Difference between pages "How to Recycle Rubber" and "How to Recycle Plastics"

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=Recycling Rubber - Technical Brief=
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=Recycling Plastics=
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==Plastics - what are they and how do they behave?==
  
 
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<center>'''PRACTICAL ACTION'''<br />'''Technology challenging poverty'''</center>
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Plastics are organic polymeric materials consisting of giant organic molecules. Plastic materials can be formed into shapes by one of a variety of processes, such as extrusion, moulding, casting or spinning. Modern plastics (or polymers) possess a number of extremely desirable characteristics; high strength to weight ratio, excellent thermal properties, electrical insulation, resistance to acids, alkalis and solvents, to name but a few.
  
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These polymers are made of a series of repeating units known as monomers. The structure and degree of polymerisation of a given polymer determine its characteristics. ''Linear polymers'' (a single linear chain of monomers) and ''branched polymers'' (linear with side chains) are ''thermoplastic,'' that is they soften when heated. ''Cross-linked polymers'' (two or more chains joined by side chains) are ''thermosetting'', that is, they harden when heated.
  
==Introduction==
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[[Image:recycle_plastic001.gif]]<br /> Figure 1: Polymer structures
  
Rubber is produced from natural or synthetic sources. Natural rubber is obtained from the milky white fluid called latex, found in many plants; synthetic rubbers are produced from unsaturated hydrocarbons.
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</center>
  
Long before Colombus arrived in the Americas, the native South Americans were using rubber to produce a number of water-resistant products. The Spaniards tried in vain to copy these products (shoes, coats and capes), and it was not until the 18<sup>th</sup> century that European scientists and manufacturers began to use rubber successfully on a commercial basis. The British inventor and chemist Charles Macintosh, in 1823, established a plant in Glasgow for the manufacture of waterproof cloth and the rainproof garments with which his name has become synonymous.
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''Thermoplastics'' make up 80% of the plastics produced today. Examples of thermoplastics include;<br />
  
A major breakthrough came in the mid 19<sup>th</sup> century with the development of the process of ''vulcanisation.'' This process gives increased strength, elasticity, and resistance to changes in temperature. It also renders rubber impermeable to gases and resistant to heat, electricity, chemical action and abrasion. Vulcanised rubber also exhibits frictional properties highly desired for pneumatic tyre application.
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<blockquote>
  
Crude latex rubber has few uses. The major uses for vulcanised rubber are for vehicle tyres and conveyor belts, shock absorbers and anti-vibration mountings, pipes and hoses. It also serves some other specialist applications such as in pump housings and pipes for handling of abrasive sludges, power transmission belting, diving gear, water lubricated bearings, etc.
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• '''high density polyethylene''' (HDPE) used in piping, automotive fuel tanks, bottles, toys,<br /> • '''low density polyethylene''' (LDPE) used in plastic bags, cling film, flexible containers;<br /> • '''polyethylene terephthalate''' (PET) used in bottles, carpets and food packaging;<br /> • '''polypropylene''' (PP) used in food containers, battery cases, bottle crates, automotive parts and fibres;<br /> • '''polystyrene''' (PS) used in dairy product containers, tape cassettes, cups and plates;<br /> • '''polyvinyl chloride''' (PVC) used in window frames, flooring, bottles, packaging film, cable insulation, credit cards and medical products.
  
In this brief, we will be looking primarily at the reclamation and reuse of scrap tyres. This is simply due to the fact that this is the major source of waste rubber in developing countries.
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<br /> There are hundreds of types of thermoplastic polymer, and new variations are regularly being developed. In developing countries the number of plastics in common use, however, tends to be much lower.
  
==What is rubber?==
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''Thermosets'' make up the remaining 20% of plastics produced. They are hardened by curing and cannot be re-melted or re-moulded and are therefore difficult to recycle. They are sometimes ground and used as a filler material. They include: '''polyurethane''' (PU) - coatings, finishes, gears, diaphragms, cushions, mattresses and car seats; '''epoxy''' - adhesives, sports equipment, electrical and automotive equipment; '''phenolics''' - ovens, handles for cutlery, automotive parts and circuit boards (The World Resource Foundation).
  
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Nowadays, the raw materials for plastics come mainly from petrochemicals, although originally plastics were derived from cellulose, the basic material of all plant life.
  
''Natural rubber'' is extracted from rubber producing plants, most notably the tree ''Hevea brasiliensis,'' which originates from South America. Nowadays, more than 90% of all natural rubber comes from these trees in the rubber plantations of Indonesia, the Malay Peninsula and Sri Lanka. The common name for this type of rubber is ''Para'' rubber.
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</div>
  
The rubber is extracted from the trees in the form of latex. The tree is 'tapped'; that is, a diagonal incision is made in the bark of the tree and as the latex exudes from the cut it is collected in a small cup. The average annual yield is approximately 2 ½ kg per tree or 450kg per hectare, although special high-yield trees can yield as much as 3000kg per hectare each year.
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==Why recycle plastics?==
  
The gathered latex is strained, diluted with water, and treated with acid to cause the suspended rubber particles within the latex to coagulate. After being pressed between rollers to form thin sheets, the rubber is air (or smoke) dried and is then ready for shipment.
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==Synthetic Rubber==
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In ‘western’ countries, plastic consumption has grown at a tremendous rate over the past two or three decades. In the ‘consumer’ societies of Europe and America, scarce petroleum resources are used for producing an enormous variety of plastics for an even wider variety of products. Many of the applications are for products with a life-cycle of less than one year and then the vast majority of these plastics are then discarded. In most instances reclamation of this plastic waste is simply not economically viable.
  
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In industry (the automotive industry for example) there is a growing move towards reuse and reprocessing of plastics for economic, as well as environmental reasons, with many praiseworthy examples of companies developing technologies and strategies for recycling of plastics.
  
There are several synthetic rubbers in production. These are produced in a similar way to plastics, by a chemical process known as polymerisation. They include neoprene, ''Buna'' rubbers, and ''butyl'' rubber. Synthetic rubbers have usually been developed with specific properties for specialist applications. The synthetic rubbers commonly used for tyre manufacture are styrene-butadiene rubber and butadiene rubber (both members of the Buna family). Butyl rubber, since it is gas-impermeable, is commonly used for inner tubes. Table 1 below shows typical applications of various types of rubber.
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Not only is plastic made from a non-renewable resource, but it is generally non-biodegradable (or the biodegradation process is very slow). This means that plastic litter is often the most objectionable kind of litter and will be visible for weeks or months, and waste will sit in landfill sites for years without degrading.
  
 
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'''Type of rubber'''
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'''Plastics fact file'''<br />
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'''Application'''
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• More than 20,000 plastic bottles are needed to obtain 1 tonne of plastic.<br /> • It is estimated that 100 million tonnes of plastics are produced each year.<br /> • The average European throws away 36kg of plastics each year.<br /> • 4% of oil consumption in Europe is used for the manufacture of plastic products.<br /> • Some plastic waste sacks are made from 64% recycled plastic.<br /> • Plastics packaging totals 42% of total consumption and very little of this is recycled.
Natural rubber
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Commercial vehicles such as lorries, buses and trailers.
 
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Styrene-butadiene rubber (SBR) and Butadiene rubber (BR)
 
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Small lorries, private cars, motorbikes and bicycles.
 
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Butyl rubber (IIR)
 
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Inner tubes.
 
