Attached greenhouses offer an oasis right off of your home, an extra living space through the winter, shared heating, and reduced construction costs because of a preexisting north wall. They can be any size, and they don’t necessitate the extra paths and infrastructure that a separate structure would. At the same time an attached greenhouse will almost certainly obstruct the view to the outside and without a screen door can introduce insects to your home. They carry some risk of unwanted humidity without a sliding glass door and proper ventilation. Also, your design will be bounded by the preexisting conditions of the house that you want to retrofit.
In North America the optimal orientation for a greenhouse is usually directly south or southeast, because in cold climates it’s important to capture the early morning sun. An east-facing orientation can work as well, especially if there is some glazing with a southern exposure. In most situations western orientation or exposure should be avoided because of the potential to overheat.
These recommendations, by the way, should be understood to be guidelines, not hard and fast rules; it’s important to examine your situation carefully. In regions where it’s cloudy for most of the winter, such as the Northwest, orientation is less important because the cloud cover diffuses sunlight over the entire sky. Also, at higher latitudes, the summer sun moves much farther north.
A greenhouse that is shorter than it is wide doesn’t have as long a window for solar gain during the day. At CRMPI, my Mana greenhouse is 24 × 35 feet and tends not to work as well as the 76 × 26 foot dimensions of Phoenix. This difference is because the sun has a lot more time in the day to heat up a space with a long east-west axis. It’s an especially important consideration if you’re building a freestanding greenhouse.
A good rule of thumb is a 3:1 size ratio.
There are many different materials and methods for building foundations, and you can use any that apply to building other structures to a greenhouse. At CRMPI the most recent foundations I’ve used have been concrete piers (see image below) tied together with the framing of the structure. Two earlier greenhouses here used sunken pressure-treated wooden posts for foundation footers.
It’s easy to overbuild greenhouse foundations because they are only holding up glazing and occasional snow loads, but depending on engineering regulations in your area and your approach to permitting, your options may be limited. Liability concerns can also be a factor in a school or business setting.
Though Phoenix’s roof has a slope of 4/12 (falling 4 inches for every foot of length), at EcoSystems Design we typically plan for a 6/12 slope to shed heavy snow loads, depending on the climate of the region. Because the greenhouse is warmer than the outside air, a layer of snowmelt often forms between polycarbonate glazing and snow, helping the roof to shed any snow of significant weight. Snow tends to stick more to double-inflated poly.
Related to the roof slope is the freeboard, the space between the lowest point of the roof and the ground. In areas with heavy snow, at least 3 or 4 feet is good to have so that snow won’t pile back up onto the greenhouse roof or obstruct any vents.
Framing and Glazing Materials
The two most common framing materials are wood and metal. Wood is excellent for smaller greenhouses and has the advantage of being a cheaper, familiar material that is easier to work, with or without specialized tools. Salvaged, rough-sawn, or beetle-kill lumber is readily available. Wood requires greater upkeep; although depending on the type of lumber, it can easily last fifty years in a dry climate with the proper paint and maintenance.
Nearly all commercial greenhouses today are made with galvanized steel, often designed to be connected in a long series. Kit greenhouses are most often made of steel, and the included fasteners and instructions can make assembly quite easy. Galvanized steel has a much longer life span than wood and doesn’t require staining, sealing, or much maintenance. As shown by the roof slope of Phoenix, steel framing often offers less flexibility in construction, especially when salvaged from other projects.
Glazing options are constantly evolving. Six-mm double- inflated poly will be cheaper, more flexible, and less insulating, while more expensive, rigid polycarbonate panels tend to last longer and hold up better against snow. Double-inflated poly was an excellent cheaper option in the early years at CRMPI, and it continues to function well on the roof of several of our greenhouses.
Glass can be appropriate for eastern or southern walls, but it should be used only for vertical glazing because of its considerable weight. Mounting problems can occur because of expansion and contraction, and glass presents a much bigger problem than polycarbonate or plastic if it breaks. It is typically more expensive and less insulating than polycarbonate and will also tend to intensify direct sunlight, which can even burn plants in some cases.
Insulation is essential on the north wall and the west wall; make sure to insulate all the walls you do not have glazing on. Foam insulation or structural insulated panels (SIPs) work well but need to be sealed and kept dry—they aren’t rated for the humidity in a greenhouse. I used these panels when constructing Phoenix, but commercially we’ve started to use metal siding directly against the Styrofoam on the inside of the SIP to eliminate any wood product. There’s a lot of room to implement your own preferred method here. Straw bales are a popular natural building method but probably not a good idea for use in a greenhouse because of the potential for mold problems in a high-humidity environment.
Beds and Paths
People often want to install large paths to accommodate carts and wheelbarrows, but think carefully about the way you’re going to be using your greenhouse.
After the initial construction and bed preparation, there isn’t much need to bring large amounts of material in and out. Here at CRMPI I tend to build smaller pathways to maximize growing space, and I keep a large staging area near the door to bring mulch and materials in with fifteen-gallon nursery pots.
Each greenhouse creates a new macroclimate inside it, but within that can be a variety of microclimates. These will be produced by your design and the materials used and may change over time with the addition of thermal mass by water tanks, more plant biomass, or new infrastructure.