An Approach to a Zero-Energy House Summary For an extreme climate (both hot and cold, with little winter sun), heat loads are the primary stressor. With little or no help from HVAC systems, the building fabric becomes the lead system. There appear to be a couple of options to reduce heat loads to the point where diffuse solar energy may be sufficient to keep occupants comfortable. Stressors Consider a climate where the winter low is –20 C and the summer high is 30 C. Both are diurnal means, with + 5 C swings. The winter low of –25 C and summer high of 35 C are both a bit more extreme than 99+% design temperatures for Chicago (as defined in ASHRAE Handbook of Fundamentals). Comfort temperatures are 20 C in winter and no more than 28 in summer. The climate is often cloudy in winter. For design conditions, it should be considered as cloudy. Because the largest indoor-outdoor temperature difference is in winter, the primary stressor can be considered to be cold winter temperatures. The absence of clear skies means that the design will need to rely more on insulation than insolation. Performance Specifications Minimum heat loss through the walls and roof is key. Heat loss through the ground is also an issue, but should be much smaller if there is decent insulation under the floor slab or at least around the perimeter of the slab. Why? Because ground temperatures are warmer in winter than air temperatures, due to the thermal mass of the Earth. There will be a need for some combination of solar heat and heat from occupants and equipment (appliances and lights) to make up for the minimal heat flow through the building envelope. Windows should be sized to provide necessary solar heat and to admit sufficient daylight to minimize the need for electric lights during daylight hours. In summer, there will be a need for thermal mass to reduce indoor temperature swings (remember the Duxford hanger, in winter) and a need for night cooling, because the diurnal average exceeds the comfort point. Photovoltaics or wind will be needed to provide electricity. Alternatively, one could consider the combustion of renewable biomass, sizing a biomass farm accordingly. 1 Meeting the Performance Specifications Heating – the primary stressor, for which the façade is the lead system Start with a windowless box, two stories. Each floor is 10 x 10 m, 3 m in height. Flat roof. Surface is 340 m2 (we won’t worry about the ground for now – too hard, although it would be more conservative to include it). Consider walls and a roof with a thermal resistance of R 6 in SI units (about R 34 in English units, or about 6 inches of extruded polystyrene, with cladding and gypsum board). The heat flow can be determined from q UA(Tin Tout ) The average heat flow over a day in winter will be about 2270 Watts, extremely low for such a large temperature difference but still a problem for a zero-energy house. How to come up with an average thermal power of 2270 W? We have several choices: Active solar collectors on the roof (and walls and surrounding ground, if needed) Let’s try them on the roof, as a form of integration. We need to estimate the average solar power incident on the collectors and their efficiency. Before going to books, let’s use 100 W/m2 on a horizontal surface from a cloudy sky, about 10% of the maximum we’d get from the sun (more on that as the course progresses). In winter, we’ll solar energy 9-10 hours a day, or about 40% of the time. With a solar-collector efficiency of 50%, we’ll get an average of 20 W/m2 of useful thermal power. Over 100 m2, we get an average of 2000 W, within about 10% of what we need. After-the-fact note: Lechner lists 300 Btu/ft2 per peak winter day on the horizontal for Medford, Oregon, a cloudy climate. This corresponds to about 900 Wh/m2 or 100 W/m2 over 9 hours. Windows or skylights for solar gain What’s the best orientation for an opening, in winter? South-facing windows take in more solar energy on clear days than do horizontal skylights. How about cloudy days? To keep things simple, let’s compare with the solar collectors with the same insolation, 100 W/m2 over 40% of a 24-hour day. Give the window a (perhaps wishfully high) transmissivity of 80%. It’s taking in more energy than the solar collector, but will also have more heat loss than an insulated wall or roof. If we cover the entire roof with windows of R 1 in SI units, the heat loss for the house increases to 5600 W. The heat gain from the sun increases from 2000 to 3200, not enough to make up for the increased losses. For a cloudy day, horizontal glass is a loser. What if we insulate the windows during the dark hours (60% of the day)? Then the heat loss decreases to the weighted average of 2270 W (60% of the time) and 5600 W (40% of 2 the time), or 3600 W. This is only 12% or so more than the heat loss, enough to make it interesting. After-the-fact note: Murdoch (p. 375) states that the illuminance on a vertical surface under an overcast sky is about 400 footcandles, which corresponds to about 4000 lux or 40 W/m2. On the horizontal, the value is about 80-100 W/m2 (when the sun, hiding behind the clouds, is about 20-25 degrees above the horizon). Our intuition seems about right. Photovoltaics for heat Does it make sense to use PV for heat, as distinguished from an application that provides power for lights and appliances? No. PV cells have a relatively low efficiency. Let’s assume 15% for now. So we only get 600 W of electricity if we cover the roof. No good for electric resistance heat. Even with a heat pump that produces three Watts of heat for every Watt of electrical input, we’re at 1800 W, no better than solar thermal collectors. Bury the building Earth has higher thermal conductivity than many insulating materials, but it can make up for that with thickness. Let’s take the limit of finding a 200 m2 cave, so far underground that the cave temperature is the yearly average air temperature, which we can take to be 5 C. This will also be the temperature of the earth surrounding the cave. Let’s build an insulating box, with the same amount of thermal insulation. Then the heat loss is reduced from 2270 W to 1100 W (here we include the floor). So our need for solar collectors has been chopped in half. An aside: are people a thermal winner or loser? Interesting question. So far, we have taken credit for making an airtight box. Even were that possible, would we want to do it? People need fresh air, to provide oxygen and remove CO2. People also produce heat, a