 
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Table 1: Applications of different classes of rubber in the manufacture of vehicle tyres.
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Although there is also a rapid growth in plastics consumption in the developing world, plastics consumption per capita in developing countries is much lower than in the industrialised countries. These plastics are, however, often produced from expensive imported raw materials. There is a much wider scope for recycling in developing countries due to several factors:<br />
  
The raw materials that make up tyres are natural and synthetic rubbers, carbon, nylon or polyester cord, sulphur, resins and oil. During the tyre making process, these are virtually vulcanised into one compound that is not easily broken down.
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• Labour costs are lower.
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• In many countries there is an existing culture of reuse and recycling, with the associated system of collection, sorting, cleaning and reuse of ‘waste’ or used materials.
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• There is often an ‘informal sector’ which is ideally suited to taking on small-scale recycling activities. Such opportunities to earn a small income are rarely missed by members of the urban poor.
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• There are fewer laws to control the standards of recycled materials. (This is not to say that standards can be low - the consumer will always demand a certain level of quality).
  
===Production of rubber products===
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• Transportation costs are often lower, with hand or ox carts often being used.
  
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• Low cost raw materials give an edge in the competitive manufacturing world.
  
The modern process of rubber manufacture involves a sophisticated series of processes such as mastication, mixing, shaping, moulding and vulcanisation. Various additives are included during the mixing process to give desired characteristics to the finished product. They include:
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• Innovative use of scrap machinery often leads to low entry costs for processing or manufacture.
  
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<br /> In developing countries the scope for recycling of plastics is growing as the amount of plastic being consumed increases.
  
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'''Plastics for recycling'''
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Polymers
 
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Vulcanisation accelerators
 
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Activators
 
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Vulcanisation agents
 
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Fillers (carbon black)
 
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Fire retardants
 
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Anti-degradants
 
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Colorants or pigments
 
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Plasticisers
 
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Softeners
 
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Not all plastics are recyclable. There are 4 types of plastic which are commonly recycled:<br />
  
Fillers are used to stiffen or strengthen rubber. Carbon black is an anti-abrasive and is commonly used in tyre production. Pigments include zinc oxide, lithopone, and a number of organic dyes. Softeners, which are necessary when the mix is too stiff for proper incorporation of the various ingredients, usually consist of petroleum products, such as oils or waxes; pine tar; or fatty acids. The moulding of the compound is carried out once the desired mix has been achieved and vulcanisation is often carried out on the moulded product.
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<blockquote>
  
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• Polyethylene (PE) - both high density and low-density polyethylene.<br /> • Polypropylene (PP)<br /> • Polystyrene (PS)<br /> • Polyvinyl chloride (PVC)
  
==Vulcanisation==
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</blockquote>
  
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<br /> A common problem with recycling plastics is that plastics are often made up of more than one kind of polymer or there may be some sort of fibre added to the plastic (a composite) to give added strength. This can make recovery difficult.
  
To understand the process of vulcanisation it is worth discussing, briefly, the molecular structure of rubber. Crude latex is made up of a large number of very long, flexible, molecular chains. If these chains are linked together to prevent the molecules moving apart, then the rubber takes on its characteristic elastic quality. This linking process is carried out by heating the latex with sulphur (other vulcanising agents such as selenium and tellurium are occasionally used but sulphur is the most common). There are two common vulcanising processes.<br />
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'''Sources of waste plastics'''
  
<blockquote>
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Industrial waste (or primary waste) can often be obtained from the large plastics processing, manufacturing and packaging industries. Rejected or waste material usually has good characteristics for recycling and will be clean. Although the quantity of material available is sometimes small, the quantities tend to be growing as consumption, and therefore production, increases.
  
• ''Pressure vulcanisation.'' This process involves heating the rubber with sulphur under pressure at a temperature of 150°C. Many articles are vulcanised in moulds that are compressed by a hydraulic press (see Figure 1 below).
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Commercial waste is often available from workshops, craftsmen, shops, supermarkets and wholesalers. A lot of the plastics available from these sources will be PE, often contaminated.
  
• ''Free vulcanisation.'' Used where pressure vulcanisation is not possible, such as with continuous, extruded products, it is carried out by applying steam or hot air. Certain types of garden hose, for example, are coated with lead, and are vulcanised by passing high-pressure steam through the opening in the hose.
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Agricultural waste can be obtained from farms and nursery gardens outside the urban areas. This is usually in the form of packaging (plastic containers or sheets) or construction materials (irrigation or hosepipes).
  
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[[Image:Rubber_Recycling_1.jpg]]
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[[Image:recycle_plastic003.jpg]]<br /> Figure 2: Mixed waste plastic requiring sorting before it can be recycled. ©World Resource Foundation
  
 
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</center>
  
The proportion of natural and synthetic rubber used for tyre manufacture depends on the application of the particular tyre.
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Municipal waste can be collected from residential areas (domestic or household waste), streets, parks, collection depots and waste dumps. In Asian cities this type of waste is common and can either be collected from the streets or can be collected from households by arrangement with the householders. (Lardinois 1995)
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'''Identification of different types of plastics'''
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There are several simple tests that can be used to distinguish between the common types of polymers so that they may be separated for processing.
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''The water test.'' After adding a few drops of liquid detergent to some water put in a small piece of plastic and see if it floats.
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''Burning test.'' Hold a piece of the plastic in a tweezers or on the back of a knife and apply a flame. Dose the plastic burn? If so, what colour?
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''Fingernail test.'' Can a sample of the plastic be scratched with a fingernail?
  
 
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{| border="1" cellpadding="5"
 
{| border="1" cellpadding="5"
 
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Truck tyre tread (in %)
 
 
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Passenger vehicle tyre tread (in %)
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'''Test'''
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'''PE'''
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'''PP'''
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'''PS'''
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'''PVC*'''
 
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Mineral oil
 
 
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13
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'''Water'''
 
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20 - 24
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Floats
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Floats
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Sinks
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Sinks
 
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Carbon black
 
 
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30
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'''Burning'''
 
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33 - 37
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Blue flame with yellow tip, melts and drips.
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Yellow flame with blue base.
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Yellow, sooty flame - drips.
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Yellow, sooty smoke. Does not continue to burn if flame is removed
 
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Rubber - of which
 
 
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57
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'''Smell after burning'''
 
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40 - 45
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Like candle wax.
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Natural rubber
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Like candle wax - less strong than PE
 
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65
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Sweet
 
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25
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Hydrochloric acid
 
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BR & SBR
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'''Scratch'''
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Yes
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No
 
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35
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No
 
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75
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No
 
|}
 
|}
  
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Table 2: Composition of typical tyre tread for commercial and passenger vehicles. (TOOL 1996)
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<nowiki>*To confirm PVC, touch the sample with a red-hot piece of copper wire and then hold the wire to the flame. A green flame from the presence of chlorine confirms that it is PVC.</nowiki><br /> Source: Vogler. 1984
  
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==Why reclaim or recycle rubber?==
 
  
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<br /> To determine if a plastic is a thermoplastic or a thermoset, take a piece of wire just below red heat and press it into the material. If the wire penetrates the material, it is a thermoplastic; if it does not it is a thermoset.
  
Rubber recovery can be a difficult process. There are many reasons, however why rubber should be reclaimed or recovered;<br />
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A coding system has also been introduced in the United States to aid identification of plastics for reclamation. It is based on the ‘Recycle Triangle’ with a series of numbers and letters to help with identification. More information is available from the Association of Plastic Manufacturers in Europe (APME). See ''useful addresses'' section later in this brief.
  
