Introduction
Today more and more homeowners are growing bedding plants, vegetable transplants and house plants in greenhouses. These greenhouses are called hobby greenhouses. They are usually small in size but can be as large as a small commercial grower’s greenhouse.
The gardener who has a greenhouse can extend or intermingle the seasons at will. With the many types of heating and cooling systems available, temperatures can be maintained to keep you and your plants comfortable. Whether you wish to build your own greenhouse from scratch or purchase a prefabricated structure ready for assembly, there are several basics that must be met.
A hobby greenhouse can be a simple, polyethylene-covered framework that can be put together in one afternoon for less than one hundred dollars or it can be a six thousand dollar prefabricated structure.
No matter which size or type of greenhouse you choose, consider how much time you will have to spend in it after it is built. With automatic controls in your greenhouse and easy-care plants, maintenance can be kept to a few hours a week. Automatic controls are ideal for providing proper growing temperature, artificial light, watering, humidity and ventilation. If you have the time to regulate the environment, you can save a great amount of money by not using automatic controls.
Types of Greenhouses
There are two basic types of greenhouses: attached and freestanding. An attached greenhouse may be even-span, lean-to or window-mounted (Figure 1). A freestanding greenhouse is usually even-span (symmetrical roof) (Figure 2).
Attached Lean-To
A lean-to greenhouse is built against a building, using the existing structure for one or more of its sides. It is usually attached to a house but may be attached to other buildings.
The lean-to is limited to single or double-row plant benches with a total width of 7 to 12 ft. It can be as long as the building it is attached to. The advantage of the lean-to greenhouse is that it is usually close to available electricity, water and heat.
The lean-to has the following disadvantages:
- Limited space
- Limited light
- Limited ventilation and temperature control
Attached Even-Span
The even-span greenhouse is the standard type — the one people generally visualize when they think about a greenhouse. The even-span greenhouse is similar to a free-standing structure except that it is attached to a house at one gable end. It can accommodate two or three rows of plant benches The cost of an even-span greenhouse is greater than the cost of a lean-to type, but it has greater flexibility in design and has space for more plants. Because of its size and greater amount of exposed area, the even-span greenhouse will cost more to heat.
Attached Window-Mounted
Window-mounted greenhouses allow space to grow a few plants at relatively low cost for heating and cooling. This reach-in greenhouse comes in many standard sizes, either single units or in tandem arrangements for large windows. Simple tools are needed to remove the regular window from the frame and fasten the prefabricated window greenhouse in its place.
Freestanding
The freestanding greenhouse is a separate structure and consists of sidewalls, end walls and gable roof. It is like an even-span except that a freestanding greenhouse is set apart from other buildings to get the most sun. It can be made as large or small as desired.
A separate heating system is necessary unless the greenhouse is very close to a heated building. The freestanding greenhouse is more easily adapted to the builder’s ideas of location, size and shape than attached greenhouses. It also provides more light but requires more heat at night due to the additional surface area.
Locating Your Greenhouse
After you have decided which type of greenhouse you want, you will need to determine the best location for it. You will limit the types of plants you can grow if you do not put your greenhouse in the best possible location.
The site is of the utmost consideration. It determines what type of structure is practical; the direction and intensity of sunlight the greenhouse will receive, which will indirectly affect the plants you will be able to grow; the susceptibility of the structure to storm damage; and the ease and convenience of access as well as maintenance of the plants and greenhouse.
The most desirable choice for a greenhouse site is on the south or southeast side of the house in a sunny location (Figure 3). That is where it will capture the most sunlight from November to February. The east side is the second best location. The next best locations are the southwest and west. The north side is the least desirable location.
Contrary to popular opinion, which holds that a greenhouse should receive unobstructed sunlight, it may be highly desirable to provide afternoon shade such as that given by nearby deciduous trees. In winter, once the leaves have fallen, the greenhouse will receive the additional light needed at that time of year. Be sure to take into account the possibility of falling limbs that can damage the greenhouse.
Some plants will grow in a greenhouse no matter where the location is. African violets and orchids, for example, will grow in a northern exposure greenhouse, but heating costs will be high. Sometimes you can place a greenhouse against a door, window or basement entrance of your house. This location will let you use heat from your house to grow plants. It also makes your greenhouse more accessible and may save on construction costs. Your home heating bill, of course, will increase, but it may be less than if you had to heat your greenhouse separately.
