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==Construction==
==Construction==
Very complete description of how final project is made. This large section should have lots of pictures.  
The construction of the roof took a combined total of four days with the effort of two people at a time.


===How to Build===
===How to Build===

Revision as of 01:48, 19 April 2015

Template:305inprogress

Abstract

Humboldt State University Engineering 305 class volunteered to construct a living roof for Bayside Park Farm a community farm in Arcata, California. The project would be the roof of an animal hutch that would simultaneously be built as this roof was being constructed. The type of living roof attempted to be created would be an extensive living roof because it would allow for the ability to be low maintenance and easiest to construct. Thus far the roof seems to be serving its purpose as a roof for a housing unit.

Background

Bayside Park Farm located in Arcata California in the United States and also goes by the name Arcata Educational Farm. It is a Community Supported Agriculture (CSA) facility that also acts as an educational farm. Our (Caroline, Mayara, and Amber’s) Engineering 305 class during the North American Spring 2015 semester will be constructing a functioning living roof. This living roof must attend to the owner's specifications regarding its dimensions and purpose, which are that the living roof be made on a small animal hutch that is currently being made. The construction and development of the living roof will span from January 2015 until May 2015.

Problem statement

The objective of this project is to create a functional, sustainable and sufficient living roof at Bayside Park Farm. A living roof also known as garden roof or green roof, is a roof that provides protection to the roof base and helps reduce water runoff and allows for some temperature regulation inside the housing unit. Furthermore it can be used for improving air and water quality, promoting energy conservation, providing food, and creating an ecosystem within an urban area. If possible we plan on using affordable or recycled materials that may be donated for the roofs construction and by doing so we will cut costs down for the construction of the roof. By doing this we aim to create a feeling of community involvement and create another area of the farm that may teach the community about an alternative to roofing.

Criteria

The criteria was defined according to the farms purposes and preferences, which were very loose and only asked that the roof serve as an educational tool that could be used over time. This criteria was used as a guide for the construction of the roof. Where values were higher is where the most effort was placed in providing those demands in the construction of the project. The scale (1-10) represents the importance level of the constraint of each listed criteria.

Criteria Constraints Weight
(1-10)
Functionality Must serve recreational and educational purposes.
10
Maintainability Must be low and easy maintenance.
8
Aesthetics Must be pleasing to the eye.
6
Safety Must be able to hold while put on a structure.
10
Weight Must be able to hold at least 20lbs per square meter.
4
Durability/Resistance Must be able to last for a long time and be weather resistant.
9

Literature Review

Living roof basics

The basic components of green roof systems are waterproofing, soil and plants. It really is that simple. The combination of these material is easy and the success of all living roofs depends on the types of plants used and an understanding of how these combined materials will work.[1] An understanding of the type of environment the roof will be located in is also important for the success of any living roof. For example here in Humboldt County earthquakes pose a risk as well as a high precipitation level in the fall and winter months, however in the spring and summer months there is little to no rain fall. Design should account for earthquakes and the forces it will create on the building as well as any irrigation or drainage components that will function during both during the wet season and dry season. These however are design features that should be asked when building the structural support and housing unit the living roof will be placed on top of before and during construction of both the roof and the house or structures for the roof. For the purpose of our project we were only asked to concern ourselves with the construction of the roof itself because the farm would be responsible for the hutch or housing unit and the structural support. This means we focused on the weather aspect of design for the roof. Living roofs are that simple especially for small designs. Living roofs are becoming increasingly popular in North America and are starting to show themselves in large scale industrial buildings. The design and construction of those types of roofs are a little more complex and a lot more labor intensive, but the end result is worth the effort

Living roof concerns

A main concern regarding living roofs revolves around the types of vegetation that is being used because the performance of the living roof is the plant communities. Concerns regarding the plant communities on living roofs deal with weather factors such as wind stress and over exposure to the sun, however in the literature the main focus has been on wind stress because plants are not generally accustomed to the heights that roofs generally are. There has been some practice of using native plant species because they are generally most accustomed to the region the roof is. However, in some of the literature discusses native plants not working on extensive living roofs because of the shallow soil depth generally found on extensive living roofs.This then means that not only is wind stress the main factor in determining the types of flora being used but that the rooftop itself is challenging for the survival of plants.[2]

Another more recent concern that has appeared during the increased popularity of living roofs is water-quality of the storm water runoff from living roofs. The literature suggestes that living roofs may act as another source surface-water pollution primarily because of the nutrient content found in the growing medium and soil used. [2] To combat this we tried to use soil and growing mediums that not only would maintain the health of the plants but that were already found on the farm. We went with a perlite and coco peat combination.

Types of Living Roofs

In the world that is living roofs there are generally two types of designs. They are intensive and extensive. More recently there has been the inclusion of a hybrid living roof that is a combination of these two types called semi-extensive.

