Constructing and Operating a Zone Four Greenhouse

Everyone gets started in the greenhouse hobby in a different way, I suppose. If you don't have the benefit of knowing someone who has a greenhouse and who can help you along, the choices can be overwhelming. Maybe my experience will inspire someone who really wants one but can’t get "off the fence" and underway to GET GOING.

In the late eighties I had been water gardening, in a small way at least, for about ten years when I added a couple of tropical water lilies to my collection. Immediately I was faced with the issue of what to do with them over the winter. Some merely treat them as annuals and throw them out. Others elect the wet sand or other storage technique similar to that used to over winter garden bulbs. But in zone 4 it takes too long to get a water lily going in the short summer, and besides that I had the idea of enjoying blossoms all winter. That was the beginning of my basement "greenhouse". In March 1991 an article which I wrote describing that effort was published in the Water Garden Journal--The official publication of the International Waterlily and Water Garden Society, Inc.. With permission, a version of that article is reproduced (here), together with some comments based on ten years or so of experience with it. While on the subject of water gardening organizations, you will find the Water Gardener's International website to be a very informative and enjoyable place to visit often.

Greenhouse space is much like computer memory—you never have enough. After the addition of a few more non-hardy water plants, visits to the Caribbean and an ever growing obsession with tropical plants, the basement GH was soon full to overflowing. Several issues were just not solvable: 1. The room was so tightly packed that watering was achieved only with great difficulty. I finally used a 6 foot length of PVC pipe with my watering can to reach many of the plants. The addition of an automatic watering and misting system only partially solved the problem and created a rat’s nest of tubing. 2. Because of the need to keep the lights fairly close to the plants, only the lower 4 or 5 feet of the room was really usable. 3. The electrical input to the room necessary to operate the lights kept the room too hot—around 85 degrees or more most of the time. In the evening, when the lights went off and the temperature dropped a bit, the humidity skyrocketed and mold became a constant problem. The addition of automatic venting controls just didn’t seem warranted for such a small room. 4. Although money wasn’t really a driving issue, I was using about $800 of electricity per year to light the room. 5. What started out as a method of keeping the plants alive over the winter so they could be put outside in the summer backfired. Except for the water plants, everything started dying back in the summer, due to the cool evenings and unpredictable daytime temperatures, and needed the winter in the basement to recover. What started out as the simple matter of carrying out a few pots in the spring became a monumental, back breaking chore as plants (including trees) grew and multiplied. With my tenting and outdoor activity going full swing in the summer, very little time was available to enjoy the plants, anyway.

It became an exercise in frustration. I had three options: 1. Get rid of 90% of it. By then my obsession with tropical specimen plants had outgrown my original water gardening hobby, and this simply was not an option. 2. Move to a warmer climate. Unless willing to move to southern Florida or to some similar growing zone, some method of protection such as a greenhouse would still be necessary. Family connections and a love of skiing also weighed strongly in favor of not moving. 3. Build a greenhouse. With hindsight, this decision was long overdue!!

The most difficult and pondered decision was where to put it. Ours is a typical suburban home on a 100 x 150 foot lot with trees in all the wrong places. The texts and references, of which there are many good ones, instruct on how to analyze shade over the four seasons, how to orient the structure to receive the best light and even how to pick the best roof angle to maximize light entry. But those instructions were just not consistent with my requirement that it be attached to the house in some way so that I could have easy access in all weather and in all seasons. The final solution was to construct a hallway from the family room to a point where the winter shadows didn't reach and start the GH at that point. In order not to block the view of the woods to the rear of the house, the GH had to be angled 90 degrees from the ideal and a large tree had to be removed. The rationale that tropical specimen plants tended to require relatively low light levels proved correct. In fact, considerable shading is required in the summer, both to keep the plants from scalding and to keep the temperature under control. A somewhat site-related problem is that in the winter the short days combined with the perpetually cloudy skies in this area induce rather deep dormancy in many plants, most particularly the water varieties. Better orientation would possibly alleviate this situation, but spot artificial illumination may be the best solution if I decide to keep those species. If you are going to raise high energy plants such as tomatoes, etc., you should pay more attention to orientation and get the most sun possible. Bear in mind that the plants on the near-to-sun side of the GH will shade other plants if they are tall, so you will need to place them accordingly. If everything is on waist-high benches it won't be as much of a problem. The winter sun is surprisingly low in the sky, and shadows can get quite long.