Research has shown that a greenhouse that lies lengthwise north-south has less shade and thus more light than one that lies east-west. In a north-south oriented greenhouse, shadows move as the sun moves across the horizon, but in an east-west house the shadows tend to cover the same area throughout the day. This is not as important during the summer when light duration and intensity are high, but during the winter months sunlight duration and intensity are less. Therefore, less shadows mean more light available for plant growth.
Designing Your Greenhouse
What Size?
Having determined the type of greenhouse and its location, you should next decide on size. Select a greenhouse as large as your site and pocketbook will allow. The tendency is to start with a very small house, which quickly becomes filled to overflowing. Try to get as wide a greenhouse as possible, as it is easier to enlarge by increasing its length.
Greenhouse Width
In determining the greenhouse width, think where you plan to put benches and walkways. Side benches are serviced from only one side and should be no wider than you can reach across. For some people this will be about 2 ft, for others perhaps as much as 3 ft. Center benches are serviced from both sides and could be as wide as 6 ft. They should be no wider than what is needed for you to work comfortably.
The width of walkways in your greenhouse is determined by how the walkways are to be used. If they will be used only as a place to stand while servicing the benches, an 18- or 19-in. walk is sufficient. If a wheelbarrow will be brought into the greenhouse, the width must be greater. Wide walkways, 24 to 30 in., will allow easy passage for visitors who may not be used to walking between rows of plants.
The paths and floor of a greenhouse can be gravel, cinders, crushed stone, concrete, brick or other material. A hard surface such as brick or concrete is cleanest, most attractive in appearance and easiest to walk upon, but a loose surface absorbs moisture better and helps to maintain desirable atmospheric humidity. The areas beneath the benches should always be water-absorbent.
Greenhouse Length
The length of your greenhouse is best determined by the number of plants you plan to grow. Most 6-in. pot plants require a minimum of 1 square foot of bench space. Therefore, if you plan to have 100 plants, you would need a minimum of 100 square feet of bench area plus space for the walkways and aisles. Usually two-thirds of a greenhouse is bench space and one-third walkways and aisles. Always make the greenhouse 25%–50% larger than your original demands because most people keep adding plants to their collection.
Greenhouse Height
The height of the greenhouse depends on the desired height to the eave. An eave height of 5 ft is satisfactory for side benches used for low-growing plants. If you want to grow tall plants, however, you will want an eave height of 6 to 7 ft.
The pitch of the roof should be 6 ft in 12 ft of run (approximately 27 degrees). The eave height, the distance from the side wall to the center of the greenhouse, and the roof pitch will determine the height of your greenhouse at the center ridge. The height of the greenhouse should be equal to the eave height plus one-fourth the width of the greenhouse to maintain a 6-in-12 roof pitch. For instance, in an even-span greenhouse 18 ft wide, the distance from the side wall to the center of the greenhouse will be 9 ft. The difference in height between the center of the greenhouse and eave will be one-half of 9 ft or 4.5 ft with a 6-in-12 roof slope. If the eave is 5 ft high, the greenhouse should be 9.5 ft high at the center.
Types of Construction
Whether the greenhouse is covered with glass, fiberglass or polyethylene film, it will be advantageous to shop around. Greenhouses have a supporting framework made of wood, aluminum, iron and plastic. Some have curved eaves; others have flat eaves. Some are glass or plastic from the ground up. All types have advantages and disadvantages.
Most greenhouses constructed today are double-layered polyethylene Quonset houses. The Quonset frame is constructed from metal conduit pipe that does not block as much sunlight as does a wood frame. Wood also rots very easily, whereas a metal frame lasts much longer. Some greenhouses have a glass covering, but they usually have a metal frame to support the glass. Glass does not have to be replaced; polyethylene has to be replaced every 2 to 3 years. If you build your own greenhouse, the plumbing and electrical work should be done by professionals in accordance with local codes. Usually a building permit is required to erect a greenhouse.
Glass Greenhouse
Glass is the traditional greenhouse covering. It is available in many designs to blend with almost any style of architecture. Glass greenhouses may have slanted sides, straight sides and eaves, or curved eaves.
Aluminum, maintenance-free glass construction has very pleasing lines and will provide a large growing area. It assures you of a weather-tight structure, which minimizes heat costs and retains humidity.
