Florida Permaculture Chicken Coop From Recycled Materials

Survival Garden Chicken Coop Constructed From Salvaged Materials

Sustainability is based on a large part in the practice of recycling and reuse of all materials.  

We were fortunate to be gifted with some used roofing tin and scrap wood from a local truss builder.

The hens feel right at home!

All it needs now is a #Greenroof and stormwater catchment system :)

August 23, 2011 Green Roof Biodiversity, Rooftop Garden, Breaking Ground Contracting, Jacksonville - Kevin Songer - Picasa Web Albums

Green Roofs always offer different scenery in the afternoon light. As the day progresses and temperatures rise, the insects and pollinators begin to show up en masse! Though rooftop temperatures are hot, the plants reduce the urban heat island effect and create an oasis in the urban core.

Green Roof moth & Zinnia

August 23, 2011 Green Roof Biodiversity, Rooftop Garden, Breaking Ground Contracting, Jacksonville - Kevin Songer - Picasa Web Albums

Another Interesting Green Roof Factoid

We had a very hot day yesterday and a cold night last night. Yesterday's temperatures of the roof under the asphalt shingles soared near 130F, 55C in the bright Florida sunlight, then dipped into the low 40's F, 4C this morning.

Interestingly, the uninsulated roof decking under the asphalt shingles followed the outside air temperature and quickly fell below the decking under the green roofs. In fact, early this morning there was a 15 degree F difference between the green roofs and the asphalt shingle roof with the asphalt shingle decking being considerably colder than the decking under the green roofs.

The green roofs stored the solar heat yesterday, during the mid-day and slowly released the heat during the night as the outside air temperatures plummeted.

The more data collected the more we see just how green roofs moderate temperature swings.

Green Roof Xericscape Primary Design Variables & Rooftop Polygons

Interestingly, according to the USEPA, Americans use approximately 1.5 billion gallons of water every day on landscaping.  Contrast this over-looked wealth and waste to the realization two hundred million hours each day are spent by families across less developed nations without adequate water infrastructure in securing daily domestic water supplies, some carrying heavy jugs of muddy water on their backs great distances.

Here in the U.S. we use twice as much water for landscaping than the number of gallons of gasoline we burn in our automobiles daily.  With the present U.S. population estimated to be about 311,000,000 persons, landscape water use is on the average about 5 gallons per person per day, or about 19 liters per person per day.  Yet fortunately many governmental agencies are presently encouraging use of native species and wildflowers acclimated to reduced watering or nature based irrigation.

So, if sustainable development practices call for conservation of water in the landscape then irrigation in green roofs should be no hidden exception.  

Because roof ecosystems are subject to significantly harsher biophysical conditions than most ground level landscapes, industry response sometimes has typically been one of adding irrigation and fertilizers to hopefully mitigate additional heat, dryness and desiccating wind stressors typically impacting green roof plants.  Moreover, because the green roof industry here in the US is still relatively young there is a lack of detailed design data to assist in planning and installing nature irrigated green roofs.

Fortunately water conservation practices in green roof design can be simple and cost-effective.   Though one can delve deeply into design theory, effective nature irrigated green roof design theory can truly be best understood with spending time outdoors in and around the project site, looking up and paying attention to what is already there.  We shall see that though we can model design variables in an attempt to analytically predict ‘what works best on a green roof’ sometimes a walk through the town, looking up to see what plants grow naturally in gutters, in the cracks of mortar and across roofs, provides the most useful design information.

To fully understand the design criteria needed for a nature irrigated, native species and biodiversity focused green roof we must first divide the rooftop area into simple polygons that are representative of existing environmental factors.  We want to know where on the roof areas are exposed to harsh, desiccating winds and we want to know where on the rooftop the sunlight becomes either lacking or unbearable.

Understanding these rooftop design variables is made easier through the use of rooftop polygons and there are two abiotic categories of green rood design variables to be used in calculating roof polygons;

• Primary Variables, and
• Secondary Variables.

Primary Variables include those variables that may vary based on individual roof polygon, including;

• Light, and
• Wind.

Secondary (yet important) variables include those design inputs remaining generally consistent across the roof and not considered in the roof polygon calculation.  They are;

• Heat Zones
• Cold Zones
• Precipitation and Water Vapor Profiles
• Smog
• Allopathic Plants Nearby, and
• other variables.