Single pane glass is the traditional greenhouse glazing. It is easy to clean and is transparent, but it is a horrible insulator and breaks easily. Even if heating cost was of no importance the constant condensation, water running down the walls and even ice formation would be unsatisfactory. Vulnerability to hail (a constant problem in my area) falling limbs and small boys also make glass unsatisfactory. One GH manufacturer offers an option whereby a second layer of removable panes could be added, thereby increasing the insulation factor, but the added insulation in my view was not significant and the task of removing the panes for cleaning seemed far out of proportion to any benefit. Several manufacturers offer double insulated glass sealed with inert gas and containing ultra violet (UV) and infra red (IR) barriers, but this arrangement is quite expensive and should be combined with professionally installed framework. This, in addition, requires an appropriate foundation. The result is a beautiful greenhouse if you can or want to afford it. Although I was not in a position to have to look for the least expensive approach, the professionally installed aluminum and glass structure was simply beyond my obsession. Having raised the subject of insulation factor, here is the appropriate place to talk about it. If you are considering building your own GH or in having someone build it to your specifications you will need to have an understanding of it and may even want to "crank through the numbers".

Simply put, the insulation factor, or "R" value of a substance, is a representation of how rapidly heat will pass through it. Four factors determine how much heat will pass through: The R value, the surface area, time and the temperature difference between the two sides. "Amount of heat" is represented by British Thermal Units, or BTU's. A BTU is the amount of heat necessary to raise one pound of water one degree Fahrenheit. Heaters are rated by BTU per hour (BTU/hr). The equation that ties all this together is:

Where A=the area in square feet and T=the temperature difference between the inside and the outside.

To work with the equation, we need to know a couple of things about the GH. First is the temperature value for the equation. Lets assume the worst case nighttime temperature will be - 20 degrees F. and under those conditions you don't want the inside temperature to go below +50 degrees F. That makes T=50- (-20)=70. Next, we need to know the total area of the glazing. Let's assume 727 square feet (guess where that number came from). Finally, pick a number from Table 1. Let's use 1.0, which is what double pane glass would give.

25,000 BTU is a common heater size, and I didn't want to use two heaters Furthermore, there's something you need to know about gas heaters. Heating units such as household furnaces, greenhouse heaters, etc. are rated with BTU INPUT. It is the OUTPUT you are interested in. Manufacturer's can't guarantee the efficiency, which is dependent upon things that the user does. Older household furnaces may be about 60% efficient, whereas the latest models may be 90% or more. I selected the 25000 BTU vented Southern Burner heater. I still feel it was an excellent choice after 2 winters of operation. After consultation with the manufacturer, I finally came to the conclusion that the usable output was about 16000 BTU.

Not wishing to compromise on the size (area) of the GH and not knowing about the existence of multi-wall polycarbonate at the time, I was stymied for nearly a year. Only after a visit to A World of Orchids in Kissimmee, FL was I aware of the possibilities of that material. The equation now became:

Still not enough. I compromised by saying that at temperatures below zero I would rely on supplementary electrical heat, but that still would not keep the internal heat to 70 degrees without supplemental heat, which is what I needed for the tropical plants. The first winter of operation proved that assumption to be correct, although I never did have to use an electrical heater to prove the point. Then I had an idea: By stapling (stainless steel staples!!) clear, 6 mil plastic to the internal framework on the sides and ends, I could add more than 2 inches of dead air space--another R of 1 to those surfaces--thereby, raising their R value to 3.5. The equation now became:

Close enough! Some other factors give a bit of safety to the number: 1. The outside door is sealed with 2" of pink poly in the winter. 2. The vents are sealed with pink poly and plywood in the winter. 3. The thickness and cumulative effect of all the framing effectively reduces the overall area, and 4. The portion of the structure which connects to the hallway to the house is not exposed to the outside temperature.