For amateur gardeners, small prefabricated glass greenhouses are available for do-it-yourself installation. They are sold in different models to fit available space and to fit your pocketbook. The disadvantages of glass are that it is easily broken, expensive and requires a much better type of construction than fiberglass and plastic.
Fiberglass Greenhouses
Fiberglass is lightweight, strong and practically hailproof. Corrugated panels 8 to 12 ft long and flat fiberglass in rolls are available in 24- to 48-in. widths. Thicknesses range from 3/64 to 3/32 of an inch.
Poor grades of fiberglass will discolor, and the discoloring reduces light penetration. Using a good grade, on the other hand, may make your fiberglass greenhouses as expensive to build as a glass one. If you select fiberglass, choose the clearest grade. Do not use colored fiberglass. Tedlar-coated fiberglass blocks out ultraviolet rays so the material remains clearer for a longer time.
Plastic Greenhouses
Plastic greenhouses are increasing in popularity. The reasons are:
- Construction cost per square foot is generally one-sixth to one-tenth the cost of glass greenhouses.
- Plastic greenhouses can be heated as satisfactorily as glass greenhouses.
- Crops grown under plastic have the same quality as those grown under glass.
- Plastic greenhouses are considered temporary structures and usually carry a low assessment rate for tax purposes or may not be taxed at all.
Plastic greenhouses can be made of polyethylene (PE), polyvinyl chloride (PVC), copolymers of these materials and other readily available clear films. Polyethylene will last from 1 to 3 years depending on the type. Other films such as PVC or copolymers with ultraviolet (UV) inhibitors last longer. Descriptions of plastics available are provided below.
Polyethylene
The advantages of polyethylene are that it is low in cost and lightweight. It also stands up well in fall, winter and spring weather and lets through plenty of light for good plant growth. However, polyethylene constantly exposed to the sun deteriorates during the summer and must be replaced often.
Ultraviolet light energy causes polyethylene to break down. This first deterioration occurs along (or over) the rafters and along the creases where the film is folded.
Ultraviolet-inhibited polyethylene lasts longer than regular polyethylene. It has an inhibitor that prevents the rapid breakdown caused by ultraviolet light. UV-inhibited polyethylene is available in 2 to 10 mil thicknesses and up to 40 ft wide.
Polyethylene permits passage of much of the reradiated heat energy given off by the soil and plants inside the greenhouse. Therefore, a polyethylene greenhouse loses heat more quickly than a glass greenhouse both during sunny periods and after sunset. This is an advantage during the day and a disadvantage at night.
Polyvinyl Chloride (PVC or Vinyl)
Vinyls from 3 to 12 mils thick are available for greenhouse covering. Like polyethylene, vinyls are soft and pliable; some are transparent, others translucent. They are usually available in 4- to 6-ft widths only; larger widths can be made by electronically sealing several smaller widths together.
Vinyls cost two to five times as much as polyethylene. When carefully installed, 8- or 12- mil vinyl hold s up for as long as 5 years. Vinyl attracts dust and dirt from the air and has to be washed occasionally.
Acrylic
Acrylic is very transparent, very resistant to weathering and breakage, and can be used as a curved panel. However, acrylic is very expensive. Most quality fiberglass panels use a resin with 15% acrylic and 85% polyester.
