement, building industry, public health advocates, labor unions, environmental organizations, consumer advocacy groups, government agencies, international models, European Union, Canada, South Korea, Japan, Singapore, air changes per hour, carbon dioxide (CO2) sensors, commissioning, verification, education, public awareness campaigns.

State of the Art HVAC: Five keys to flawless space conditioning.

Blog