An ecobrick is a plastic bottle densely packed with used plastic to create a reusable building block that achieves plastic sequestration.The concept behind ecobricks is to utilize and upcycle post consumer plastic, benefiting our Earth. These plastic bottles are precisely packed with clean and dry used plastic to avoid the growth of bacteria. [1] Ecobricks can be used to produce various items, including furniture, garden walls and other structures. [2] These plastic packed bottles are produced primarily as a means of managing consumed plastic by sequestering it and containing it safely, by terminally reducing the net surface area of the packed plastic to effectively secure the plastic from degrading into toxins and microplastics. Ecobricking is a both an individual and collaborative endeavor. The ecobricking movement promotes the personal ecobricking process as a strategy to raise awareness of the consequences of consumption and the dangers of plastic. It also promotes the collaborative process as a way to encourage communities to take collective responsibility for their used plastic and to use it to produce a useful product. [3]
Typically, producers use a wood or bamboo stick to manually pack plastic into the plastic bottle. [4] Containing and compacting plastic helps ensure these photo-grading materials stay in one place for numerous years. The strongest bottle candidates for ecobricks are thick and durable plastic bottles with wider cap openings that can resist UV radiation. [5] Any size of transparent polyethylene terephthalate (PET) plastic bottle can be used to make an ecobrick. The bottle and the packed plastic are clean and dry to prevent the growth of bacteria. Plastic is cut or ripped into small pieces then packed little by little, alternating between adding the plastic and compacting it, layer by layer. The bottle is rotated with each press to ensure the plastic is evenly compacted throughout the bottle. This helps prevent voids and allows the packing to reach the requisite solidity needed for building block applications. [6] Completed ecobricks are packed solid enough that they can bear the weight of a person without deforming—a density range between 0.33 g/ml and 0.7 g/ml. [7] Maximizing density minimizes the flammability of the ecobrick [8] while increasing its durability and re-usability.
The global ecobrick movement has emerged as the result of a number of local initiatives in locations around the world in response to the challenges associated with the management of plastic waste. As economic petroleum consumption and plastic production have increased, [9] and as industrial waste management methods have struggled to keep pace, ecobricking has emerged as a local, non-industrial solution. [2]
Petroleum-derived energy has enabled the growth of the global economy over the last hundred years. The widespread adoption of fossil fuels has enabled transportation and material technologies to develop. However, in the refinement of crude oil, 4-13% cannot be processed into high value, high energy fuels. [10] This by-product is useful as a feedstock for the ultra-cheap production of plastic polymers. Since 1950 an estimated 8,300 million metric tons (Mt) of virgin plastics have been produced worldwide; 9% of which had been recycled, 12% were incinerated and 79% have accumulated in landfills or the natural environment. [11]
According to the American Chemistry Council, since 2010, $186 billion dollars have been invested in 318 new projects to fuel a 40% increase in plastic production over the next decade. [12] If current production and waste management trends continue, roughly 12,000 Mt of plastic waste will be in landfills or in the natural environment by 2050. [11] In addition, by 2030, CO2 emissions from the production, processing and disposal of plastic could reach 1.34 gigatons per year—equivalent to the emissions released by more than 295 new 500-megawatt coal-fired power plants. [13]
A tremendous amount of plastic waste litters our planet every year, and its cost is enormous. According to the United Nations Environment Programme (UNEP) 2014 Yearbook, plastic contamination threatens marine life, tourism, fisheries and businesses and the overall natural capital cost for plastic waste is $75 billion each year. [14] Increasing scientific documentation is demonstrating many dangers arising from plastic degradation. When plastic enters the biosphere it releases toxins, fragments into microplastics and emits greenhouse gases that interfere with ecological cycles. [15] When plastic is burned or incinerated, toxic gases like dioxins, furans, and polychlorinated biphenyls are released into the atmosphere. [16] Photo-oxidative degradation caused by exposure to ultraviolet (UV) radiation and physical abrasion fragments plastic debris into smaller and smaller particles, known as microplastics. [17] The degradation process corresponds directly to the amount of surface area of the plastic that is exposed as well as the length of time of exposure to UV rays. The majority of single use plastics are sheets and films with large surface areas and are highly susceptible to photodegradation. The photodegradation process also emits greenhouse gases, methane and ethylene. [18]
Microplastics can have possible direct ecotoxicological impacts, accumulate in food chains and cause economic damage because of food safety concerns. [19] Burned and incinerated plastics have been shown to release dioxins and other chemicals that are harmful to human health. [20]
In countries and communities without access to industrial recycling or incineration, plastic has accumulated in streets, ditches, and beaches. Without large scale options for managing plastic households and communities have been powerless to manage their own plastic, other than dangerous and toxin-producing low-temperature incineration, water, and land loose dumping. [21]
When plastic accumulates in these areas, the plastic releases toxins into the ground that contaminate groundwater and possible food sources. This makes it difficult for lower income communities as they have to deal with serious health problems and little resources. The use of ecobricks has greatly reduced the amount of plastic scattered in these communities. [3] Ecobricks are used to make walls, garden beds, chairs, tables, and so much more as they are a reliable and strong building material. [22]