General Type |
Comments | Typical Trade Names | Light (PAR) Trans- mitting (%) |
IR Trans- mittance (%) |
Est. Lifetime (years) | $/ Sq. Ft. |
---|---|---|---|---|---|---|
Glass | Advantages Excellent transmissivity; Superior resistance to heat, U.V. abrasion; Low thermal expansion/contraction; Readily available; Transparent Disadvantages Difficult to site fabricate; Low impact resistance unless tempered; High cost; Heavy |
Double Strength |
85 |
< 3 |
25+ |
0.75-2.00 |
Insulated Units | 1 | < 3 | 25+ | 3.50-7.00 | ||
Low Iron | 0–92 | < 3 | 25+ | 0.90-2.25 | ||
Acrylic | Advantages Excellent transmissivity; Superior UV & weather resistance; Won't yellow; Lightweight; Easy to fabricate on site Disadvantages Easily scratched; High expansion/contraction; Slight embrittlement with age; High cost; Relatively low service temperatures; Flammability |
Plexiglass |
93 |
< 5 |
20+ |
2.00-3.00 |
Double Wall Exolite |
83 | < 5 | 20+ | 2.50-4.00 | ||
Polycarbonate | Advantages Excellent service temperatures; High impact resistance Disadvantages Poor weatherability & UV resistance (yellows); Scratches easily; Not readily available; High expansion/contraction |
Lexan |
87 |
< 6 |
7–10 |
10.22–13.62 |
Double Wall |
75 | < 6 | 5–7 | 5.96–10.22 | ||
Fiber Reinforced Polyester | Advantages Low cost; Strong; Superior weatherability only when Tedlar coated; Easy to fabricate & install Disadvantages Susceptible to UV dust & pollution degradation; Yellows with age; High expansion/contraction rate |
Lasolite |
75–85 |
< 10 |
10–15 |
2.89–5.96
|
(Fiberglass) | Doublewall roof panels | 70 | 7–12 | 17.03 | ||
Laminated Acrylic/ Polyester Film | Advantages Combines weatherability of acrylic with high service temperature of polyester; Good transmissivity Disadvantages Nonreversible, acrylic must be installed to the outside; Susceptible to wind flapping; Only 4 ft width available |
Flexigard | 87 | 9.5 | 10+ | 1.53–2.38 |
Polyethylene Film |
Advantages |
Visqueen |
< 85 |
80 |
8 months |
0.07 |
Monsanto 602 (UV resistant) |
87 | 80 | 2 | 0.20 | ||
Monsanto 603 | 80 | 3 | 0.27 | |||
Weatherable Polyester Film |
Advantages |
Llumar Mylar Melinex |
85–88 | < 30 | 7–10 | 1.70–3.41 |
Note: Much of the technical information in this chart was taken from manufacturers' data. Actual field performance may be different. Costs are accurate as of May 2023† from regional distributors. Local prices may vary. † Estimated costs adjusted from 1981 figures to 2023 figures using https://www.minneapolisfed.org/about-us/monetary-policy/inflation-calculator |
Types of Frames
Plastic greenhouse structures range from crude wooden frameworks to air-supported houses. If you plan to build a plastic greenhouse, careful consideration should be given to economy of size and future expansion. Because plastic is available in large widths and is lighter in weight, greenhouse rafters and supporting members can be widely spaced to permit maximum light penetration. Common types of greenhouse frames are as follows:
A-Frame
In building an A-frame structure, consider the placement of cross members. Place them at least one-third of the distance down from the ridge. Otherwise, it will be difficult to work around the cross member in applying an insulating layer of plastic.
When the cross member support is high in the peak of the greenhouse, especially in narrow greenhouses, an essentially clear span type of structure permits easy application of an inner layer of plastic. The inner layer can be applied under the cross-rafter supports, leaving a small triangular air space in the peak of the house. This space serves as an insulation for the house. Diagonal bracing wires provide added strength to an A-frame structure. This type of greenhouse is among the least difficult to build.
Rigid Frame
Rigid-frame greenhouses have been designed in widths up to 40 ft. This clear span structure has no columns to hold up the roof section. It is designed for 30-, 36- or 40-ft widths.
Prefabricated greenhouses built with curved laminated wood rafters are commercially available. They have low side walls (low head room), and for tall plants the structure must be raised higher on the foundation side walls.
Panel Frame
Panel-frame greenhouses are a modification of the sash house (a small plastic greenhouse used for growing plants for later transplanting). This structure requires accurate carpentry, and construction costs are higher than for other frames because of the added lumber and labor needed to build the panels. Advantages of panels are that they can be quickly installed and taken down and stored during the summer. This will increase the life of the plastic panels. Panel greenhouses can be easily ventilated.
Quonset
Quonset greenhouses are oval in shape. Some have been constructed of wood, but usually the frames are constructed of pipe bent into the oval shape. The advantage of this house is the ease of construction and covering. Ventilation is by exhaust fans at the ends of the houses.
Beds for Growing Small Plants
Coldframes
A coldframe (Figure 4) is a bottomless box with a removable top. It is used to protect small plants from wind and low temperatures. No artificial heat is used inside a coldframe.
Coldframes utilize the sun’s heat. The soil inside the box is heated during the day and gives off its heat at night to keep the plants warm. The frame may be banked with straw or other insulating material to insulate it from the outside air and to retain heat.