<blockquote>
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'''Collection'''
  
• Recovered rubber can cost half that of natural or synthetic rubber.
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When thinking about setting up a small-scale recycling enterprise, it is advisable to first carry out a survey to ascertain the types of plastics available for collection, the type of plastics used by manufacturers (who will be willing to buy the reclaimed material), and the economic viability of collection.
  
• Recovered rubber has some properties that are better than those of virgin rubber.
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The method of collection can vary. The following gives some ideas;<br />
  
• Producing rubber from reclaim requires less energy in the total production process than does virgin material.
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<blockquote>
  
It is an excellent way to dispose of unwanted rubber products, which is often difficult.
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House to house collection of plastics and other materials (e.g. paper).<br /> • House to house collection of plastics only (but all types of polymer).<br /> • House to house collection of certain objects only.<br /> • Collection at a central point e.g. market or church.<br /> • Collection from street boys in return for payment.<br /> • Regular collection from shops, hotels, factories, etc.<br /> • Purchase from scavengers on the municipal dump.<br /> • Scavenging or collecting oneself.
  
• It conserves non-renewable petroleum products, which are used to produce synthetic rubbers.
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• Recycling activities can generate work in developing countries.
 
 
 
• Many useful products are derived from reused tyres and other rubber products.
 
 
 
• If tyres are incinerated to reclaim embodied energy then they can yield substantial quantities of useful power. In Australia, some cement factories use waste tyres as a fuel source.
 
 
 
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==Tyre reuse and recovery in developing countries==
 
 
 
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There is an enormous potential for reclamation and reuse of rubber in developing countries. There is a large wastage of rubber tyres in many countries and the aim of this brief is to give some ideas for what can be done with this valuable resource. Whether rubber tyres are reused, reprocessed or hand crafted into new products, the end result is that there is less waste and less environmental degradation as a result.
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<br /> The method will depend upon the scale of the operation, the capital available for set-up, transport availability, etc.
  
In developing countries, there is a culture of reuse and recycling. Waste collectors roam residential areas in large towns and cities in search of reusable articles. Some of the products that result from the reprocessing of waste are particularly impressive and the levels of skill and ingenuity are high. Recycling artisans have integrated themselves into the traditional market place and have created a viable livelihood for themselves in this sector. The process of tyre collection and reuse is a task carried out primarily by the informal sector. Tyres are seen as being too valuable to enter the waste stream and are collected and put to use.
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'''Processing of reclaimed plastic - processes and technology for small-scale recycling enterprises'''
  
In Karachi, Pakistan, for example, tyres are collected and cut into parts to obtain secondary materials which can be put to good use. The beads of the tyres are removed and the rubber removed by burning to expose the steel. The tread and sidewalls are separated - the tread is cut into thin strips and used to cover the wheels of donkey carts, while the sidewalls are used for the production of items such as shoe soles, slippers or washers (WAREN Report).
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• ''Initial upgrading.'' Once the plastic has been collected, it will have to be cleaned and sorted. The techniques used will depend on the scale of the operation and the type of waste collected, but at the simplest level will involve hand washing and sorting of the plastic into the required groups. More sophisticated mechanical washers and solar drying can be used for larger operations. Sorting of plastics can be by polymer type (thermoset or thermoplastic for example), by product (bottles, plastic sheeting, etc.), by colour, etc.
  
 
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<center>
  
[[Image:Rubber_Recycling_2.jpg]]<br /> Figure 2: Manual Separation of the Tread from the Sidewalls, Karachi, Pakistan © PCSIR - WASTE
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[[Image:recycle_plastic004.jpg]]<br /> Figure 3: Collection of Waste Materials. © World Resource Foundation
  
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==Recovery of rubber==
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[[Image:recycle_plastic005.gif]]<br /> Figure 4: Flow chart of a typical waste plastic reprocessing stream in a low-income country (TOOL 1995)
  
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'''Recovery Alternatives'''
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''Size reduction techniques''. Size reduction is required for several reasons; to reduce larger plastic waste to a size manageable for small machines, to make the material denser for storage and transportation, or to produce a product which is suitable for further processing. There are several techniques commonly used for size reduction of plastics;<br />
  
There are many ways in which tyres and inner tubes can be reused or reclaimed. The waste management hierarchy dictates that re-use, recycling and energy recovery, in that order, are superior to disposal and waste management options. This hierarchy is outlined in Table 3 below.
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<blockquote>
  
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• ''Cutting'' is usually carried out for initial size reduction of large objects. It can be carried out with scissors, shears, saw, etc.
  
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''Shredding'' is suitable for smaller pieces. A typical shredder has a series of rotating blades driven by an electric motor, some form of grid for size grading and a collection bin. Materials are fed into the shredder via a hopper which is sited above the blade rotor. The product of shredding is a pile of coarse irregularly shaped plastic flakes which can then be further processed.
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Kind of recovery
 
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Recovery process
 
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Product reuse
 
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Repair
 
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• Retreading<br /> • Regrooving
 
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Physical reuse
 
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Use as weight<br /> • Use of form<br /> • Use of properties<br /> • Use of volume
 
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Material reuse
 
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Physical
 
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• Tearing apart<br /> • Cutting<br /> • Processing to crumb
 
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Chemical
 
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• Reclamation
 
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Thermal
 
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• Pyrolysis<br /> • Combustion
 
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Energy reuse
 
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• Incineration
 
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• ''Agglomeration'' is the process of pre-plasticising soft plastic by heating, rapid cooling to solidify the material and finally cutting into small pieces. This is usually carried out in a single machine. The product is coarse, irregular grain, often called crumbs.
  
Table 3: Principal rubber recycling processing paths (adapted from van Baarle)
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'''Product re-use'''
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<br /> • ''Further processing techniques''<br />
  
Damaged tyres are, more often than not, repaired. Tubes can be patched and tyres can be repaired by one of a number of methods. Regrooving is a practice carried out in many developing countries where regulations are slacker and standards are lower (and speeds are lower) than in the West. It is often carried out by hand and is labour intensive.
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<blockquote>
  
The use of retread tyres saves valuable energy and resources. A new tyre requires 23L of crude oil equivalent for raw materials and 9L for process energy compared with 7L and 2L respectively for retreading. Tyres of passenger vehicles can generally be retreaded only once while truck and bus tyres can be retreaded up to six times. Retreading is a well established and acceptable (in safety terms) practice. The process involves the removal of the remaining tread (producing tyre crumb - see later) and the application and vulcanisation of a new tread (the 'camel back') onto the remaining carcass. In Nairobi about 10,000 tyres a week are received for retreading (Ahmed).
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• ''Extrusion and pelletising''. The process of extrusion is employed to homogenise the reclaimed polymer and produce a material that it subsequently easy to work. The reclaimed polymer pieces are fed into the extruder, are heated to induce plastic behaviour and then forced through a die (see the following section on manufacturing techniques) to form a plastic spaghetti which can then be cooled in a water bath before being pelletised. The pelletisation process is used to reduce the ‘spaghetti’ to pellets which can then be used for the manufacture of new products.
  