The UV coating on the polycarbonate should provide protection from the sun and extend the life of the plastic. The need to clean the area between the plastic and polycarbonate has not arisen in over a year so far. A possible downside of this arrangement for some would be that the light transmissibility of the polycarbonate is something like 80% which is further reduced by the addition of the plastic sheet. I have not found this to be a problem.

Having made the decision that aluminum framework was too expensive, the choice of construction material became wood frame. There are some really nice looking wood framed units available from a number of manufacturers, but two major drawbacks forced me to reject all of them: 1. The framework did not appear to me to be strong enough to withstand the snow load that might be expected and 2. The triple wall polycarbonate glazing was not available--at least not in anything close to what I thought the price should be. I needed design drawings and a specification.

The size of your greenhouse will, to a large degree, be dictated by your budget (or the size of your obsession). Just remember--whatever you build will be small on the day you move in. In my own case, a 14' x 20' floor area was the largest I could accommodate with one heater. It has given me plenty of room and although it went over budget it worked out about right. As far as cost goes, the price doesn't relate directly to size, because of fixed, or relatively fixed, costs which are independent of size. Examples of these are the heater, ventilation system, foundation, doors, lighting and any access passageway.

I can't emphasize enough the importance of the foundation in a cold climate. In my area the building codes require that the foundation footing be below the frost line, which can be 4 feet. You wouldn't want to violate that rule anyway, because frost heave would cause too many problems over the years.

It should be insulated. In my own case, I use a dirt floor and have many specimens planted in the soil near the foundation. Heat loss could not be tolerated near or below the ground. All the plans of a well insulated GH can be ruined by a lossy foundation.

The footing should be tiled and drained. If you are not sure of your soil percolation or if you have no drain field then install a sump pump. Believe me--I know!! I could write a humorous story on that subject (it wasn't funny at the time)!

You basically have two choices--either concrete block or pressure treated wood. Concrete block is the traditional choice, but it throws another contractor into the loop, and after it's all done you still have to go through the added insulation process. Pressure treated wood sounds a little spooky on the surface. After all, wood rots--right? Not this stuff. It works great and can be insulated as it is being constructed. It has the additional advantage that you can nail, screw or otherwise fasten things to it easily. I added brown aluminum flashing, on the outside, to mine as a finishing touch.

Making drawings and a specification is not as difficult a job as it might seem. Even if you plan to do all the work yourself you still need to prepare them for the zoning review. The zoning permit and process was simple for me--practically non existent--but for some it could be quite formal and demanding. The technicality of whether or not it classes an addition to the home and how it affects your home value and insurance are details you need to work out with your builder, the zoning officer and your insurance agent. Here are the drawings and specifications that I used:

___________________________________________________________________________________________________________

Drawings and Specifications for a Greenhouse/Addition

DESCRIPTION

A. General

This document contains the drawings and specifications for the construction of a residential greenhouse attached to the dwelling at (Location). Figure 1 shows an artist's sketch of the existing dwelling, the polar orientation and the location of the addition. Figures 2 shows the east elevation and Figure 3 shows the north elevation. The 14' x 20' x 8' greenhouse shall maintain a semi-tropical environment during the entire year for the purpose of housing a private horticulture collection. Integral to the greenhouse is an enclosed passageway which shall allow comfortable access to the greenhouse from the dwelling under all weather conditions.

The construction of the greenhouse and passageway shall be aesthetically similar to the main dwelling.

The greenhouse meets the Town of (your town) side and rear offset requirements of 10 feet and 30 feet, respectively. The actual offsets are approximately 62 feet from the rear and 25 feet from the side.

B. Construction

Construction of the project shall be divided into two phases. Phase I includes site layout, excavation, grading, foundation, passageway, and utilities. Phase II includes the greenhouse framing, glazing and equipment.

