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Vermifilter toilet

From Wikipedia, the free encyclopedia

Vermifilter toilet, also known as a primary vermifilter, vermidigester toilet, tiger toilet[1][2] or tiger worm toilet,[3] is an on-site sanitation system in which human excreta are delivered from a toilet (usually by flushing) onto a medium containing a worm-based ecosystem. Faecal solids are trapped on the surface of the vermifilter where digestion takes place.[2] Liquids typically flow through drainage media, before the effluent is infiltrated into the soil.[2]

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  • Vermicomposting: How worms can reduce our waste - Matthew Ross
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Transcription

Think of all the food made in the world each year. Hard to picture? Then, imagine that you are all of humanity, and on a plate in front of you is the one lovely annual meal you make for yourself. You did all sorts of work putting that meal on your table. You must be eager to consume the fruits of your labor. And the vegetables and meats and waffles of your labor, too, right? Well, oddly enough, a third of that meal ends up in the trash. A third of the food we eat globally, an estimated 1.3 billion tons ends up as waste. All the work we put into producing that food is wasted. And what's worse, it costs us. America alone spends an estimated 165 billion dollars a year managing food waste. We're wasting food, energy, and money. Perhaps worst of all, we're wasting the chance to change, to make the system of food consumption more efficient. If you want to bring on that change, you should know about a humble yet diligent and ever-so-crucial ally: the worm. Worms convert organic waste and other compostable products into natural fertilizers. Up to 75% of what we put in the waste stream can become food and bedding material for vermicomposting. You can create a worm bin in your own home to see the composting process in action. First off, you need worms and not your typical earthworms. You need redworms, eisenia foetida, the species responsible for most vermicomposting in North America. These red wigglers are surface dwellers who don't burrow too deep, they're optimal feeders around room temperature, and they're well-suited to converting organic waste into usable fertilizer. Now, your worms might be vermin, but they need a comfortable space to live and work: some bedding materials, either shredded paper or cardboard, some moisture, and, of course, food, mainly, your leftovers, slightly decomposed table scraps. The worms break down food waste and other organic matter into castings, a fancy synonym for worm poop. Their excrement is absolutely teeming with microbes, which continue the decomposition process, making all those once-wasted nutrients available again as fertilizer. The timeline for the whole process varies depending on the quantity of worms, the temperature, and how much waste is added to the bin. And there's another timeline to consider. In a healthy worm-bin habitat, worm reproduction will occur when the wigglers become sexually mature, indicated by an elongation of the segments into a bulbous structure. Three-month old wigglers can produce two to three semi-translucent yellow worm cocoons a week. You thought only moths and butterflies come out of cocoons? Well, we can't all be majestic. It takes around 11 weeks for new babies to hatch. When your bin seems to be full of living vermicelli noodles, it's time to share the bounty with your friends and start a vermicompost club. Or keep those worms to yourself and start a business. Vermicomposting isn't confined only to small worm bins, it's an emerging entrepreneurial enterprise. Large-scale facilities convert bulk organic waste and even manure into rich, black castings called black gold. Its value as a soil additive is unparalleled, and it can help plants resist harmful pathogens. The lack of available land in urban environments, coupled with growing interest in smaller-scale farming means there is a market for vermicomposting. Many communities use composting as part of zero-waste strategies, and they can sell their worm-eaten table scraps to local farms, hungry for rich fertilizer. So, instead of wasting money, dumping wasted food in landfills, we can remake waste into an asset, putting it back into our food system to make it more sustainable, all with the help of the humble worm, the tiny organism that can help us change the way we look at food's place in our lives and our place in the world, as long as we give the little guy a place at our table. Well, not an actual seat at the table. A bin in the shed is fine.

Description

A vermifilter toilet contains composting worms such as Eisenia fetida that digest human faeces, thus reducing the accumulation of solids in the system and reducing the need for frequent emptying, in comparison with pit latrines. Further, worm-based digestion is virtually complete and produces vermicompost, so emptying does not involve handling of sludge or require a specialist service. This is a key benefit to users, as is the associated lack of smells.[2]

In field trials in rural India, chemical oxygen demand (COD) and faecal indicators were reduced by 60% and 99% respectively in the effluent.[2]

A worm colony can live inside the vermifilter indefinitely as long as the correct environmental conditions are maintained. Worms need air, food (human faeces) and added (flush) water. An aerobic environment must be provided (e.g. ventilation), and the liquid effluent must be able to drain away. It is important to site the vermifilter correctly so that any risk of flooding is avoided.