help in winter. Which side of the ledger wins? ASHRAE, for office buildings, specifies 20 l/s of fresh air. Given the density and heat capacity of air, that leads to 24 W/K or 960 W per person. Yikes! Another calculation method starts with 0.5 ACH as a lower limit on infiltration, which matches 20 l/s if there are four people in the house. A person produces about 75 W of heat, only 8% of the heat needed to condition outdoor air. For a family of four, we have added about 3840 W, meaning that for this very well insulated house airflow is much more a concern than conduction. Can we possibly come up with another 3840 W? Or can we reduce the heat needed to condition outdoor air? A common approach – no integration here, simply an HVAC trick – is to use an air-to-air heat exchanger or an exhaust air heat pump. In either case, the idea is to wring heat out of air before it leaves the building. A good air-to-air heat exchanger can recover about 70% of the heat, but requires electricity for a fan. 3 Another approach is to use the walls or windows as heat exchangers, an attractive example of integration if it can be made to work. Walls naturally work in this way, to some extent: air that leaks in through a wall picks up some heat that would otherwise flow out by conduction. Facades in high-tech office buildings are engineered in some cases to bring air in through a circuitous path, to pick up heat flowing out. Another aside: where does structure come into play? For heating, structure serves two purposes that express an integration with HVAC. Put another way, we want other building systems to provide heating in lieu of a dedicated HVAC system. First, we need exposed mass to soak up heat on rare sunny days, to prevent overheating and ease the burden on solar collectors. Second, we do not want structure to form thermal bridges, which will increase heat losses. Post-and-beam construction with stress-skin rigid-foam panels are one solution, because the panels entirely cover the structure. Electricity for lights and appliances Here’s where we need to consider PV or wind. Consider a winter day, with minimal daylight hours. Let’s say we need lighting for 60% of a 24-hour day, at 10 W/m2 for half the house or 1000 W. For the remaining 40% of the time, we’ll hope we get enough daylight. (We can estimate this, taking it beyond wishful thinking.) The average lighting power is 600 W. Too much! In a house larger somewhat larger than 200 m2, monthly electricity usage might be about 400 kWh for everything (lights, fridge, washer, electric dryer). This is an average of about 550 W. For a zero-energy house, it is reasonable to expect to use the most efficient lamps and appliances. Maybe we can get down to 400 W on average. Covering 100 m2 with photovoltaics could provide about 600 W, as noted above. The extra could be used to power a fan needed to push air through wall or window cavities or a dedicated air-to-air heat exchanger. Note that the 400 W of electricity is dissipated as heat, which reduces what is needed from solar gain (through windows or via solar collectors). Can windows or skylights provide enough light to eliminate the need for electric lighting? One rule of thumb for commercial buildings is that daylight should be acceptable within 5 meters of windows. Clearly depends on the size of the windows. We’ll learn later how to calculate this. Another approach is to take the 100 W/m2 on the roof and convert it to lux, or lumens/m2, using 100 lumens/Watt. We then have 10,000 lux outside the glass and say 8,000 inside. If we want 300-500 lux and we lose about 50% to absorption by room surfaces, we would need 5% roof openings for a single-story house and 10% for two-story (plus a means of piping light down to the first floor). So using at least some skylights, insulated at night, would appear to be a good idea because they bring in light as well as heat. 4 We have neglected cooking. For now, live on peanut-butter sandwiches. Can think about generating more electricity or using a solar cooker or biomass or simply give up. After-the-fact note: Baker (p. 45) shows that we can get a daylight factor of 2% (2% of outdoor horizontal illuminance indoors) about 3 meters in from a wall with 30% glazing. For an outdoor illuminance of 10,000 lux, we would get 200, marginally acceptable. Daylight will not be sufficient further from the window, unless the window is larger. Cooling For the climate chose, cooling is a bit challenging but less so than heating and electricity for lighting and appliances. At first glance, it’s hopeless: the diurnal average outdoor temperature exceeds the specified upper bound on thermal comfort And solar gain, heat from occupants, and heat dissipated from lights and appliances only make things worse. But there’s a trick. The occupants can open the windows or doors and hope that wind-driven airflows are sufficient to bring the indoor temperature down to a level close to the outdoor temperature. But this is not a good idea in the heat of the day, when the outdoor temperature rises to 35 C. The occupants could shut up their house entirely. If the house were sufficiently massive (here’s the integration of structure and HVAC again) and if there were no internal gains, the indoor temperature would vary little over a day and would equal the outdoor average temperature. But with 400 Watts of electricity and 300 Watts from sensible body heat, the indoor temperature would rise 5 C (which can be easily calculated with the same heat-flow equation shown above). Can the smart occupants combine the two strategies? Yes!! They can open up at night, when it is cool, and shut up in the hot day. What’s the limit to this? Clearly, it cannot get cooler inside than the outdoor minimum, which is 25 C. That value may not be practical, but it is reasonable to try to reduce the indoor peak temperature to a value lower than the diurnal average outdoor temperature, 30 C. Here’s a way to estimate what can be done. Imagine cooling down the structural mass or dedicated thermal mass (tubes filled with water, for example) to 25 C at night. Over a 15-hour period with the windows closed, heat from lights and occupants (700 W total) amounts to 10,500 Whr or 37.8 MJ (3600 J equals 1 Whr). If we want the mass to heat up to 28 C and no more, how much do we need? If water, with a heat capacity of 4200 J/kg K, we would need 3,000 kg. The density of water is 1,000 kg/m3, so we need 3 m3, an achievable amount. Concrete in building mass should also work. 5