Secondary reuse of whole tyres is the next step in the waste management hierarchy. Tyres are often put to use because of their shape, weight, form or volume. Some examples of secondary use in industrialised countries include use for erosion control, as tree guards, in artificial reefs, fences or as garden decoration. In developing countries wells can be lined with old tyres, docks are often lined with old tyres which act as shock absorbers, and similarly crash barriers can be constructed from old tyres. Old inner tubes also have many uses; swimming aids and water containers being two simple examples.
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</blockquote>
  
<center>
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<br /> • ''Manufacturing techniques''<br />
  
[[Image:p5.jpg]]<br /> Figure 3: Following the grooves is a Labour -intensive process. © Knud Sauer - WASTE
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<blockquote>
  
</center>
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• ''Extrusion''. The extrusion process used for manufacturing new products is similar to that outlined above for the process preceding pelletisation, except that the product is usually in the form of a continuous ‘tube’ of plastic such as piping or hose. The main components of the extrusion machine are shown in Fig. 2 below. The reclaimed plastic is forced along the heated tube by an archimedes screw and the plastic polymer is shaped around a die. The die is designed to give the required dimensions to the product and can be interchanged.
  
'''Material re-use'''
+
''Injection moulding''. The first stage of this manufacturing process is identical to that of extrusion, but then the plastic polymer emerges through a nozzle into a split mould. The quantity of polymer being forced out is carefully controlled, usually by moving the screw forward in the heated barrel. A series of moulds would be used to allow continual production while cooling takes place. See Figure 2 below. This type of production technique is used to produce moulded products such as plates, bowls, buckets, etc.
  
The next step in our hierarchy involves the material being broken down and reused for the production of a new product. As mentioned earlier, in developing countries this hand reprocessing of rubber products to produce consumer goods is well established and the variety of products being made from reclaimed tyres and tubes is astonishing. The rubber used in tyres is a relatively easy material to reform by hand. It behaves in a similar manner to leather and has in fact replaced leather for a number of applications. The tools required for making products directly from tyre rubber are not expensive and are few in number. Shears, knives, tongs, hammers, etc., all common tools found in the recyclers' workshop, along with a wide range of improvised tools for specialised applications. Shoes, sandals, buckets, motor vehicle parts, doormats, water containers, pots, plant pots dustbins and bicycles pedals are among the products manufactured.
+
• ''Blow moulding''. Again the spiral screw forces the plasticised polymer through a die. A short piece of tube, or ‘parison’ is then enclosed between a split die -which is the final shape of the product - and compressed air is used to expand the parison until it fills the mould and achieves its required shape. This manufacturing technique is used for manufacturing closed vessels such as bottles and other containers. See Figure 2 below.
  
Another way in which physical reuse can be achieved is by reducing the tyre to a granular form and then reprocessing. This can be a costly process and there has to be a manufacturer willing to purchase the granules. Crumb rubber from the retreading process can be used in this way, as it is a good quality granulated rubber. The reprocessing techniques used are similar to those described in earlier chapters. Granulate tends to be used for low-grade products such as automobile floor mats, shoe soles, rubber wheels for carts and barrows, etc., and can be added to asphalt for road construction, where it improved the properties of this material.
+
• ''Film blowing''. Film blowing is a process used to manufacture such items as garbage bags. It is a technically more complex process than the others described in this brief and requires high quality raw material input. The process involves blowing compressed air into a thin tube of polymer to expand it to the point where it becomes a thin film tube. One end can then be sealed and the bag or sack is formed. Sheet plastic can also be manufactured using a variation of the process described.
  
<center>
+
</blockquote><center>
  
[[Image:Rubber_Recycling_3.jpg]]<br /> Figure 4: Garbage containers made from Truck tyres. Manila, The Philippines © CAPS - WASTE
+
[[Image:recycle_plastic006.jpg]]<br /> Figure 5: Plastic manufacturing techniques; extrusion (top), blow moulding (middle) and injection moulding (bottom).
  
</center>
+
</center></div>
  
'''Chemical and thermal recovery'''
+
==Products from plastic==
  
This type of recovery is not only lower in the waste management hierarchy, but is also a higher technology requiring sophisticated equipment. The applicability of such technologies for small-scale applications in developing countries is very limited. We will therefore look only very briefly at a couple of processes. Chemical recovery is the process of heating waste rubber reclaim, treating it with chemicals and then processing the rubber mechanically.<br />
+
<div class="booktext">
  
<blockquote>
+
There is an almost limitless range of products that can be produced from plastic. However, the market for recycled plastic products is limited due to the inconsistency of the raw material. Many manufacturers will only incorporate small quantities of well-sorted recycled material in their products whereas others may use a much higher percentage of recycled polymers. Much depends on the quality required.
  
• Acid reclamation - uses hot sulphuric acid to destroy the fabric incorporated in the tyre and heat treatment to render the scrap rubber sufficiently plastic to allow its use as a filler with batches of crude rubber.
+
In developing countries, where standards are often lower and raw materials very expensive, there is a wider scope for use of recycled plastic material. The range of products varies from building materials to shoes, kitchen utensils to office equipment, sewage pipe to beauty aids.
  
• Alkali recovery - Reclaimed rubber, treated by heating with alkali for 12 to 30 hours, can be used as an adulterant of crude rubber to lower the price of the finished article. The amounts of reclaimed rubber that are used depend on the quality of the article to be manufactured.
+
'''Manufacturers of plastics recycling equipment'''
  
</blockquote>
+
Machinery for plastics recycling and processing varies in size and sophistication. In most developing countries it is not possible to find new equipment which can be purchased off-the-shelf and machinery will either have to be imported, manufactured locally, or improvised. Within the informal sector, the latter is usually the most common method of procuring equipment and the level of improvisation is often admirable and ingenious.
  
<br /> One form of thermal recovery is pyrolysis. This involves heating the tyre waste in the absence of oxygen which causes decomposition into gases and constituent parts. It is a technology which is still immature in the tyre-reprocessing field.
+
Below are the addresses if some manufacturers and suppliers of plastics recycling equipment (for a more comprehensive list see Vogler [1]):
  
'''Energy recovery'''
+
<div align="left">
  
Tyres consist of around 60% hydrocarbons, which is a store of energy that can be recovered by incineration. The heat produced can be used directly in processes such as cement making, or to raise steam for a variety of uses, including electricity generation. Again, this technology requires sophisticated plant and its application is limited when looking at small-scale enterprise.
+
{| cellpadding="5"
 
+
|- valign="top"
'''Landfill'''
+
| valign="top" |
 +
Brimco Plastic Machinery Prt. Ltd.<br /> 55 Gort Industrial Estate,<br /> Kandirli (West),<br /> Mumbai 400 067,<br /> India.
 +
| valign="top" |
 +
Plasplant Machinery Ltd.<br /> Bordon Trading Estate,<br /> Oakhanger Road,<br /> Bordon, Hants, GU35 9HH.<br /> UK.
 +
|- valign="top"
 +
| valign="top" |
 +
Produce general equipment for plastics manufacture.
 +
| valign="top" |
 +
Suppliers of used and new equipment for plastics recycling. Many years experience of supplying to developing countries.
 +
|}
  
Landfill is the final step in the waste management hierarchy. The landfill disposal of tyres, if properly managed, does not constitute an environmental problem. However, concerns about conserving resources and energy have seen an increasing opposition to landfilling. Also, public sanitation and municipal waste management is often ineffective in developing countries and scrap tyres are often found littering the streets.
+
</div></div>
 
 
</div>
 
  
 
==References and further reading==
 
==References and further reading==
  
<div class="booktext">
+
'''This Howtopedia entry was derived from the Practical Action Technical Brief ''Energy from the Wind''.  <br />To look at the original document follow this link: http://http://www.practicalaction.org/?id=technical_briefs_manufacturing'''
  
1. Ahmed, R., Klundert, Arnold van de, Lardinois, I., ''Rubber Waste, Options for Small-scale Resource Recovery,'' TOOL Publications and WASTE, 1996. A book aimed at small-scale rubber recyclers in developing countries.
 