With a coldframe, you can do many of the same things you do in a greenhouse. You can sow summer flowers and vegetables weeks before outdoor planting. Often, you will gain sufficient time to grow an extra crop. You can start vegetables, annual flowers for fall and winter, and perennials for next year’s bloom. Plants are protected from harsh weather and will grow to transplant size quickly . You can root cuttings of deciduous and evergreen shrubs and trees, as well as softwood cuttings of chrysanthemums, geraniums and fuschia, and leaf cuttings of rex begonnias. African violets and succulent and foliage plants take root faster in a coldframe, particularly during warmer months.
You can grow your own lettuce, chives, endives, parsley and green onions right through the winter by converting your coldframe to a hotbed.
Portable coldframes can be built in your workshop from surplus materials you may have on hand. Most coldframes can be converted to hotbeds for use in all seasons by installing electric heat and automatic clock-controlled misting or watering.
Hotbeds
A hotbed (Figure 5) is a bed of soil enclosed in a glass or plastic frame. It is heated by electricity, steam or hot-water pipes. Hotbeds are used for forcing plants or for raising early seedlings. Instead of relying on outside sources of supply for seedlings, you can grow vegetables and flowers best suited to your own garden.
Seeds may be started in a heated bed weeks or months before they can be sown out of doors. At the proper time the hotbeds can be converted into cold-frames for hardening. Then the plants may be moved to the garden when outdoor conditions are favorable.
Provide between 10 to 15 watts of electric heat for every square foot of growing area in a hotbed. Soil-heating tape or cable is available in several lengths, which give a choice of wattages. If the bed is in a sunny, well-sheltered location and the climate not too severe, 10 watts per square foot should be adequate. Lining the sidewalls with moisture proof insulation is desirable. Place tape or wire screening, 0.25- or 0.5-in. mesh, over the heating tape or cable to prevent possible damage by cultivating tools. Do not place hotbed cables of any type directly in peat. When peat dries out it acts as an insulator and may cause the cable to overheat. Use a thermostat to control temperatures automatically and make more efficient use of energy.
Because accurate temperature control is possible with a thermostat, you can grow better plants at lower costs by separating plants requiring different temperatures in different beds. Temperatures from 50 °F to 70 °F are best for hotbeds. On very cold nights cover the beds with mats, burlap, straw, or other insulating materials.
Greenhouse Heating
Economics will dictate what energy source you can use to heat your greenhouse, whether it be electricity, bottled gas, natural gas, wood or fuel oil. While large greenhouses will require a fairly complicated system, package units are available for most home greenhouses. When planning the heating system, it is important to follow directions to insure adequate and uniform circulation and to allow for a safety margin in heating capacity. Consider the possibility of future expansion when selecting a unit. In many cases, especially with lean-to units, it is possible to heat the greenhouse with an extension from the home heating unit and its own thermostat, or through a window or open door with a fan that blows in warm air from the living unit. The capacity of your heating system will depend on the size of your greenhouse, whether it is covered with a single layer or a double layer of plastic or glass, and the maximum difference between inside and outside temperature.
The firm from which you buy your greenhouse can tell you what size or capacity of heater will best suit your needs. Also, you can estimate the size of the heating system you need with ½ûÂþÌìÌà Extension Bulletin 792, .
Heating equipment can be a space heater, a forced-air heater, a hot-water or steam system, or electric heaters. Radiant heat lamps over plants and soil heating cables or pipes under plants are also being used.
The type of heating system you choose will depend on how much you want to spend.
Space Heaters
For low-cost heating for small greenhouses, use one or more ordinary space heaters with electric fans to distribute the warm air evenly. Warning: If you use a gas, oil or coal heater, be sure to have a fresh air supply and an unobstructed chimney so carbon monoxide will not build up. Remember, all greenhouse heaters should be ventilated for both plant and human health. Use high grade (low sulfur) kerosene to avoid sulfur dioxide damage; the need for high ignition temperature to avoid carbon monoxide and ethylene buildup is important.
Forced-air Heater
The best system for heating a small greenhouse is a forced-air furnace with a duct or plastic tube system to distribute heat. The polytube is best placed down the length of the greenhouse in the top ridge. The polytube evenly distributes the heat throughout the house — thus no cold spots. You can use a thermostat to control the temperature in the greenhouse.
Hot-water or Steam Heater
A hot-system with circulator or a steam system linked with automatic ventilation will give adequate temperature control. Bench heating with hot water is becoming more popular for localized heating. In some areas coal or natural gas is readily available at low cost. The fuel is ideal for a hot water or central steam system. Steam has an advantage in that it can be used to sterilize growing beds and potting soils.