Maintenance consists of occasionally removing the accumulated vermicompost: it is estimated that vermicompost removal will be required every 6–8 years, about one-half to one-third of the fill rate for an equivalent size of pit latrine with the same number of users.[4] Emptying latrines can be expensive and often comes with smell and contamination issues: in long-term refugees camps vermifilter toilets reduce the need to replace filled pit latrines and are more cost-effective.[5]

A vermifilter toilet provides primary treatment of human excreta. Providing they are used correctly and maintenance is carried out safely, they offer an affordable route towards safely managed sanitation, the new ambition for global sanitation,[6] for all.

Examples

  • Bear Valley Ventures has used the brand "Tiger Toilet" for marketing their product.[7][8]
  • Biofilcom, and GSAP Microflush toilet secured funding from the Bill & Melinda Gates Foundation to develop vermifilter toilet technology in Africa.[9]
  • Oxfam also instructs construction of brandless vermifilter toilets.[10][11]
  • TBF Environmental Solutions Pvt Ltd markets the "Tiger Toilet" in India[12]
  • Biofil market a vermifilter toilet in Bangladesh and Ghana.[13]
  • Biolytix in New Zealand[14]
  • Naturalflow New Zealand[15]
  • A&A Worm Farm Waste Systems in Australia[16]
  • Wendy Howard provides open-source plans for decentralized on-site vermifiltration septic treatment and distribution, and has been involved with promoting this technology in Portugal.[17][18]
  • Vermifilter.com provide low cost design options for building vermifilter toilets from readily available materials[19]

History

Anna Edey constructed a vermicomposting flush toilet in 1995, called the Solviva Biocarbon filter system. This was later adapted by Wendy Howard.[20] Dean Cameron in Australia developed the "dowmus" vermifilter toilet in the mid 1990s which morphed into the biolytyx system.[21] Colin Bell from New Zealand began marketing his "wormorator" in the late 1990s, a twin-chamber vermifilter toilet.[22]

Later, attention began to focus on applications in the developing world in 2009-2012 through the Sanitation Ventures project at the London School of Hygiene and Tropical Medicine (LSHTM) funded by a grant from the Bill & Melinda Gates Foundation. This project had the goal of finding solutions to the problem of pit latrine filling: vermifilter toilets appeared to be an attractive option. Colin Bell provided the design[21] and technical development was led by Claire Furlong in collaboration with Professor Michael Templeton of Imperial College London,[23][24] and was carried out at the Centre for Advanced Technology (CAT) in Wales.[25] By the end of the project, the team had built a usable prototype at CAT,[1] determined key operating parameters[2][26] and shown that there was consumer interest.

In parallel with the LSHTM work and also with Bill and Melinda Gates Foundation funding, Biofilcom (under Kweko Annu) developed a vermifilter toilet which has been commercialised in Ghana and Bangladesh. Development of the GSAP (Ghana Sustainable Aid Project) Microflush vermifilter toilet was also funded by the Bill and Melinda Gates Foundation.

Oxfam subsequently funded the construction of field-based trials in Ethiopia (in 2013), Liberia (in 2013[27]), while ACTED funded the development and construction of a communal (school) vermifilter toilet in Pakistan.

In continuation of the earlier Sanitation Ventures work, in 2013 Bear Valley Ventures was awarded a Development Innovation Ventures grant from USAID to support field testing in three countries and three different settings. This work was carried out in partnership with Oxfam (humanitarian relief camp, Myanmar), Water for People (peri-urban, Uganda) and PriMove (rural, India). After a year long trial the conclusion was that it worked well in all three settings: the results from India have been published.[2]

After field testing Bear Valley Ventures and PriMove (under Ajeet Oak) continued to collaborate from 2014 onwards on developing and marketing the Tiger Toilet band vermifilter toilet to low income rural and peri-urban households. From 2015 to 2017 they worked with the Institute for Transformative Technologies[28] (under Shashi Bulaswar) to rigorously test the product and explore paths to scale. In 2018 Bear Valley Ventures and PriMove set up TBF Environmental Solutions Pvt Ltd[12] to commercialise the Tiger Toilet and related technologies.

Oxfam (under Andy Bastable) have collaborated closely with Dr Claire Furlong to further develop applications for emergency and humanitarian camps.