  
2. Vogler, Jon, ''Work from Waste,'' Intermediate Technology Publications and Oxfam, 1981. A classic for those wishing to recycle waste and create employment.
+
1. Vogler, Jon, ''Small-scale recycling of plastics.'' Intermediate Technology Publications 1984. A book aimed at small-scale plastics recycling in developing countries.
  
3. Baarle, B. van, ''Het hervewerken van Rubberafval van Personenevagenbanden (Reuse of Rubber from Passenger Vehicles),'' NOVEM / RIVM, The Netherlands 1988.
+
2. Vogler, Jon, ''Work from Waste.'' Intermediate Technology Publications 1981. A classic text for those recycling wastes to create employment.
  
4. "Rubber," ''Microsoft® Encarta® 98 Encyclopedia.'' © 1993-1997 Microsoft Corporation. All rights reserved.
+
3. Lardinois, I., and van de Klundert, A., ''Plastic Waste, Option for small-scale resource recovery.'' TOOL 1995. A publication in the urban solid waste series. Gives many examples of successful plastics recycling operations in developing countries.
  
5. ''Scrap Tire and Rubber Recycling Terminology Booklet'' developed by the ITRA Tire and Rubber Recycling Advisory Council (TRRAC) (See address in following section). It is a valuable resource to understanding the tire industry and tire recycling issues.
+
4. Birley, A. W., Heath, R. J., and Scott, M. J. ''Plastics Materials.'' Blackie, 2nd ed. 1988. Introductory scientific textbook.
  
6. Porteous, Andrew, ''Recycling Resources Refuse,'' Longman 1977.
+
5. Harper, Charles A., and others, etc. ''Handbook of Plastics and Elastomers.'' McGraw-Hill, 1975. Basic data on design, construction and use.
  
'''Internet addresses'''
+
6. Roth, Laszlo. ''A Basic Guide to Plastics for Designers, Technicians, and Crafts People.'' Prentice-Hall, 1985. Introduction to materials and technology.
  
<u>http://www.itra.com/corporate/recycling/trrac.htm</u><br /> International Tire and Rubber Association (ITRA) Home Page. A wealth of information on recycling of tyres and associated topics.
+
7. Sparke, Penny, ed. ''The Plastics Age: from Modernity to Post-Modernity.'' Victoria and Albert Museum, 1990. A celebration of the usefulness and aesthetics of plastics; well illustrated.
  
<u>http://www.wrf.org.uk</u><br /> Web site of the World Resource Foundation (see previous section).
+
8. "Plastics," ''Microsoft® Encarta® 98 Encyclopedia.'' © 1993-1997 Microsoft Corporation. Encyclopedia article.
 
 
<u>http://www.rapra.net</u><br /> Web site of RAPRA (see previous section).
 
 
 
<u>http://usrubber.com/</u><br /> US Rubber Inc. A commercial Website with an interesting range of products from recycled rubber.
 
  
 
</div>
 
</div>
Line 367: Line 311:
 
<div class="booktext">
 
<div class="booktext">
  
World Resource Foundation<br /> Heath House<br /> 133 High Street, Tonbridge<br /> Kent TN9 1DH<br /> Tel +44 (0)1732 368333<br /> Fax +44 (0)1732 368337<br /><u>http://www.wrf.org.uk</u> email; <u>[mailto:wrf@wrf.org.uk wrf@wrf.org.uk]</u><br /> 'The Warmer Bulletin' published 4 times a year (subscription required)
+
World Resource Foundation<br /> Heath House<br /> 133 High Street, Tonbridge<br /> Kent TN9 1DH<br /> Tel +44 ( 0)1732 368333<br /> Fax +44 (0)1732 368337<br /> email: [mailto:wrf@wrf.org.uk wrf@wrf.org.uk]<br />http://www.wrf.org.uk<br /> The Warmer Bulletin' published 4 times a year (subscription required)
  
CAPS<br /> Room 202, Loyola Heights Cond.<br /> Est Abada crnr F de la Rosa St<br /> 1109 Loyola Heights, Quezon City<br /> The Philippines.<br /> Contact: Mr. Dan Lapid<br /> Tel: +63 (2) 4345573<br /> Fax: +63 (2) 4345954<br /> Email: <u>[mailto:danlapid@mnl.sequel.net danlapid@mnl.sequel.net]</u><br /> Consultants with on-line enquiries, training, info and education.
+
WASTE Nieuwehaven 201,<br /> 2801 VW Gouda, The Netherlands.<br /> Tel: +31 (0)182 522 625<br /> Fax: +31 (0)182 550313<br /> email: [mailto:office@waste.nl office@waste.nl]<br /> Consultants in Urban waste management in developing countries.
  
 
UNDP / World Bank<br /> Integrated Resource Recovery Programme,<br /> 1818 H. Street NW, Washington DC, USA.<br /> Tel: +1 (202) 477 1254<br /> Fax: +1 (202) 477 1052<br /> Publications on policy and case studies
 
UNDP / World Bank<br /> Integrated Resource Recovery Programme,<br /> 1818 H. Street NW, Washington DC, USA.<br /> Tel: +1 (202) 477 1254<br /> Fax: +1 (202) 477 1052<br /> Publications on policy and case studies
  
RAPRA Technology Ltd.<br /> Shawbury, Shrewsbury,<br /> Shropshire SY4 4NR<br /> Tel: +44 (0)1939 250 383<br /> Fax: +44 (0)1939 251 118<br /> Technical info centre for rubbers and plastics, consulting and analysis services. Publish Journal 'Progress in Rubber and Plastics technology'
+
TNO Plastics and Rubber Research Inst.<br /> PO Box 6031, 2600 JA Delft,<br /> The Netherlands.<br /> Tel: +31 (15) 69 66 21<br /> Fax: +31 (15) 56 63 08<br /> Research into plastics and rubber, advice and training.
  
WASTE Nieuwehaven 201,<br /> 2801 CW Gouda, The Netherlands.<br /> Tel: +31 (0)182 522 625<br /> Fax: +31 (0)182 550313<br /> Email: <u>[mailto:office@waste.nl office@waste.nl]</u><br /> Advisers on urban environment and development.<br /> Anne-Lies Risseeuw - Compiles regular Urban Waste Expertise Programme Bulletin
+
RAPRA Technology Ltd.<br /> Shawbury, Shrewsbury,<br /> Shropshire SY4 4NR<br /> Tel: +44 (0)1939 250 383<br /> Fax: +44 (0)1939 251 118<br /> Website: <u>http://www.rapra.net</u><br /> Technical info centre for rubbers and plastics, consulting and analysis services.<br /> Publish Journal '''Progress in Rubber and Plastics technology''' and a publications catalogue
  
ITRA Tire and Rubber Recycling<br /> Advisory Council, P.O. Box 37203, Louisville,<br /> Kentucky 40233-7203 USA,<br /> Tel: +1 800-426-8835, 502-968-8900<br /> Fax: +1 502-964-7859,<br /> E-mail: [mailto:itra@itra.com itra@itra.com]
+
European Centre for Plastics in the Environment and Association of Plastics Manufacturers in Europe,(APME),<br /> Avenue E. van Nieuwenhuyse 4, BP3,<br /> B-1160 Brussels, Belgium<br /> Tel: +32 (2) 675 32 97<br /> Fax: +32 (2) 675 39 35<br /> General info on plastics waste recycling
  