Not only do Ecobricks help reduce plastic waste, they also help clean up lower income communities that have been polluted with plastic. Ecobricks have been used to build gardens, furniture, and even schools. The ecobricks website talks about a project using ecobricks to build a park almost five years ago in April 2019. This Ecobrick build project took place in Probolinggo, East Java, Indonesia. Thirty-three GEA (Global Ecobrick Alliance) trainers and 200 volunteers gathered at a park in Probolinggo, East Java to build a seating and garden area. They used a total of 1200 ecobricks, other organic materials and cement to create a mandala seating arrangement. The construction took place over 5 days and unfortunately, several hours after completion, rain struck and destroyed parts of the build. After that, the Paiton and Probolinggo park administrators were in charge of fixing and finishing the build. Since then, the build and the mandala park have been completed. [23] The ecobricks website mentions this project on its webpage but there are many other projects and studies around the world that are spreading the awareness of ecobricks and their uses.
In addition to aiding lower income communities, ecobricks can be a creative learning activity for poverty-struck schools. The Bargua District in Kendari City, Indonesia teaches school children the importance of solving the district's plastic pollution crisis. Through creative children building ecobricks, Bargua compacts plastic waste while informing of young generations the harms of the substance. [22] Another school in Indonesia, named SMP Nusa Bhaki, has addressed the country's increasingly concerning waste issue. This school has centralized on the creative learning mechanisms children can grasp through ecobricks. Teachers can give their children the innovative freedom to create products and materials with ecobricks. Moreso, all participants involved with the process of constructing ecobricks can spread the sustainable idea to their friends and families. [24]
Ecobricks may even be the future for the resettlement of refugees. Due to extremely limited living conditions and scarce available land, Burmese refugees who fled to Bangladesh had to be moved to the country's island Bhasan Char. The government of Bangladesh built new refugee camps constructed of traditional building materials. A sustainable alternative for future refugee resettlements would be ecobricks. The utilization of local plastic waste as building components would significantly lower costs, C02 emissions, and consumption of other resources. This building alternative would also grant refugees the opportunity to build a positive and protective relationship with the environment. [25]
Lower income communities feel the effects of plastic waste the worst as they don't have the funding to keep their environment clean. There is also a lack of education on plastic waste in these communities that prevent the proper disposal plastic and recycling methods. The Tanjung Mekar Village in Karawang Regency is an example of a village that have used ecobricks as a way to keep their environment clean and educate the public about plastic waste and pollution. There was also a study that took place in this village to determine if ecobricks were a better building material compared to regular concrete bricks and a material known as red bricks. They found that, when put under pressure, an ecobrick was able to withstand much more than the concrete and red bricks. This confirmed that ecobricks can be a cheap and environmentally friendly non-structural building material. [26]
Ecobricks are a great way to recycle plastic waste as well as educate about the dangers of plastic pollution. Although, due to ecobricks being a relatively new solution to plastic pollution, studies are still taking place to determine if ecobricks will continue to be a solution in the long run. Ecobricks are not a solution to get rid of plastic waste. They simply extend the life of already used plastic in a way that is beneficial to environments that are affected the most. [22]
Between 1950 and 2017 an estimated 8,300 million metric tons (Mt) of virgin plastics have been produced worldwide; only 9% were recycled, the rest have been dumped or burned. [27] As of the early 2000s most industrial recycling was occurring in China where the majority of G7 countries were exporting their waste plastic. [28] The processing of this plastic, in particular the dumping and incineration of un-recyclables, caused significant pollution in China. [29] As of January 1, 2018, China banned plastic imports in its National Sword program. [30] Since then, globally, more plastics are now ending up in landfills, incinerators, or likely littering the environment as rising costs to haul away recyclable materials increasingly render the practice unprofitable. [31] The displaced plastic exports from Europe and America has been largely diverted to Indonesia, Turkey, India, Malaysia, and Vietnam [32] where lacking environmental regulations have resulted in wholesale air, water and earth pollution around processing plants. [33] Critics observe that industrial recycling relies on the energy intensive export of plastic to other locations, that industrial recycling isn't circular (processes turn a high grade plastic into a lower, less-recyclable form), and that recycling enables the unquestioned continuation of plastic consumption [34] [35]
The ecobricking movement has emerged from a growing awareness of the scale of plastic pollution, the problems it causes and the inability of industrial means to adequately manage plastic waste [36] The ecobricking movement promotes techniques, methodologies and applications for households, communities and cities [37] to take responsibility for their plastic. Ecobricks serve to sequester plastic, to use the local plastic as building blocks, and as an alternative medium of community exchange [38]