In 2020 the International Worm-based Sanitation Association was formed under the leadership of Prof. Michael Templeton of Imperial College London to share, develop and promote best practice in vermifiltration for sanitation.[29]

See also

References

  1. ^ a b Furlong, C.; Gibson, W. T.; Templeton, M. R.; Taillade, M.; Kassam, F.; Crabb, G.; Goodsell, R.; McQuilkin, J.; Oak, A.; Thakar, G.; Kodgire, M. (2015-11-26). "The development of an onsite sanitation system based on vermifiltration: the 'Tiger Toilet'". Journal of Water, Sanitation and Hygiene for Development. 5 (4): 608–613. doi:10.2166/washdev.2015.167. hdl:10044/1/31477. ISSN 2043-9083.
  2. ^ a b c d e f g Furlong, C.; Gibson, W. T.; Oak, A.; Thakar, G.; Kodgire, M.; Patankar, R. (2016-04-01). "Technical and user evaluation of a novel worm-based, on-site sanitation system in rural India". Waterlines. 35 (2): 148–162. doi:10.3362/1756-3488.2016.013. ISSN 0262-8104.
  3. ^ Furlong, C.; Lamb, J.; Bastable, A. (2017). Learning from Oxfam's Tiger Worm Toilets projects. 40th WEDC International Conference, Loughborough, UK.
  4. ^ Hylton, Erin; Noad, Liam; Templeton, Michael R.; Sule, May N. (2020-06-29). "The rate of vermi-compost accumulation within 'Tiger Toilets' in India". Environmental Technology: 1–10. doi:10.1080/09593330.2020.1789750. hdl:10044/1/81148. ISSN 0959-3330. PMID 32597333. S2CID 220258149.
  5. ^ Snoad, C. (2020). Tiger Worm Toilet: One Stop Shop Manual. GB: Oxfam.
  6. ^ "Progress on drinking water, sanitation and hygiene: Joint Monitoring Programme 2017 update and SDG baselines". World Health Organization. Archived from the original on July 16, 2017.
  7. ^ Parsons, Jeff (15 January 2019). "The story of Bill Gates and the worm-powered toilet that could change the world". Metro. Retrieved 16 December 2019.
  8. ^ "Tiger Toilet - Bear Valley Ventures". engineeringforchange.org. Retrieved 16 December 2019.
  9. ^ "Vermifilters for blackwater treatment, "worm toilets", "Tiger worm toilet"". SuSanA.
  10. ^ Furlong, Claire; Polson, Lucy (11 April 2019). "Are Communal Tiger Worm Toilets a sustainable option for camps?". Oxfam. Retrieved 16 December 2019.
  11. ^ Guilbert, Kieran (8 March 2017). "Tiger worm toilets turn poo into fertilizer in crowded cities and refugee camps". Reuters. Retrieved 16 December 2019.
  12. ^ a b "TBF Environmental".
  13. ^ "Biofilcom".
  14. ^ "Biolytix".
  15. ^ "NaturalFlow". 29 January 2018.
  16. ^ "A&A Worm Farm Waste Systems".
  17. ^ "Permaculture In Portugal".
  18. ^ "Design and construction of a vermicomposting toilet". Vermicomposting Toilets. Retrieved 2021-10-16.
  19. ^ "Vermifilter.com". vermifilter.com.
  20. ^ "Vermicomposting Toilets".
  21. ^ a b "History of vermifilter toilet". SuSanA. 15 February 2020. Retrieved 16 February 2020.
  22. ^ "History of vermifilter toilet and wikipedia article". 15 February 2020.
  23. ^ "Home - Professor Michael Templeton".
  24. ^ "Imperial College London".
  25. ^ "Centre for Alternative Technology".
  26. ^ Furlong, C.; Templeton, M. R.; Gibson, W. T. (2014-03-26). "Processing of human faeces by wet vermifiltration for improved on-site sanitation". Journal of Water, Sanitation and Hygiene for Development. 4 (2): 231–239. doi:10.2166/washdev.2014.107. ISSN 2043-9083.
  27. ^ Watako, David; Mougabe, Koslengar; Heath, Thomas (2016). "Tiger worm toilets: lessons learned from constructing household vermicomposting toilets in Liberia". Waterlines. 35 (2): 136–147. doi:10.3362/1756-3488.2016.012. ISSN 0262-8104. JSTOR 26600731.
  28. ^ "Transformative Technologies".
  29. ^ "International Worm Based Sanitation Association".
This page was last edited on 13 March 2024, at 18:35
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