Electric Heater
Overhead infrared heating equipment combined with soil cable heat provides a localized plant environment that allows plants to thrive even though the surrounding air is at a lower than normal temperature. Electric resistance types of heaters are used as space heaters or in a forced system. Electric heat can be very costly and is usually used only in very small greenhouses.
Temperature
For most greenhouse plants a night temperature of 55–65 °F in the greenhouse is adequate. The minimum temperature in most situations is 40 °F, and the maximum temperature is 85 °F. The general rule, however, is not to have a higher temperature than is necessary.
As a gardener you will be concerned with two temperatures—the air temperature required in the greenhouse and the minimum outside temperature that your heating equipment must overcome. The temperature we are most concerned with is the minimum night temperature, but we also want to know what is the ideal daytime temperature to keep the greenhouse. On bright sunny days it is best to have day temperatures 10 to 15 °F higher than night temperatures. Daytime temperatures on dull, cloudy days is usually kept about 5 °F above the nighttime temperatures.
If you want a temperature of 60 °F, install heaters that will provide that temperature. If you want no more than frost protection, set the thermostat at 40 °F. Higher temperatures on plant benches can be provided with soil-warming equipment.
In any greenhouse you will find microclimates such as those found near the outside walls, furthest from the heater or closest to the floor. There are always cooler areas where certain plants will do better than others. By selecting plants for certain locations, you will get better use of your greenhouse. Remember that heat is lost from a greenhouse by radiation, conduction and convection through the covering, the walls and other non-glass parts of the structure, the floor or soil, ventilation, door openings and cracks.
Greenhouse Ventilation and Cooling
Ventilation and cooling are equally important, especially in southern climates. Ventilation-cooling systems range from manually operated vents to fully automatic systems regulated by an in-house thermostat. In these days of escalating fuel and electrical costs, it might be wise to grow those plants that tolerate a cooler temperature during the winter and to switch to heat tolerant plants during the summer.
Ventilation
A greenhouse is a heat trap. Much of the radiant energy from the sun enters the greenhouse, but the reflected energy from interior surfaces, such as walls and benches, is trapped in the form of heat energy. Some of the heat is lost through the walls and roof. But when the outside temperature is almost the same as the inside temperature, very little heat is lost. Without ventilation the air temperature inside the greenhouse may become so high that plants are injured or killed.
Even during cold weather a greenhouse can get too warm on bright sunny days. So an adequate ventilation system must be built into your greenhouse to control temperatures in all seasons. If you use hand operated roof vents, they will have to be opened and closed periodically during the day. As outdoor weather changes, sashes must be opened and closed manually to keep plants from getting too hot or too cold. An automatic ventilation system eliminates the manual work and is the best way to control temperature and humidity in a greenhouse.
A thermostat will respond to changing air temperature and activate the ventilation system to keep temperatures in an acceptable range. Fans are needed to provide good ventilation in both large and small greenhouses. In recent years exhaust fans have replaced flow-through ventilation as the major means of cooling hobby greenhouses. Exhaust fans should be large enough to change the air in the greenhouse one to one and one-half times every minute.
Fans and duct (sometimes known as polytube) ventilation can also be used for automatic greenhouse heating and ventilation. Polyethylene ducts are suspended by wires or straps from the roof of the greenhouse. The fan-heater-louver unit gives positive air flow and the polyethylene duct distributes the incoming air evenly throughout the house.
Shading Your Greenhouse
When protection from the sun is needed, use roll-up screens of wood (lath fence) or aluminum, vinyl, plastic shading, or paint-on-materials. Roll-up screens are available with pulleys and rot-resistant nylon ropes. These screens are attractive and can be easily adjusted from outside as weather and sunlight vary.
Vinyl plastic shading is made of a flexible film that reduces light from 55% to 65%. The material comes in rolls and installs easily against the glass inside your greenhouse. To apply, just wash the glass with a wet sponge and then smooth the plastic onto the wet glass. When smoothed into position, it adheres to the glass. It can be pulled off and used again. Shading compound can be applied on the outside of greenhouses to lower temperature and light intensities. These compounds usually come in choices of white or green. A shading compound that mixes with water is easy to use and readily available from greenhouse supply firms. Some people use a readily available latex paint from the local paint store, mixed 1 part latex paint to 20 parts water. However, it is much better and safer to buy a commercially prepared greenhouse shading compound.