By packing plastic into a bottle, flat high-surface area wrappers and films are compressed together. This terminal minimization of net surface area means that the plastic is secured from the principal forms of potential degradation: heat, burning, friction and photo-degradation. [39] In addition, by ensuring that only clean and dry plastic is packed and permanently sealing the bottle, potential microbial degradation is also prevented. [40]
When ecobricks are properly made and properly applied in cradle to cradle design constructions they result in the effective plastic sequestration, [41] of plastic out of the biosphere. In other words, ecobricks serve as a way to trap and secure plastic from entering the environment, degrading and causing ecological harm. [42] In short-term ecobrick applications, such as milstein [43] or Dieleman Modules [44] ecobricks can be used for up to three years without any damage to the bottle. By using silicone sealant [45] or inner-tube-bands [46] as short-term, non-permanent attachment methods, the ecobricks can be extricated undamaged at the construction's end and used again in another short or long-term applications. [47] In particular, the long-term earth and ecobrick building method, [48] results in gardens, parks, and earthen walls that ensure that the ecobricked plastic is fully secured. Earthen mortar will easily crumble when the structure is disassembled ensuring that the ecobricks can be extricated and reused. [49] Earthen mortar also completely covers the ecobrick negating any possibility of heat, friction, fire or microbial degradation. [50] Ecobrick sequestration thus prevents the breakdown of the contained plastic into micro-plastics [51] and into green house gases through photo-degradation. [52] Ecobrick sequestration also prevents the incineration of the plastic and the release of gases and CO2 [53] It is estimated that for each 1 kg of ecobricked plastic, 3.1 kg of CO2 is sequestered. [13]
In contrast to industrial plastic management technologies, ecobriking directly involves the consumers of plastic in its process. The process of saving, segregating, washing, drying and packing plastic results in consumer/ecobricker reflection. [7] The meditative and communal tendencies of ecobricking raise individual and collective 'ecological consciousness' over time. [54] [3] Ecobrickers tend to pursue more information about waste disposal in their community, plastic, recycling and ecobricking topics. This leads to a steady decrease in the ecobricker's net plastic consumption. [55] [56]
Ecobricks can be connected using tire bands, silicone, cob, and cement to build furniture, gardens, structures and more. [57] Ecobricks are being used in different ways around the world. Ideally, ecobrick constructions use cradle to cradle design methods of combining the bottles—ensuring that the ecobricks can be extricated without compromise to the bottle at the end of the construction's life span. [58] It is useful to differentiate between short-term ecobrick and long term ecobrick applications
Eco bricks can be combined together using tire bands [59] or inner-tube-bands [46] as short-term, non-permanent attachment methods to create applications that last months to several years. As short-term applications are not usually covered, such constructions are typically for indoor use, in order to prevent UV photodegration of the bottles. Short-term applications range from:
Ecobricks can be used with Earth building techniques (i.e. cob, wattle and daub, and adobe) to create structures that can last years or decades. [64] In this way, Earth mixes are used in between horizontally laid ecobricks as mortar. [65] Ecobricks can also be used vertically and with traditional construction techniques in the Pura Vida Atlan style of building. [66] Both methods are careful to avoid the complete covering of ecobricks with cement which upon the end of the construction results in the destruction of ecobricks upon extrication. [67] Examples of long-term ecobrick applications include:
The packing of plastic into bottles to sequester plastic and to make building blocks has arisen independently in locations around the world as a local solution to plastic pollution[ clarification needed ]. Filling bottles with plastic waste builds upon the bottle building techniques of German architect Andreas Froese (using sand-filled PET bottles) in South America in 2000. Alvaro Molina began packing plastic into bottles on the island of Ometepe in 2003. Susana Heisse, in Guatemala began to encourage ecobricking in 2003 as a building technique and for solving plastic pollution challenges faced in Lake Atitlan communities. [71]
In 2010, in the Northern Philippines, Russell Maier and Irene Bakisan [72] developed a curriculum guide of simplified and recommended practices to help local schools integrate eco-bricks into their curriculum. Applying the ancestral ecological principles of the Igorots for building rice terraces, they integrated cradle-to-cradle principles into ecobrick methodology: ensuring that ecobricks can be reused at the end of the construction they are used in. [73] Through the Department of Education, the guide was distributed to 1,700 schools in 2014. [74]
Movements in South Africa began in 2012, when Joseph Stodgel brought the concept to Greyton, throwing an annual Trash to Treasure festival at the local dumpsite with South African, Candice Mostert, who started local school projects under Greyton transition town building with the bricks made by the community. The movement has since grown in South Africa, with organizations like Waste-ED, founded by Candice Mostert, who works both in Zambia and Cape Towns surrounds to educate people about plastic and its value, and the architect Ian Dommisse as the Ecobrick Exchange.[ citation needed ]
Polyethylene terephthalate (or poly(ethylene terephthalate), PET, PETE, or the obsolete PETP or PET-P), is the most common thermoplastic polymer resin of the polyester family and is used in fibres for clothing, containers for liquids and foods, and thermoforming for manufacturing, and in combination with glass fibre for engineering resins.