Intensive

Suitable for underground garages and heavy buildings. Soil depth 15 cm. Areas is used as much as possible. Area has a high plant diversity. Conventional garden where plants tend to be maintained on an individual basis in the same way a garden ground level. High maintenance and irrigation system.[3][4][5] “Intensive green roofs are often accessible and are characterized by: deeper soil and greater weight, higher capital costs, increased plant diversity, and more maintenance requirements. The growing medium is often soil based, ranging in depth from 20–60 cm (8-24"), with a saturated weight increase of between 290 - 967.7 kg/m2 (60-200 lbs/sf). Due to the increased soil depth, the plant selection is more diverse and can include trees and shrubs, which allows for the development of a more complex ecosystem. Requirements for maintenance - especially watering - are more demanding and ongoing, and irrigation systems are usually specified.”[5] [6]

Advantages of Intensive roofs:

  • Diversity of plants
  • Good insulation properties
  • Simulate wildlife garden
  • Attractive aesthetically
  • Accessable/recreation
  • Longer membrane life
  • Energy efficient
  • Storm water retention capability

Disadvantages of Intensive roofs:

  • Greater weight load on roof
  • Need irrigation and drainage system
  • High maintenance and cost
  • More complex[5]

Extensive

Thin substrate depths 2-15cm. This means lower in extra loading. Cheaper and easy maintenance. Aesthetically looks the same as other living roofs. “The extensive solution is suitable for lightweight and low height buildings: the utilised plants are species of sedum, shrubs and bushes that need low maintenance and can be self-generative. [4][3] [6]

“Extensive green roofs are often not accessible and are characterized by: low weight, low capital cost, low plant diversity, and minimal maintenance requirements. The growing medium, typically made up of a mineral-based mixture of sand, gravel, crushed brick, leca, peat, organic matter, and some soil, varies in depth between 5-15 cm (2-6") with a weight increase of between 72.6-169.4 kg / m2 (16-35 lbs/sf) when fully saturated. Due to the shallowness of the growing medium and the extreme desert-like microclimate on many roofs, plants must be low and hardy, typically alpine, dryland, or indigenous. Typically the plants are watered and fertilized only until they are established, and after the first year, maintenance consists of two visits a year for weeding of invasive species, safety and membrane inspections.”[5]

Advantages of Extensive roofs:

  • Lightweight. Generally no reinforcement.
  • Suitable for large areas.
  • Roof slope 0degrees-30degrees
  • Long life and low maintenance
  • No need for irrigation or specialized drainage system.
  • Less technical expertise needed
  • Suitable for retrofit projects
  • Inexpensive
  • Looks more natural
  • Vegetation can grow spontaneously

Disadvantages of Extensive roofs:

  • Less energy efficient
  • Less storm water retention benefits
  • Limited choice of plants
  • Not accessible for recreation or other uses
  • Unattractive usually in the winter season[5]

Semi-Extensive

There is more information on semi-extensive living roofs out there, but the main idea behind the design is that it is low maintenance like an extensive roof, but has deeper layers for growing medium like an intensive roof has. Meaning high diversity of plants with low-input.[3]

Living roof design

The basic components of green roof systems are waterproofing, soil and plants. However, although the combination of these components seems easy, the success of green roofs systems depends on the understanding the interaction among the parts and its complexity. [1] A green roof is composed of different layers which are described below:

Layers

Layers gf.jpg
  • Deck Layer: is the foundation of a green roof and may be of concrete, wood, metal, plastic or a composite material.[7]
  • Leak Detection System (optional). Leak detection systems are often installed above the deck layer to identify leaks, minimize leak damage through timely detection, and locate leak locations. [7]
  • Waterproofing Layer: very important to prevent water damage through the deck layer. This layer must be entirely waterproof and long lasting. Several waterproofing materials can be used, like thermoplastic membranes, elastomeric membranes, modified bitumen polyvinyl chloride (PVC), applied rubberized asphalt, built up bitumen and others. The waterproofing material may be loose laid or bonded, which is more recommended. [7]
  • Insulation Layer (optional): usually located above, but sometimes below, the waterproofing layer. Its function is to increase the energy efficiency. Recommended for metal roofs.[7]
  • Root Barrier: used to protect the waterproofing membrane from root penetration.[7]
  • Drainage Layer: placed between the root barrier and the growing media to remove excess water from the vegetation root zone. Must consist of synthetic or inorganic materials. The thickness of the drainage layer type is an important design decision. For extensive green roof systems, the depth of the drainage layer usually varies from 0.25 to 1.5 inches thick and increases for intensive designs. [7]
  • Filter Sheet: consists in a “semi-permeable needled polypropylene filter fabric placed between the drainage layer and the growing media” in order to prevent the drainage layer to clog by the migration of some particles from the media into it. The filter sheet must allow the water migration into the drainage layer. [7]
  • Growing Media: usually 3 to 6 inches deep and composed of approximately 70 to 80 percent lightweight inorganic materials like clays, pumice, scoria or other similar materials. The remaining media must not exceed 30 percent organic matter because it can transport nutrients into the runoff from the roof and clog the permeable filter sheet. [7]
  • Plant Cover: it is the top layer and consists of plants that are non-native, slow-growing, shallow-rooted and perennial. The selected plants must be able to withstand harsh conditions at the roof surface. For drought periods it is recommended the installation of a watering system. [7]