TNO Plastics and Rubber Research Inst.<br /> PO Box 6031, 2600 JA Delft,<br /> The Netherlands.<br /> Tel: +31 (15) 69 66 21<br /> Fax: +31 (15) 56 63 08<br /> Research into plastics and rubber, advice and training.
+
Plastics Recycling Foundation,<br /> 1275 K Street NW, Suite 400,<br /> Washington DC 20005, USA.<br /> Tel: +1 (202) 371 5337<br /> Sponsor R&D, Info on technology and markets.
 +
 
 +
Appropriate Technology Development Association,<br /> PO Box 311, Gandhi Bhawan,<br /> Lucknow-226001, U.P.<br /> India.<br /> Research Institute - rubber and plastics
 +
 
 +
Environmental Development Action in the Third World,<br /> Head Office: PO Box 3370, Dakar, Senegal.<br /> Tel: +221 (22) 42 29 / 21 60 27<br /> Fax: +221 (22) 26 95<br /> Regional offices in Colombia, Bolivia and Zimbabwe. Database, library, publications and advice. Quarterly magazine 'African Environment'
  
Environmental Development Action in the Third World,<br /> Head Office: PO Box 3370, Dakar, Senegal.<br /> Tel: +221 (22) 42 29 / 21 60 27<br /> Fax: +221 (22) 26 95<br /> Regional offices in Colombia, Bolivia and Zimbabwe<br /> Database, library, publications and advice.<br /> Quarterly magazine 'African Environment'
+
CAPS<br /> Room 8, Maya Building, 678 EDSA, Cubao,<br /> Quezon City, Metro Manila,<br /> The Philippines.<br /> Contact: Mr. Dan Lapid<br /> Tel: +63 (2) 912 36 08<br /> Fax: +63 (2) 912 34 79<br /> Consultants with on-line enquiries, training, info and education.
  
Appropriate Technology Development Association,<br /> PO Box 311, Gandhi Bhawan,<br /> Lucknow-226001, U.P.<br /> India.<br /> Research Institute - rubber and plastics
+
'''Internet addresses'''
  
'''Practical Action, The Schumacher Centre for Technology & Development'''<br />'''Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK'''<br />'''Tel: +44 (0)1926 634400 Fax: +44 (0)1926 634401 E-mail: [mailto:Infoserv@practicalaction.org.uk Infoserv@practicalaction.org.uk] Web: http://www.practicalaction.org'''<br />'''Intermediate Technology Development Group Ltd Patron HRH -The Prince of Wales. KG, KT, GCB'''<br />'''Company Rag. No 871954, England Rag. Charity No 247257 VAT No 241 5154 92'''<br />
+
<u>http://www.polymers.com/dotcom/home.html</u>
  
</div>
+
This is the polymers and plastics industry site which contains an online magazine, links to tutorials and chemistry guides, and links to related sites. Registration is required.
  
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'''Practical Action, The Schumacher Centre For Technology & Development'''<br />'''Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK'''<br />'''Tel: + 44(0) 1926 634400 Fax: +44(0) 1926 634401'''<br />'''E-mail: [mailto:Infoserv@practicalaction.org.uk Infoserv@practicalaction.org.uk] Web: http://www.practicalaction.org'''<br />'''Intermediate Technology Development Group Ltd'''<br />'''Patron HRH - The Prince of Wales, KG, KT, GCB'''<br />'''Company Reg. No 871954, England Reg. Charity No 247257 VAT No 241 5154 92'''<br />
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<span class="langmeniuactiv"> English </span><nowiki>|</nowiki>[gsdl?e=d-00gtzinti---000--1-0--010---4----0--0-10l--1en-5000---50-about-0---01131-0011T7%2eCNJnXc0a8012f0000057844f1611d-0utfZz-8-0-0&cl=CL2.1.5&d=Js7754e&az=A&gt=2&gc=&ihs=0&l=fr&az=A&p=about  French ]<nowiki>|</nowiki>[gsdl?e=d-00gtzinti---000--1-0--010---4----0--0-10l--1en-5000---50-about-0---01131-0011T7%2eCNJnXc0a8012f0000057844f1611d-0utfZz-8-0-0&cl=CL2.1.5&d=Js7754e&az=A&gt=2&gc=&ihs=0&l=es&az=A&p=about  Spanish ]
 
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Revision as of 14:52, 27 August 2006

Recycling Plastics

Plastics - what are they and how do they behave?

Plastics are organic polymeric materials consisting of giant organic molecules. Plastic materials can be formed into shapes by one of a variety of processes, such as extrusion, moulding, casting or spinning. Modern plastics (or polymers) possess a number of extremely desirable characteristics; high strength to weight ratio, excellent thermal properties, electrical insulation, resistance to acids, alkalis and solvents, to name but a few.

These polymers are made of a series of repeating units known as monomers. The structure and degree of polymerisation of a given polymer determine its characteristics. Linear polymers (a single linear chain of monomers) and branched polymers (linear with side chains) are thermoplastic, that is they soften when heated. Cross-linked polymers (two or more chains joined by side chains) are thermosetting, that is, they harden when heated.

Recycle plastic001.gif
Figure 1: Polymer structures

Thermoplastics make up 80% of the plastics produced today. Examples of thermoplastics include;

high density polyethylene (HDPE) used in piping, automotive fuel tanks, bottles, toys,
low density polyethylene (LDPE) used in plastic bags, cling film, flexible containers;
polyethylene terephthalate (PET) used in bottles, carpets and food packaging;
polypropylene (PP) used in food containers, battery cases, bottle crates, automotive parts and fibres;
polystyrene (PS) used in dairy product containers, tape cassettes, cups and plates;
polyvinyl chloride (PVC) used in window frames, flooring, bottles, packaging film, cable insulation, credit cards and medical products.


There are hundreds of types of thermoplastic polymer, and new variations are regularly being developed. In developing countries the number of plastics in common use, however, tends to be much lower.

Thermosets make up the remaining 20% of plastics produced. They are hardened by curing and cannot be re-melted or re-moulded and are therefore difficult to recycle. They are sometimes ground and used as a filler material. They include: polyurethane (PU) - coatings, finishes, gears, diaphragms, cushions, mattresses and car seats; epoxy - adhesives, sports equipment, electrical and automotive equipment; phenolics - ovens, handles for cutlery, automotive parts and circuit boards (The World Resource Foundation).

Nowadays, the raw materials for plastics come mainly from petrochemicals, although originally plastics were derived from cellulose, the basic material of all plant life.

Why recycle plastics?

In ‘western’ countries, plastic consumption has grown at a tremendous rate over the past two or three decades. In the ‘consumer’ societies of Europe and America, scarce petroleum resources are used for producing an enormous variety of plastics for an even wider variety of products. Many of the applications are for products with a life-cycle of less than one year and then the vast majority of these plastics are then discarded. In most instances reclamation of this plastic waste is simply not economically viable.

In industry (the automotive industry for example) there is a growing move towards reuse and reprocessing of plastics for economic, as well as environmental reasons, with many praiseworthy examples of companies developing technologies and strategies for recycling of plastics.

Not only is plastic made from a non-renewable resource, but it is generally non-biodegradable (or the biodegradation process is very slow). This means that plastic litter is often the most objectionable kind of litter and will be visible for weeks or months, and waste will sit in landfill sites for years without degrading.