Zero waste, or waste minimization, is a set of principles focused on waste prevention that encourages redesigning Natural resource resource life cycles so that all products are repurposed and/or reused. The goal of the movement is to avoid sending trash to landfills, incinerators, oceans, or any other part of the environment. Currently 9% of global Plastic recycling plastic is recycled. In a zero waste system, all materials are reused until the optimum level of consumption is reached.
Marine debris, also known as marine litter, is human-created solid material that has deliberately or accidentally been released in seas or the ocean. Floating oceanic debris tends to accumulate at the center of gyres and on coastlines, frequently washing aground, when it is known as beach litter or tidewrack. Deliberate disposal of wastes at sea is called ocean dumping. Naturally occurring debris, such as driftwood and drift seeds, are also present. With the increasing use of plastic, human influence has become an issue as many types of (petrochemical) plastics do not biodegrade quickly, as would natural or organic materials. The largest single type of plastic pollution (~10%) and majority of large plastic in the oceans is discarded and lost nets from the fishing industry. Waterborne plastic poses a serious threat to fish, seabirds, marine reptiles, and marine mammals, as well as to boats and coasts.
Plastic recycling is the processing of plastic waste into other products. Recycling can reduce dependence on landfill, conserve resources and protect the environment from plastic pollution and greenhouse gas emissions. Recycling rates lag behind those of other recoverable materials, such as aluminium, glass and paper. From the start of plastic production through to 2015, the world produced around 6.3 billion tonnes of plastic waste, only 9% of which has been recycled and only ~1% has been recycled more than once. Of the remaining waste, 12% was incinerated and 79% was either sent to landfills or lost to the environment as pollution.
Biodegradable plastics are plastics that can be decomposed by the action of living organisms, usually microbes, into water, carbon dioxide, and biomass. Biodegradable plastics are commonly produced with renewable raw materials, micro-organisms, petrochemicals, or combinations of all three.
Textile recycling is the process of recovering fiber, yarn, or fabric and reprocessing the material into new, useful products. Textile waste is split into pre-consumer and post-consumer waste and is sorted into five different categories derived from a pyramid model. Textiles can be either reused or mechanically/chemically recycled.
Pre-production plastic pellets, commonly known as nurdles, are tiny plastic pellets that are universally used in the plastics industry for the manufacture of plastic products. These microplastics are made primarily from polyethylene, polypropylene, polystyrene, polyvinyl chloride, and other plastics or synthetic resins. Nurdles are the building block, via plastic extrusion or injection molding, for items for everyday life including plastic water bottles, containers, and bags.
Marine plastic pollution is a type of marine pollution by plastics, ranging in size from large original material such as bottles and bags, down to microplastics formed from the fragmentation of plastic material. Marine debris is mainly discarded human rubbish which floats on, or is suspended in the ocean. Eighty percent of marine debris is plastic. Microplastics and nanoplastics result from the breakdown or photodegradation of plastic waste in surface waters, rivers or oceans. Recently, scientists have uncovered nanoplastics in heavy snow, more specifically about 3,000 tons that cover Switzerland yearly.