Phase I

a. Site Layout--The addition shall be square with the main dwelling.

b. Excavation--Excavation includes that necessary for the foundation and utilities.

c. Grading--Grading includes that necessary for foundation backfill and the lawn area designated on Figure 4 to prevent water runoff from accumulating against the foundation. Some grading is also necessary inside the greenhouse. Note that there is about one foot of slope from greenhouse end to end. It is desired to level the interior finished soil surface and the door sills with the lowest point of the outside soil (the north end). The interior finished soil shall be one foot in depth, achieved by removing the existing clay/shale hardpan and replacing it with topsoil.

d. Foundation--The foundation shall be constructed so that footings are below the frost line in accordance with Figure 5. Note that the two doorways to the greenhouse are to be at approximately ground level for ease of entrance, requiring that the foundation be relieved at those points. Foundation insulation is to be applied to the passageway as well as to the greenhouse. Dimensions relating to the passageway and the distance of the greenhouse from the main dwelling are nominal. Dimensions relating to the greenhouse proper are measured along the outer surfaces of the framing and are exact. The greenhouse length dimension is arrived at in the following manner (see Figure 9 and Appendix A1, A2, and A3.): Sheet width = 4'. H profile = 5/8". Assembly tolerance and thermal expansion (each edge) = 1/8". 48 + 1/8 + 1/8 + 5/8 = 48 7/8". This places studs on 48 7/8 / 2 = 24 7/16" O.C.

e. Passageway--The passageway shall be constructed in a manner similar to the main dwelling. Siding and roof slope shall match except as stated below. The slope of the shed roof above the entrance area to the main dwelling should come as close as possible to the slope of the main roof, however it will probably be limited by the clearance between the roof joist and the door. Compromises in this area may have to be made to achieve a satisfactory appearance. The interior of the passageway shall be left unfinished, and the floor shall be dirt. A pressure-treated wood landing with stairs to facilitate exit from the

Figure 1. Dwelling at (Location)

main dwelling shall be provided. No insulation other than the foundation shall be provided, however the treatment of the wall under the siding shall be consistent with typical, well insulated house construction. The entrance doorway to the passage shall be located as close to the family room window as practical. This will be the limiting factor as to the start of the passageway. The door shall be a standard 2' 6" door similar to other interior doors used in the downstairs area of the house. A portion of the family room baseboard heater will have to be shortened to make room for the door, and electrical wiring in the wall may have to be relocated. The clothesline canister shall be relocated to the north wall of the passageway. The floodlight shall be relocated, but the relocated position is yet to be determined. It is desired that there be no wood exposed to the weather (no painting).

f. Utilities--Hot and cold water, natural gas and electricity are to be supplied to the greenhouse electrical box, heater and sink as shown in Figure 4. Gas and water connections shall be provided with shutoff valves at both ends of the lines. Water valves at the house end shall be equipped with drains. The hot water pipe shall be insulated. Water pipes shall be underground to provide freeze protection.

Phase II

a. Greenhouse Framing--All lumber exposed to the greenhouse interior shall be pressure treated. Nails shall be galvanized and screws shall be stainless steel. Construction details are outlined in Figures 6, 7, 8, 9, 10 and 11.

b. Glazing--The greenhouse glazing material shall be clear, 16 mm triple wall polycarbonate. Glazing, attachment extrusions and related hardware are described in Appendix A1, A2 and A3. Note that it appears as though the extrusions must be slipped onto the panels from the end, because of the difficulty in installing from the side. This being the case, the walls must be installed first due to the roof overhang.

___________________________________________________________________________________________________________

Table 1. Insulation R-Values for Common Building Materials
Material	R Value
Single Pane Glass	0.7
Double Thickness Glass	1.0-1.25
2" Dead Air Space	1.0
1" Pink Poly	5
2" Pink Poly	10
Wood (1")	1.0
Concrete (6")	1.63
Dual Glass with Argon Gas	2.3
Dual Glass with Argon Gas and Special Tinting	3.7
Dual Glass with Argon Gas, Special Tinting and Film Barrier	4.8
6 mm Dual Wall Polycarbonate	1.6
8 mm Dual Wall Polycarbonate	1.7
16 mm Tri Wall Polycarbonate	2.5

	Down comes the tree.
	Laser guided backhoe--accurate to 1/8 inch!
	Back hoe work completed
	Installing the foundation. Fabricated off-site
	Framing going up--1/8 inch tolerances!
	Installing the triple-wall polycarbonate
	View from above
	View from the road
	View from the side
	Rear View #1
	Rear View #2