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Difference between revisions of "CCAT greenhouse rainwater catchment"

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Image:con7.jpg|Originally we had the storage units on a wood pallet, this didn't last because the weight of the storage proved to be too much for the integrity of the wood ''prototype stage''
 
Image:con7.jpg|Originally we had the storage units on a wood pallet, this didn't last because the weight of the storage proved to be too much for the integrity of the wood ''prototype stage''
 
Image:con4.5.jpg|Convaience system that was found at CCAT that we were able to reuse for this project ''construction''
 
Image:con4.5.jpg|Convaience system that was found at CCAT that we were able to reuse for this project ''construction''
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Image:con9.jpg|The gutter system ending over the placement of the convenience system so the water flows directly into it ''construction''
 
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Revision as of 03:47, 13 May 2019

Engr305 Appropriate Technology page in progress
This page is a project in progress by students in Engr305 Appropriate Technology. Please do not make edits unless you are a member of the team working on this page, but feel free to make comments on the discussion page. Check back for the finished version on May 23, 2019.


Background

Outside CCAT sits a sloping glass greenhouse. Many changes have occurred in and around the structure during its time at the Campus Center for Appropriate Technology including separation from the main building, construction of a new wall using beach grass as insulation, and a floor reconstruction that's occurring concurrently with our project to build a rainwater catchment system for the greenhouse. CCAT wanted a rainwater catchment system to be built off the greenhouse to catch the rain that would just run down the building and into the ground beneath below. The water captured from the rain will ensure that the plant life at CCAT will be adequately watered when necessary.

The CCAT Greenhouse as of February 21st 2019

The CCAT Greenhouse when facing North West
The CCAT Greenhouse when facing East
The CCAT Greenhouse when facing West

Problem Statement & Criteria

The greenhouse at the Campus Center for Appropriate Technology doesn't have a renewable system to ensure the flourishing of the plants inside. The objective of this project is to build a rainwater catchment system for the greenhouse at CCAT to employ the use of our local weather patterns to water the plants within and outside of the greenhouse. With this renewable source CCAT can reduce their carbon footprint and create a sustainable resource to utilize.

Below is the criteria for the greenhouse rainwater catchment system. The criteria is scaled on a 0-10 high.

Criteria Constraints Weight
(1-10)
Functionality System is expected to run efficiently and effectively
9
Safety Must be in a secure location where it is easily accessible, also must be out of walkways, doorways, and head space
10
Aesthetics Must be pleasing to look at and enhance the CCAT environment
5
Budget Project will not exceed team budget
7
Durability Must be compatible with structure
8
Adaptable/Maintenance The structure should be able to be adjusted and mended
7
Accessibility Filtered rainwater should be easily accessible
7
Pairability Repair greenhouse cracks
6
Simplicity Weight should be minimal
5
Purpose Successfully captures and stores rainwater, educate, and be used for solar shower
10

Literary Review

This Literature Review will cover aspects of our greenhouse rainwater catchment at CCAT. Including, the climate for the area, filtration types to use, CCAT background, and overall design of rainwater catchments.

Climate

This project takes place at CCAT located on the campus of Humboldt State University in Arcata, Californa. Arcata receives about 46 inches of annual average rainfall with a annual average temperature of about 53 degrees Fahrenheit. The city recieves its most rain during the months of November,December, January, and February. An average year in Arcata receives 175 days of sun and on average, 77 days of precipitation.

CCAT Greenhouse

The CCAT greenhouse is located outside of the CCAT building in Arcata, California at Humboldt State University. The greenhouse is constructed of a Beach Grass Clay Slip Wall and a Sturdi-Built prefabricated greenhouse structure. The frame is made of redwood, which is resistant to decay. Preventing decay in a greenhouse structure should be cheap, effective, and non-toxic to plants and animals. The highest recommended solution against wood rot is redwood stain. With the high amount of rainfall that is present in Humboldt County, it is important to ensure the structure is secure. During the Summer the greenhouse requires additional water. In addition to the greenhouse, water is needed to care for surrounding plants and crops. Agriculture is the largest consumer of freshwater. By cutting down the overall water needs for CCAT's agriculture and greenhouse, it can become a high opportunity for a positive environmental impact.

Rainwater Catchment Design

Rainwater design has been worked with for millennia. Ancient civilizations in modern day India and Israel are recorded using catchment methods as early as 3000 BC and later on the Romans developed vast systems of aqueducts, gardens, and pools all fed by rainwater. Since then rainwater catchment has gone into and out of style many times as other technologies developed, but it remains the most reliable and renewable way of attaining access to water.

There is no one way to catch rainwater and design varies depending on many different variables including location, weather patterns, end usage, community utilization, etc.

Catchment design can be broadly categorized into active and passive systems, where active is a system that is built and maintained through human activity and passive is a system mostly in place in the environment that is initially worked on and then maintained by humans. We'll focus on active systems as the project we are working on will fall into that category. In active systems there are some fundamental components.

1. Catchment Surface - Where the rain is falling

2. Conveyance - Transports water from catchment surface to end use

3. Screens - Filters out debris

4. First Flush - Diverts initial most dirty water

5. Storage - Holds water til later use

6. Purification - Cleans water for desired use

7. End Use - Gives the system purpose!

For each of these components there are different materials and technologies you can use.