Oxo-degradation, refers to the process by which plastics that contain additives that accelerate its breakdown into smaller fragments, called microplastics, when exposed to heat, light or oxygen. This is in contrast to biodegradable or compostable plastics, which break down at the molecular or polymer level. Oxo-degradable plastics are currently banned in the EU, but still permitted in other jurisdictions such as the UK.
Plastics are a wide range of synthetic or semi-synthetic materials that use polymers as a main ingredient. Their plasticity makes it possible for plastics to be molded, extruded or pressed into solid objects of various shapes. This adaptability, plus a wide range of other properties, such as being lightweight, durable, flexible, and inexpensive to produce, has led to their widespread use. Plastics typically are made through human industrial systems. Most modern plastics are derived from fossil fuel-based chemicals like natural gas or petroleum; however, recent industrial methods use variants made from renewable materials, such as corn or cotton derivatives.
The North Atlantic garbage patch is a garbage patch of man-made marine debris found floating within the North Atlantic Gyre, originally documented in 1972. A 22-year research study conducted by the Sea Education Association estimates the patch to be hundreds of kilometers across, with a density of more than 200,000 pieces of debris per square kilometer. The garbage originates from human-created waste traveling from rivers into the ocean and mainly consists of microplastics. The garbage patch is a large risk to wildlife through plastic consumption and entanglement.
Microplastics are fragments of any type of plastic less than 5 mm (0.20 in) in length, according to the U.S. National Oceanic and Atmospheric Administration (NOAA) and the European Chemicals Agency. They cause pollution by entering natural ecosystems from a variety of sources, including cosmetics, clothing, food packaging, and industrial processes.
Recycling can be carried out on various raw materials. Recycling is an important part of creating more sustainable economies, reducing the cost and environmental impact of raw materials. Not all materials are easily recycled, and processing recyclable into the correct waste stream requires considerable energy. Some particular manufactured goods are not easily separated, unless specially process therefore have unique product-based recycling processes.
Plastic pollution is the accumulation of plastic objects and particles in the Earth's environment that adversely affects humans, wildlife and their habitat. Plastics that act as pollutants are categorized by size into micro-, meso-, or macro debris. Plastics are inexpensive and durable, making them very adaptable for different uses; as a result, manufacturers choose to use plastic over other materials. However, the chemical structure of most plastics renders them resistant to many natural processes of degradation and as a result they are slow to degrade. Together, these two factors allow large volumes of plastic to enter the environment as mismanaged waste which persists in the ecosystem and travels throughout food webs.
Plastic roads are paved roadways that are made partially or entirely from plastic or plastic composites, which is used to replace standard asphalt materials. Most plastic roads make use of plastic waste a portion the asphalt. It is currently unknown how these aggregates will perform in the mid- to long-term, or what effect their degradation might have on surrounding ecosystems.
Packaging waste, the part of the waste that consists of packaging and packaging material, is a major part of the total global waste, and the major part of the packaging waste consists of single-use plastic food packaging, a hallmark of throwaway culture. Notable examples for which the need for regulation was recognized early, are "containers of liquids for human consumption", i.e. plastic bottles and the like. In Europe, the Germans top the list of packaging waste producers with more than 220 kilos of packaging per capita.
China's waste import ban, instated at the end of 2017, prevented foreign inflows of waste products. Starting in early 2018, the government of China, under Operation National Sword, banned the import of several types of waste, including plastics with a contamination level of above 0.05 percent. The ban has greatly affected recycling industries worldwide, as China had been the world's largest importer of waste plastics and processed hard-to-recycle plastics for other countries, especially in the West.
Polymateria Ltd is a British technology company developing biodegradable plastic alternatives. In 2020, the privately owned company was the first to achieve certified biodegradation of the most commonly-littered forms of plastic packaging in real-world conditions, in less than a year without creating microplastics.
Plastic sequestration is a means of plastic waste management that secures used plastic out of industry and out of the environment into reusable building blocks made by manual compaction. Plastic sequestration is motivated by environmental protection and modeled on the Earth's process of carbon sequestration. Emerging out of the struggle of towns and communities in the Global South to deal with plastic pollution, plastic sequestration compaction methods are characterized by being locally based, non-capital, non-industrial and low-tech. Plastic sequestration is defined by the goals of securing plastic out of the environment and out of high energy/carbon industrial systems. Based on eliminating the chemical and physical and abiotic and biotic degradation pathways, plastic sequestration aims to achieve these goals, by terminally reducing the net surface area of thin film plastics. The building blocks that emerge from plastic sequestration are used in applications that further protect from degradation and permanently keep plastic out of industrial processes, thereby preventing their carbon emissions.
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