The Building Science Podcast

Join Kristof as he discusses the ins and outs of attic ventilation. If you find this topic helpful or interesting, take a moment to dive into the resources below!  http://www.greenbuildingadvisor.com/blogs/dept/musings/all-about-attic-ventinghttp://buildingscience.com/documents/digests/bsd-102-understanding-attic-ventilationhttp://builditgreendallas.org/sites/builditgreendallas.org/files/www/files/rr-9801_vented_sealed_attics.pdfhttp://www.structuretech1.com/wp-content/uploads/2013/12/Early-History-of-Attic-Ventilation.pdf

What do you really know about your HVAC system? Well wonder no more. We've got you covered!At Positive Energy, we design high performance HVAC systems. Just to be perfectly clear, we design systems that rely on Variable Capacity (VRF) HVAC equipment. Simply put, installers and mainstream MEP engineers launch into designs thinking about air handlers, plenums and ducts, while we start by thinking about your enclosure, your pulmonary system and health, and how your body perceives comfort. Having a carefully designed, high performance HVAC system is the most sensible way to deliver health and comfort in your home or building. Positive Energy has a team of passionate, creative, and thoughtful engineers and we love what we do. Learn more about our process, outlining the architectural and mechanical design processes to see where we’ll intersect along the way.A quick reference mentioned in the podcast on humidity and asthma:

In our very first short episode, the show's producer rambles while gives a brief overview of building science's role in societal change and how it could affect our lives.

The PHIUS+ 2015 Passive Building Standard provides the climate-specific sweet spot where aggressive energy and carbon reduction overlap with cost effectiveness. It accounts for a full range of variables including climate zone, source energy, and costs. In cooperation with Building Science Corporation under a U.S. DOE Building America Grant, the PHIUS Technical Committee developed passive building standards that account for the broad range of climate conditions, market conditions, and other variables in North American climate zones. In this week's episode, we explore the above code practice of Passive House and its role in American architecture and building. Special thanks to the Austin PHAUS Chapter for their generous support of this episode.

"“Why do we heat and cool buildings with air? How did a thermodynamically and physiologically irrational medium of heat transfer - air - become the dominant method of heating and cooling buildings? Water is 832 times denser than air. Energy Density is directly related to the density of a material. Water can capture and channel far more energy per unit volume than air. Thermally active surfaces are built around this basic principle. The human body is a hydronic, thermally active surface system. Heat energy is transferred in and around a body through the hydronic circulatory system. The heart circulates heat through the blood back and forth between the core of the body to its skin, a thermally active surface. Its thermal system is decoupled from its ventilation system. Thermally active surfaces in buildings follow this logic, literally. This alters energy consumption and amends human comfort. Thermally active surfaces in buildings are not metaphors for the body and do not mimic a natural system. Rather, they share the same thermo-dynamical system. In this century, building science and systems will follow how the body actually functions. The human body uses radiant transfer to exchange most of its thermal energy. Buildings based on this logic will significantly amend current patterns of energy consumption and human comfort. Achieve greater human comfort with low air temperature heating and high air temperature cooling. Thermally active surfaces utilize low-supply temperature heating and high-supply temperature cooling to achieve human comfort. This can save an immense amount of energy in the next century of building. Cooling is a deceptive concept. If a building does not get hot, it does not need to be ‘cooled.’ Thermally active surfaces ‘cool’ by continuously removing heat energy. This is fundamentally different from air based approaches to cooling. If a surface is cooler than the bodies and objects in its space, it is removing heat from those objects and has the effect of cooling. There is no circumstance when the surface temperature should be near or at the dew point temperature to heat or ‘cool’ a space. As such, condensation is not an impediment to thermally active surfaces. De-fragment buildings and the building industry. Integrated practices must occur on societal levels in how teams and projects are structured as well as on material levels in the form of simplified, yet higher performing, building systems. Thermally active surfaces engender more deeply integrated design of material and energy systems for more robust buildings.What would change if we heated and cooled buildings with water rather than air? Thermally active surfaces stand to advance architecture’s practices and performances: its techniques, technologies, professional and ecological sustainability, budgets, and formal possibilities.” -Kiel Moe, Thermally Active Surfaces In ArchitectureIn this episode of The Building Science Podcast we explore one of the world's most potent and revolutionary technologies - thermally active surfaces, or radiant heating and cooling. 

We take the air conditioner for granted, but imagine what life would be like without it. Once considered a luxury, this invention is now an essential, allowing us to cool homes, businesses, hospitals, data centers, laboratories and other buildings vital to our economy and daily lives. In fact, air temperature is so important to us that 48 percent of all energy consumption in American homes is a result of cooling and heating, according to the Energy Information Administration.Like most important breakthroughs, modern commercial and residential air conditioning technology is a result of a series of advancements by scientists and inventors who challenged themselves to come up with creative solutions to problems of the day.How much do you really know about where air conditioning comes from? From Benjamin Franklin to the vast scientific HVAC advancements of the future - in this episode of The Building Science Podcast, we explore the rich and fascinating history of air conditioning and discover something fascinating about the difference between air and water.

In this episode, Kristof interviews world renowned lighting consultant Matthew Tanteri on the complexities of the windows in architecture. Matthew Tanteri runs Tanteri + Associates to provide architectural lighting design services to architects, designers, building owners and developers.  We work on light projects large and small that include retail, residential, commercial, institutional, landscape and much more.For 25 years, their collaborations on lighting projects all over the world have been recognized by many of the lighting industry’s most distinguished awards.  With natural and electric light they seek to enhance and define the visual experience. They are constantly exploring new methods, materials, and applications in which to use light.Join us for a wonderful conversation and enjoy!

In our first ever episode of the building science podcast, Kristof & Michael introduce a wild product that could change how your home can passively handle heat loads. A phase change material (PCM) is a substance with a high heat of fusion which, melting and solidifying at a certain temperature, is capable of storing and releasing large amounts of energy. Heat is absorbed or released when the material changes from solid to liquid and vice versa; thus, PCMs are classified as latent heat storage (LHS) units.Join us as we begin this wild adventure with very little knowledge of how to make a podcast. We hope it goes well and that you enjoy!