Evaporative Cooling
An evaporative cooler (or fan and pad system) cools incoming hot air and adds beneficial humidity to the greenhouse atmosphere. The exhaust fan pulls hot, dry air from the greenhouse, the replacement air is cooled passing through the wet pads, humidity is increased and watering needs are reduced. You can select a cooling system of the right size by following directions in ½ûÂþÌìÌà Extension Bulletin 792, . In hot, dry climates an evaporative cooling system can reduce incoming air temperature between 10 and 30 degrees. In wet, humid climates the cooling is less, with the most effective cooling coming in the hottest part of the day.
Other Greenhouse Necessities
It is advisable not only to have both hot and cold water outlets handy but to have regulating valves leading to a common outlet to provide room temperature water throughout the year. The number of outlets should be proportional to the size of the greenhouse and number of benches.
Benches themselves should be comfortable to work with. This means a working height of 36 in. and a width of no more than 40 in. Naturally, a center bench can double this width. Bench construction can be of wood, aluminum and other materials. The best wood for benches is redwood or cypress. Other woods must be thoroughly treated with preservative. Other suitable materials can be sheet metal, corrugated asbestos sheet with a pea-gravel top layer, stretched hardware fabric, or a very permanent structure such as poured concrete. Galvanized pipe legs and braces are an ideal framework for the benches. Regardless of the construction used, be sure that the benches are level, as this facilitates watering and stability of potted plants.
Automatic controls are important in greenhouses. Lights, fans, pumps, heaters and mist systems must be turned on and off at prescribed times. Without automatic switching, precise control can be a complicated and laborious task. Time clocks, photocells, thermostats and other automatic controls are available commercially. Individual controls or combinations of controls provide interval control as desired.
Automatic controls can be many jobs. A thermostat can turn the heater on when the temperature drops to a certain point. Humidistats are available to regulate humidifiers automatically. Automatic ventilators, controlled by a thermostat, open the vents and turn on the fans. Automatic misting is also very important if you propagate many of your plants. Automatic watering devices can also be used. The water requirements of plants vary so much that this segment is going to require very close attention. Remember, automatic controls are costly and you may want to add some of them after you get started.
Plans
Click on the plan to view and print the diagrams. Alternatively, view in the PDF layout using the download PDF button at the top of the page.
Hotbeds and Cold Frames
- USDA 5941 Cold Frame-Greenhouse
Greenhouses
- CT 238 A-Frame
- USDA 6251 Plastic
- USDA 6181 Home
- CT 210 Fiberglass
- CT 252 Attached Greenhouse and Solar Collector
- MC 2802 Attached Solar Greenhouse
Miscellaneous
- USDA 5980 Plant Growth Chamber Roomette
- NY IB40 Potting Bench
References
Aldrich, R. A., Bailey, W. A., Bartok, J. W., Jr., Roberts, W. J., & Ross, D. S. (1978). Hobby greenhouses and other gardening structures. NE-77 Northeast Regional Agricultural Engineering Service, Cornell University.
Badger, P. C., & Poole, H. A. (1979). Conserving energy in Ohio greenhouses. Extension Bulletin 651, Cooperative Extension Service, Ohio State University, Columbus, Ohio.
Bailey, W. A., Liu, R. C., & Klueter, H. H. (1977). Building hobby greenhouses. Agricultural Information Bulletin Number 357. U.S. Government Printing Office.
Bartok, J. W., Jr., Ross, D. S., White, J., Roberts, W. J., Aldrich, C. A., & Parsons, R.A. (1982). Solar greenhouses for the home. NRAES-2, Northeast Regional Agricultural Engineering Service, Cornell University.
Roberts, W. J., Bartok, J. W., Jr., Fabian, E. E., & Simpkins, J. (1985). Energy conservation for commercial greenhouses. NRAES-3, Northeast Regional Agricultural Engineering Service, Cornell University.
Worley, J. (2005). Greenhouses—Heating, cooling and ventilation (Publication No. B 792). University of Georgia Cooperative Extension. /publications/detail.html?number=B792
Status and Revision History
Published on Feb 23, 2009
Published on May 14, 2009
Published with Full Review on Feb 16, 2012
Published with Full Review on Feb 20, 2015
Published with Minor Revisions on Nov 17, 2023