Design

The living roof was designed based off the information given by the farm that the hutch being built would be a 4.5ft by 4.5ft structure. We were not told anything else about the hutch being built other than its proposed size. Because of the size of the roof it seemed practical to give the roof no more than a two degree slope to prevent soil erosion and allow water to drain naturally. Because we knew nothing of what the structure would look like we assumed an overhang of about three inches. The roof was asked to be built as low maintenance as possible therefore a simple one inch open was allotted for the back of the roof to allow water to flow backward naturally. INSERT EQUATION. Bpf livingroof design.jpg Bpf livingroof design 01.jpg

Construction

The construction of the roof took a combined total of four days with the effort of two people at a time.

How to Build

Image:roof_before.jpg
How to Build a Living Roof

Proposed timeline

Weeks Tasks Observation
16-Fev Prototype budget and get the materials
23-Fev Build the prototype
2-Mar Build the prototype
9-Mar Find donation, materials, weekly checks Wait until the plants grow
16-Mar Find donation, materials, weekly checks Wait until the plants grow
23-Mar Find donation, materials, weekly checks Wait until the plants grow
30-Mar Analyse if everything is ok, recalculate
6-Apr Build the real one
13-Apr Build the real one
20-Apr Build the real one
27-Apr Verify functionality
4-May Verify functionality
11-May Verify functionality

Costs

This is the budget for the roof. Almost all of the items were donated.

Quantity Material Source Cost ($) Total ($)
1 Pond liner-10ft x 12ft Donated by Pierson Building Center 00.00 00.00
1 Landscaping fabric-3' x 25' Donated by Pierson Building Center 0.00 0.00
1 Soil-28L Donated By Farm 00.00 00.00
1 Growing medium-6qt Donated by Pierson Building Center 0.00 0.00
1 Wood Glue-18oz Donated byPierson Building Center 0.00 0.00
36 Stainless Steel Wood Screws Donated by Pierson Building Center 0.00 00.00
1 Wood Preserver Paint-32 oz Donated by Pierson Building Center 00.00 00.00
1 Rubber membrane-5' x 6 ' Donated by Pierson Building Center 00.00 00.00
1 Shower Pan Liner Adhesive-16oz Donated by Pierson Building Center 0.00 0.00
5 Wood Donated By Farm 00.00 00.00
8 Plants Donated By Farm 00.00 00.00
1/4 Landscape Rocks Donated by Miller Farms Nursery 00.00 00.00
1 Drop cloth 9'x12' Ace Hardware 03.99 03.99
1 Paintbrush 3" poly Ace Hardware 02.99 02.99
1 Paintbrush 2-1/2" poly Ace Hardware 02.79 02.79
Total Cost $010.58

Operation

The roof should be very low maintenance with weeding being done once a year if desired.

Maintenance

The roof was designed specifically for low maintenance. The farm will have to do come light weeding once a year or once a season if desired. And check the health of the soil if desired.

Schedule

This is when to maintain weeds and if desired check on the health of the soil.

Yearly

Weed any unwanted plants. Make sure soil is healthy.

References

  1. 1.0 1.1 Weiler, S.K. and Scholz-Barth. 2011. "Green rood system: A Guide to the Planning, Design, and Construction of Landscapes over Structure".
  2. 2.0 2.1 Oberndorfer, Erica, Jeremy Lundholm, Brad Bass, Reid R. Coffman, Hitesh Doshi, Nigel Dunnett, Stuart Gaffin, Manfred Köhler, Karen K. Y. Liu, and Bradley Rowe. 2007. “Green Roofs as Urban Ecosystems: Ecological Structures, Functions, and Services. (Cover Story).” BioScience 57 (10): 823–33.
  3. 3.0 3.1 3.2 Dunnett, Nigel, and Noel Kingsbury. Planting Green Roofs and Living Walls. Portland: Timber Press, 2008.
  4. 4.0 4.1 Lazzarin, Renato M., Francesco Castellotti, and Filippo Busato. 2005. “Experimental Measurements and Numerical Modelling of a Green Roof.” Energy and Buildings 37 (12): 1260–67.
  5. 5.0 5.1 5.2 5.3 5.4 Peck, S. and M. Kuhn. 2003. Design Guidelines for Green Roofs (PDF) (22 pp, 551K). Canada Mortgage and Housing Corporation and the Ontario Association of Architects
  6. 6.0 6.1 "Green Roof Systems: Intensive, Semi-Intensive, and Extensive.".Architect's Technical Reference. Accessed February 8, 2015. http://www.archtoolbox.com/materials-systems/site-landscape/green-roofs.html..
  7. 7.0 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 "Hoffmann, G., Stack, R.C. and Wye, B.V. 2012. “Stormwater Management Guidebook”.
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