Plastics fact file

• More than 20,000 plastic bottles are needed to obtain 1 tonne of plastic.
• It is estimated that 100 million tonnes of plastics are produced each year.
• The average European throws away 36kg of plastics each year.
• 4% of oil consumption in Europe is used for the manufacture of plastic products.
• Some plastic waste sacks are made from 64% recycled plastic.
• Plastics packaging totals 42% of total consumption and very little of this is recycled.

Although there is also a rapid growth in plastics consumption in the developing world, plastics consumption per capita in developing countries is much lower than in the industrialised countries. These plastics are, however, often produced from expensive imported raw materials. There is a much wider scope for recycling in developing countries due to several factors:

• Labour costs are lower.

• In many countries there is an existing culture of reuse and recycling, with the associated system of collection, sorting, cleaning and reuse of ‘waste’ or used materials.

• There is often an ‘informal sector’ which is ideally suited to taking on small-scale recycling activities. Such opportunities to earn a small income are rarely missed by members of the urban poor.

• There are fewer laws to control the standards of recycled materials. (This is not to say that standards can be low - the consumer will always demand a certain level of quality).

• Transportation costs are often lower, with hand or ox carts often being used.

• Low cost raw materials give an edge in the competitive manufacturing world.

• Innovative use of scrap machinery often leads to low entry costs for processing or manufacture.


In developing countries the scope for recycling of plastics is growing as the amount of plastic being consumed increases.

Plastics for recycling

Not all plastics are recyclable. There are 4 types of plastic which are commonly recycled:

• Polyethylene (PE) - both high density and low-density polyethylene.
• Polypropylene (PP)
• Polystyrene (PS)
• Polyvinyl chloride (PVC)


A common problem with recycling plastics is that plastics are often made up of more than one kind of polymer or there may be some sort of fibre added to the plastic (a composite) to give added strength. This can make recovery difficult.

Sources of waste plastics

Industrial waste (or primary waste) can often be obtained from the large plastics processing, manufacturing and packaging industries. Rejected or waste material usually has good characteristics for recycling and will be clean. Although the quantity of material available is sometimes small, the quantities tend to be growing as consumption, and therefore production, increases.

Commercial waste is often available from workshops, craftsmen, shops, supermarkets and wholesalers. A lot of the plastics available from these sources will be PE, often contaminated.

Agricultural waste can be obtained from farms and nursery gardens outside the urban areas. This is usually in the form of packaging (plastic containers or sheets) or construction materials (irrigation or hosepipes).

Recycle plastic003.jpg
Figure 2: Mixed waste plastic requiring sorting before it can be recycled. ©World Resource Foundation

Municipal waste can be collected from residential areas (domestic or household waste), streets, parks, collection depots and waste dumps. In Asian cities this type of waste is common and can either be collected from the streets or can be collected from households by arrangement with the householders. (Lardinois 1995)

Identification of different types of plastics

There are several simple tests that can be used to distinguish between the common types of polymers so that they may be separated for processing.

The water test. After adding a few drops of liquid detergent to some water put in a small piece of plastic and see if it floats.

Burning test. Hold a piece of the plastic in a tweezers or on the back of a knife and apply a flame. Dose the plastic burn? If so, what colour?

Fingernail test. Can a sample of the plastic be scratched with a fingernail?

Test

PE

PP

PS

PVC*

Water

Floats

Floats

Sinks

Sinks

Burning

Blue flame with yellow tip, melts and drips.

Yellow flame with blue base.

Yellow, sooty flame - drips.

Yellow, sooty smoke. Does not continue to burn if flame is removed

Smell after burning

Like candle wax.

Like candle wax - less strong than PE

Sweet

Hydrochloric acid

Scratch

Yes

No

No

No

*To confirm PVC, touch the sample with a red-hot piece of copper wire and then hold the wire to the flame. A green flame from the presence of chlorine confirms that it is PVC.
Source: Vogler. 1984


To determine if a plastic is a thermoplastic or a thermoset, take a piece of wire just below red heat and press it into the material. If the wire penetrates the material, it is a thermoplastic; if it does not it is a thermoset.

A coding system has also been introduced in the United States to aid identification of plastics for reclamation. It is based on the ‘Recycle Triangle’ with a series of numbers and letters to help with identification. More information is available from the Association of Plastic Manufacturers in Europe (APME). See useful addresses section later in this brief.

Collection

When thinking about setting up a small-scale recycling enterprise, it is advisable to first carry out a survey to ascertain the types of plastics available for collection, the type of plastics used by manufacturers (who will be willing to buy the reclaimed material), and the economic viability of collection.

The method of collection can vary. The following gives some ideas;

• House to house collection of plastics and other materials (e.g. paper).
• House to house collection of plastics only (but all types of polymer).
• House to house collection of certain objects only.
• Collection at a central point e.g. market or church.
• Collection from street boys in return for payment.
• Regular collection from shops, hotels, factories, etc.
• Purchase from scavengers on the municipal dump.
• Scavenging or collecting oneself.


The method will depend upon the scale of the operation, the capital available for set-up, transport availability, etc.

Processing of reclaimed plastic - processes and technology for small-scale recycling enterprises

Initial upgrading. Once the plastic has been collected, it will have to be cleaned and sorted. The techniques used will depend on the scale of the operation and the type of waste collected, but at the simplest level will involve hand washing and sorting of the plastic into the required groups. More sophisticated mechanical washers and solar drying can be used for larger operations. Sorting of plastics can be by polymer type (thermoset or thermoplastic for example), by product (bottles, plastic sheeting, etc.), by colour, etc.

Recycle plastic004.jpg
Figure 3: Collection of Waste Materials. © World Resource Foundation

Recycle plastic005.gif
Figure 4: Flow chart of a typical waste plastic reprocessing stream in a low-income country (TOOL 1995)

Size reduction techniques. Size reduction is required for several reasons; to reduce larger plastic waste to a size manageable for small machines, to make the material denser for storage and transportation, or to produce a product which is suitable for further processing. There are several techniques commonly used for size reduction of plastics;

Cutting is usually carried out for initial size reduction of large objects. It can be carried out with scissors, shears, saw, etc.

Shredding is suitable for smaller pieces. A typical shredder has a series of rotating blades driven by an electric motor, some form of grid for size grading and a collection bin. Materials are fed into the shredder via a hopper which is sited above the blade rotor. The product of shredding is a pile of coarse irregularly shaped plastic flakes which can then be further processed.

Agglomeration is the process of pre-plasticising soft plastic by heating, rapid cooling to solidify the material and finally cutting into small pieces. This is usually carried out in a single machine. The product is coarse, irregular grain, often called crumbs.


Further processing techniques

Extrusion and pelletising. The process of extrusion is employed to homogenise the reclaimed polymer and produce a material that it subsequently easy to work. The reclaimed polymer pieces are fed into the extruder, are heated to induce plastic behaviour and then forced through a die (see the following section on manufacturing techniques) to form a plastic spaghetti which can then be cooled in a water bath before being pelletised. The pelletisation process is used to reduce the ‘spaghetti’ to pellets which can then be used for the manufacture of new products.


Manufacturing techniques

Extrusion. The extrusion process used for manufacturing new products is similar to that outlined above for the process preceding pelletisation, except that the product is usually in the form of a continuous ‘tube’ of plastic such as piping or hose. The main components of the extrusion machine are shown in Fig. 2 below. The reclaimed plastic is forced along the heated tube by an archimedes screw and the plastic polymer is shaped around a die. The die is designed to give the required dimensions to the product and can be interchanged.