The main parameters for these systems are rainfall, catchment area, collection efficiency, tank volume and water demand. Systems should be tailored specifically to the community they're serving, so a good place to start you design process is on the ground with the people who will be using it.


Water Filtration Systems for Purifying Rainwater Catchment Systems

1. To Catch the Rain

Filtration basics

Water Filtration is essential to the end use if for human consumption, however, many uses do not require filtration like the first flush or plant use. Filtration concerns

  • Unfiltered Rainwater is not to be to be ingested by humans. Different treatment methods effect different pathogens. Many purification treatments are used in combination.

Types of Filtration

Common filtration materials include Canister filters, Activated carbon filters, Ceramic Filters, Hollow fiber membrane filters,Slow-sand filters, Bioremediation, SoDis, Solar pasteurization, Solar distillation, Boiling, Reverse Osmosis, UV, Chorination, and Electrochlorination.

Designing interpretive materials

According to To Catch the Rain,interpretive materials for rainwater filtration should include a filter, sometimes a structure to hold the filter, and a connecting storage and conveyance point.

2. Rainwater treatment in airports using slow sand filtration followed by chlorination: Efficiency and costs

Filtration basics

Rainwater catchment can be highly valuable as for non-potable settings such as airport complexes. Cost efficient, this method is valuable in this setting because of the large catching surfaces. Based out of a mid-sized airport in Brazil, this system studied the performance of slow sand filtration by chlorination and cost effectiveness. Overall, this project resulted in 60% cost efficiency compared to current water supply per cubic meter, ultimately providing chemical and biological-free water.

Filtration concerns

Not labeled for human consumption

Types of Filtration

Slow Sand filter following Chlorination filtration.

Conclusion

According to the Resources, Conservation, and Recycling book, 70% of the company’s non-potable water can be accounted for by this rainwater catchment and treatment system.

3. Effective removal of microbial contamination from harvested rainwater using a simple point of use filtration and UV-disinfection device

Filtration basics

Focusing towards utilizing of harvested rainwater for alternative water source on privately-owned cisterns in Arizona, this treatment uses Point of Use (POU) and UV filtration.

Filtration concerns

Originally, the untreated water contained levels of lead, Enterococci and E. coli, POC filtration sufficiently cleaned the rainwater of most contaminates.

Construction

In this section, we will be going over the construction of the the project. This will include some of the design stage, the prototypes that were created and though of, construction of the rainwater catchment system, and finally the final results.

Proposed timeline

Week 6:

  • Tentative Timeline
  • Tentative Budgets
  • Go over some Prototyping
  • Alternative solutions
  • Meet with CCAT

Week 7:

  • Timesheet #2
  • Prototypes done
  • Designed for desire and function
  • More definitive Budget
  • Make more definitive solutions
  • Meet with CCAT
  • Meet with Lonny

Week 8:

  • Possible buying of construction materials
  • Meet with risk management and facilities at school to make sure we can begin working at CCAT
  • Meet with CCAT
  • Meet with Lonny

Spring Break

Week 9:

  • Project Photos
  • Meet with CCAT
  • Meet with Lonny
  • Catch up with other groups and see if we can learn from/help each other
  • Start Construction
  • Work on appropedia page

Week 10:

  • Observations and Interviews II
  • Meet with CCAT
  • More Construction
  • Work on appropedia page

Week 11:

  • Appropedia Draft page done
  • Meet with CCAT
  • Meet with Lonny
  • Construction

Week 12:

  • Timesheet #4
  • Meet with CCAT
  • Construction
  • Catch up with other groups and see how they are doing to help each other with projects

Week 13:

  • Meet with CCAT
  • Meet with Lonny
  • Construction
  • Work on appropedia page more

Week 14:

  • Talk with class as a whole about project updates and see if anyone has any ideas for ours
  • Meet with CCAT
  • Begin working on Appropedia final draft
  • Begin work on final presentation and videos

Week 15:

  • Final presentation due
  • Finish final video

Cost

Quantity Material Source Cost ($) Total ($)
6 PVC pipe Ace 7.00 42.60
1 Storage Tank, 50 Gal Resale store 33.00 33.00
1 Filter Resale store 5.00 5.00
2 Gutter Resale store 4.00 8.60
1 Silicon Hamanaka Painting Donation Donation
1 Nails Ace 3.70 3.70
1 Aesthetics TBD 50.00 50.00
Total Cost $223.70

Refrences

Kinkade-Levario, Heather Design for Water: Rainwater Harvesting, Stormwater Catchment, and Alternate Water Reuse New Society Publishers, Jun 1, 2007

Grafman, Lonny To Catch The Rain Arcata. Humboldt State University Press, 2017

Mun, J.S. "Design and operational parameters of a rooftop rainwater harvesting system: Definition, sensitivity and verification" Eleviser Volume 93, Issue 1 (2012)

http://www.appropedia.org/CCAT_greenhouse/OM

http://www.appropedia.org/CCAT_greenhouse

http://www.appropedia.org/CCAT_Beach_Grass_Clay_Slip_Wall