Though not used to determine the roof polygon boundaries, the secondary variables play an important role within a design model considerations and we will discuss those interactions in detail in future sections. 

Importantly, certain light wavelengths are required for photosynthesis.  Without light photosynthesis does not occur and plants do not grow.  Light is the first primary design variable to be considered when creating roof ecosystem polygons.  Understanding where on the roof photosynthetically reactive radiation and light volume measured by Daily Light Intervals or DLI is critical to good green roof design.

Wind is the second of the primary design factors used to determine roof ecosystem polygons.  

Though ambient outside air temperatures, precipitation, air quality and other design variables are generally consistent across the roof, light availability and wind effects can change depending upon where one stands on the same roof.  Both light and wind are critical factors in designing a green roof for dry and arid climates.  Without adequate light plants will not live and consistently buffeted by desiccating winds plants may cease to transpire and quickly die.

Over the next couple of weeks we will be exploring xeric green roof design variables.  First, as an introduction to developing rooftop polygons an Youtube powerpoint presentation is included here for review.

The presentation was used as an introduction for native plants on green roofs but has a solid explanation of rooftop polygon development included.  After reviewing the powerpoint you will have an understanding of rooftop polygon development, and how the two primary design variables can be incorporated into the green roof model.

Further discussion of why light and wind are the two primary green roof design variables will be included in subsequent articles.  Enjoy the powerpoint worksheet.  TOmorrow's post will discuss in length why light and wind are te two primary design variables for green roof plantings.

CAM Plants for Green Roofs, Effects of Heat and of Humidity

We discussed how some cold tender CAM plants, such as many of the succulents, can be damaged by freezing temperatures.  CAM plants are called CAM plants because they possess a specific form of metabolism called Crassulacean acid metabolism.

The CAM metabolic process helps succulents and other CAM plants survive in dry, arid regions by working to keep stomata closed during the day when high temperatures and hot drying winds.  If temperatures are high, the sun is bright and stomata are open the plants can rapidly dehydrate. 


CAM plants open stomata at night when temperatures are cooler and solar radiation minimal.  When stomata are open CAM plants take in carbon dioxide (CO2) and store the CO2 in their leaf cells.  Once the sun rises and temperatures increase, CAM plants close their stomata and take the CO2 absorbed from the evening air and begin photosynthesis, producing the substances the plant requires and also oxygen, O2.

An analogy I like to use in comparing CAM plants to C3 plants is thinking about the difference between a gas guzzling 1970's sedan as compared to a new hybrid-type car with a highly efficient engine.  The C3 plants' metabolism is like the 1970's V8 gas guzzler - they both take in lots of fuel, fire up quickly, get to where they are going/growing quickly but are inefficient with respect to fuel utilization.  In the 1970's V8 wasted, unburned fuel leaves the engine as exhaust.  In the C3 plants we see volatilization and evaporation out of the leaf of photosynthesis substances through numerous opened stomata.  Yet both get where they are going/growing - quickly!

CAM plants though are like the highly efficient hybrid electric/petroleum engine.  In addition to conserving CO2 and preventing desiccation by keeping their stomata closed during the day, they are also very efficient at uptaking and using nutrients like nitrogen.  Because a CAM plant's CO2 is limited, the plants have developed mechanisms to become ultra-efficient at nutrient utilization.  Little is wasted.

Because of CAM plants adaptations to hot, arid, dry and drought-like conditions, they make great green roof plants and have been used historically across Europe as such.

Interestingly, some plants like the sedums can switch back and forth between the C3 and CAM metabolic processes depending upon the amount of water and nutrients available in the environment.  This process is called acclimation and is very similar to what we may imagine a grizzly bear's hibernation may be like.

Sedums are considerably more cold hardier than many of the other succulents that are members of the Crassulacaea family and so are popular in colder climates as green roof plants.  Some sedums are so popular for use on green roofs that they have become pest plants, exotic invasive species displacing some types of native vegetation.

Several CAM plants (Agave) surrounded by C3 plants

However, though CAM plants are excellent at surviving heat, aridity, and bright solar radiation and frost if protected, another climatic condition often is a limiting factor.  Though CAM plants, if protected can survive freezing temperatures and certainly can survive long periods of drought, many are susceptible to humidity-heat combination related issues.