Injection moulding. The first stage of this manufacturing process is identical to that of extrusion, but then the plastic polymer emerges through a nozzle into a split mould. The quantity of polymer being forced out is carefully controlled, usually by moving the screw forward in the heated barrel. A series of moulds would be used to allow continual production while cooling takes place. See Figure 2 below. This type of production technique is used to produce moulded products such as plates, bowls, buckets, etc.

Blow moulding. Again the spiral screw forces the plasticised polymer through a die. A short piece of tube, or ‘parison’ is then enclosed between a split die -which is the final shape of the product - and compressed air is used to expand the parison until it fills the mould and achieves its required shape. This manufacturing technique is used for manufacturing closed vessels such as bottles and other containers. See Figure 2 below.

Film blowing. Film blowing is a process used to manufacture such items as garbage bags. It is a technically more complex process than the others described in this brief and requires high quality raw material input. The process involves blowing compressed air into a thin tube of polymer to expand it to the point where it becomes a thin film tube. One end can then be sealed and the bag or sack is formed. Sheet plastic can also be manufactured using a variation of the process described.

Recycle plastic006.jpg
Figure 5: Plastic manufacturing techniques; extrusion (top), blow moulding (middle) and injection moulding (bottom).

Products from plastic

There is an almost limitless range of products that can be produced from plastic. However, the market for recycled plastic products is limited due to the inconsistency of the raw material. Many manufacturers will only incorporate small quantities of well-sorted recycled material in their products whereas others may use a much higher percentage of recycled polymers. Much depends on the quality required.

In developing countries, where standards are often lower and raw materials very expensive, there is a wider scope for use of recycled plastic material. The range of products varies from building materials to shoes, kitchen utensils to office equipment, sewage pipe to beauty aids.

Manufacturers of plastics recycling equipment

Machinery for plastics recycling and processing varies in size and sophistication. In most developing countries it is not possible to find new equipment which can be purchased off-the-shelf and machinery will either have to be imported, manufactured locally, or improvised. Within the informal sector, the latter is usually the most common method of procuring equipment and the level of improvisation is often admirable and ingenious.

Below are the addresses if some manufacturers and suppliers of plastics recycling equipment (for a more comprehensive list see Vogler [1]):

Brimco Plastic Machinery Prt. Ltd.
55 Gort Industrial Estate,
Kandirli (West),
Mumbai 400 067,
India.

Plasplant Machinery Ltd.
Bordon Trading Estate,
Oakhanger Road,
Bordon, Hants, GU35 9HH.
UK.

Produce general equipment for plastics manufacture.

Suppliers of used and new equipment for plastics recycling. Many years experience of supplying to developing countries.

References and further reading

This Howtopedia entry was derived from the Practical Action Technical Brief Energy from the Wind.
To look at the original document follow this link: http://http://www.practicalaction.org/?id=technical_briefs_manufacturing


1. Vogler, Jon, Small-scale recycling of plastics. Intermediate Technology Publications 1984. A book aimed at small-scale plastics recycling in developing countries.

2. Vogler, Jon, Work from Waste. Intermediate Technology Publications 1981. A classic text for those recycling wastes to create employment.

3. Lardinois, I., and van de Klundert, A., Plastic Waste, Option for small-scale resource recovery. TOOL 1995. A publication in the urban solid waste series. Gives many examples of successful plastics recycling operations in developing countries.

4. Birley, A. W., Heath, R. J., and Scott, M. J. Plastics Materials. Blackie, 2nd ed. 1988. Introductory scientific textbook.

5. Harper, Charles A., and others, etc. Handbook of Plastics and Elastomers. McGraw-Hill, 1975. Basic data on design, construction and use.

6. Roth, Laszlo. A Basic Guide to Plastics for Designers, Technicians, and Crafts People. Prentice-Hall, 1985. Introduction to materials and technology.

7. Sparke, Penny, ed. The Plastics Age: from Modernity to Post-Modernity. Victoria and Albert Museum, 1990. A celebration of the usefulness and aesthetics of plastics; well illustrated.

8. "Plastics," Microsoft® Encarta® 98 Encyclopedia. © 1993-1997 Microsoft Corporation. Encyclopedia article.

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Useful addresses

World Resource Foundation
Heath House
133 High Street, Tonbridge
Kent TN9 1DH
Tel +44 ( 0)1732 368333
Fax +44 (0)1732 368337
email: wrf@wrf.org.uk
http://www.wrf.org.uk
The Warmer Bulletin' published 4 times a year (subscription required)

WASTE Nieuwehaven 201,
2801 VW Gouda, The Netherlands.
Tel: +31 (0)182 522 625
Fax: +31 (0)182 550313
email: office@waste.nl
Consultants in Urban waste management in developing countries.

UNDP / World Bank
Integrated Resource Recovery Programme,
1818 H. Street NW, Washington DC, USA.
Tel: +1 (202) 477 1254
Fax: +1 (202) 477 1052
Publications on policy and case studies

TNO Plastics and Rubber Research Inst.
PO Box 6031, 2600 JA Delft,
The Netherlands.
Tel: +31 (15) 69 66 21
Fax: +31 (15) 56 63 08
Research into plastics and rubber, advice and training.

RAPRA Technology Ltd.
Shawbury, Shrewsbury,
Shropshire SY4 4NR
Tel: +44 (0)1939 250 383
Fax: +44 (0)1939 251 118
Website: http://www.rapra.net
Technical info centre for rubbers and plastics, consulting and analysis services.
Publish Journal Progress in Rubber and Plastics technology and a publications catalogue

European Centre for Plastics in the Environment and Association of Plastics Manufacturers in Europe,(APME),
Avenue E. van Nieuwenhuyse 4, BP3,
B-1160 Brussels, Belgium
Tel: +32 (2) 675 32 97
Fax: +32 (2) 675 39 35
General info on plastics waste recycling

Plastics Recycling Foundation,
1275 K Street NW, Suite 400,
Washington DC 20005, USA.
Tel: +1 (202) 371 5337
Sponsor R&D, Info on technology and markets.

Appropriate Technology Development Association,
PO Box 311, Gandhi Bhawan,
Lucknow-226001, U.P.
India.
Research Institute - rubber and plastics

Environmental Development Action in the Third World,
Head Office: PO Box 3370, Dakar, Senegal.
Tel: +221 (22) 42 29 / 21 60 27
Fax: +221 (22) 26 95
Regional offices in Colombia, Bolivia and Zimbabwe. Database, library, publications and advice. Quarterly magazine 'African Environment'

CAPS
Room 8, Maya Building, 678 EDSA, Cubao,
Quezon City, Metro Manila,
The Philippines.
Contact: Mr. Dan Lapid
Tel: +63 (2) 912 36 08
Fax: +63 (2) 912 34 79
Consultants with on-line enquiries, training, info and education.

Internet addresses

http://www.polymers.com/dotcom/home.html

This is the polymers and plastics industry site which contains an online magazine, links to tutorials and chemistry guides, and links to related sites. Registration is required.

Practical Action, The Schumacher Centre For Technology & Development
Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK
Tel: + 44(0) 1926 634400 Fax: +44(0) 1926 634401
E-mail: Infoserv@practicalaction.org.uk Web: http://www.practicalaction.org
Intermediate Technology Development Group Ltd
Patron HRH - The Prince of Wales, KG, KT, GCB
Company Reg. No 871954, England Reg. Charity No 247257 VAT No 241 5154 92