Sedums and other succulents are highly prone to fungal attacks during the summer months when the temperatures range between 90 F and 100 F (35 - 37C).

The Southern Blight fungus, Sclerotium rolfsii, also known by the common names 'crown rot' and 'white mold' can decimate a well established roof of succulents or sedums.  Fortunately, southern blight does not seem to bother the succulents during cooler or dryer months.  However the everyday rainfall and resulting high air water vapor combined with high temperatures found during the summer months produce an environment just right for Sclerotium rolfsii, to proliferate.

CAM plants (Graptopetalum) with C3 and C4 Green Roof Plants

But what does all this technical information about photosynthesis and botany have to do with green roofs?

For the nature irrigated green roof, an understanding of C3, C4 and CAM plants and their advantages and disadvantages, their benefits and their limitations, is critical for a successful design.

Green Roof Succulent Injured by Southern Blight

As we continue our discussion of C3, C4 and CAM plants over the next several days we will begin to clearly see how 'Right Plant, Right Place' is important even on green roofs.

Water supplies are limited across the world.  We cannot continue to rely on irrigation use of potable water on landscapes or green roofs.

Designing a nature irrigated green roof will require utilization of a combination of C3, C4 and CAM plants, planted on the roof according to a number of biophysical variables we will discuss.

And so, to date we now understand that CAM plants are ideal for arid, hot areas and can survive drought.  We also know CAM plants may be susceptible to frost or also to fungal attacks encouraged by hot, humid weather.  We know C3 plants grow quickly.

Finally, as we discuss other important factors about plants suitable for a nature irrigated green roof we will begin to develop a sense of understanding as to the type of plant that will work long term on the green roof if planted in associations with other plants and in the right roof location.

As always, email us with questions or comments and Happy Green Roofing!  Kevin

Florida Green Roof Hurricane Simulator Testing This Month

MetroVerde assembled a 4' x 10' extensive green roof panel in early 2009 for research at the University of Florida.

The green roof was assembled over an asphalt shingle roof decking.

Allium and other drought tolerant species were planted in the 2" thick engineered soil over a woven PPE  1/2" thick anchoring mat.  Blue spruce sedum was also used however this species did not thrive on the non-irrigated system.

The panel was exposed to full sun in an area with little to zero shade.

Over time the Allium species established good rooting architecture and began to fill out the vegetated roof panel open space.

The roof is now scheduled for Hurricane simulator testing with winds up to 120 MPH - either this week or next week.

We will keep you posted on results.

Happy Green Roofing!

Kevin

Top 5 Reasons for a Green Roof in Florida

Today I want to reiterate the top five reasons for installing a green roof in Florida.

There are actually many advantages to having a vegetated roof and living walls here in the southern portion of the U.S.

However, understanding the main benefits from volumetric green helps in the justification process.  In today's economy cost-effectiveness is important, both short-term and long-term.

After working with green roofs here in Florida for years, these are the top five reasons I would recommend to anyone for installing a:

1. lightweight, extensive (less than 4" deep - preferably 2-3" deep),
2. non-irrigated (hey - we have a water crisis in Florida - and you WILL have to have backup potable water if you rely on rainwater cisterns to irrigate a roof),
3. cost-effective green roof

are:

1.  Protects underlying roof, extending the life of your underlying roof by decades.
2.  Provides significant insulation (the difference is between 40 degrees F and 60 degrees F),
3.  Cleans stormwater - especially for those designed to not require fertilization,
4.  Creates wildlife habitat and in-turn an IPMS - an Integrated Pest Management System - the lizards and anoles you attract will eat pest insects such as termites, ants, roaches and flies.
5.  Cleans stormwater and creates a Sense of Place (beauty).

Other very important reasons include;

1.  Sequestering and lowering Carbon Footprint,
2.  Uptake of CO2
3.  Production of O2
4.  Reduction of Heat Island Effect
5.  Reduction of Stormwater Runoff volume (in addition to water quality),
6.  Increased pedestrian traffic for retail areas,
7.  and more (i.e. Green Building Cert Points).

So you see there are many reasons to build a green roof.

What are you waiting for?

For help with system selection and design, please send us an email today!

Happy Green Roofing!

Kevin