Technologies for the Identification, Separation and Recycling of
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Technologies for the Identification, Separation and Recycling of Automotive Plastics by Joerg Hendrix*, Kevin A. Massey*, Eric Whitham* and Bert Bras** Systems Realization Laboratory The George W. Woodruff School of Mechanical Engineering Georgia Institute of Technology Atlanta, Georgia 30332-0405 U.S.A. Mark D. Russell+ Chrysler Corporation 800 Chrysler Drive East Auburn Hills, Michigan 48326-2757 U.S.A. ABSTRACT Virtually all of the material in today's automobiles can technically be recycled. The challenge facing engineers is making this recycling process economical, especially for the materials in such components as seats and instrument panels. Recycling these components requires the different materials to be separated so that each can be recycled individually. This separation can be accomplished either manually, where workers disassembly and sort the vehicle components by hand, or mechanically, where the vehicle is shredded and the materials sorted by properties such as conductivity and density. In this paper, we provide an overview of efforts and technologies which primarily support automated separation and recycling. Although the paper is focused on * ** + Undergraduate research assistant Assistant Professor, corresponding author Supervisor Quality Planning and Recycling, Large Car Platform Submitted to International Journal of Environmentally Conscious Design and Manufacturing, March 1996. automotive applications, many of the technologies are applicable to white goods and consumer electronic products as well. –2 – 1 OUR FRAME OF REFERENCE Whether motivated by recent legislative efforts or by a moral sense of obligation, automotive manufacturers are attempting to reduce the environmental impacts of the entire life cycle of their vehicles. Specifically, the manufacturers are attempting to improve the recyclability of their vehicles and therefore reduce the percentage of each car which must be disposed of in a landfill. In Europe, legislation has been proposed that requires car manufacturers to be responsible for comprehensive recycling and material recovery from their vehicles. The increased emphasis on recyclability has among others led to the establishment of the Vehicle Recycling and Development Center (VRDC) in Detroit which serves as the headquarters of the Vehicle Recycling Partnership (VRP), a cooperative effort among Chrysler, Ford, and General Motors as part of the USCAR initiative. Since most of the steel and metals from these vehicles (which constitute about 75% of a vehicles weight) are already recycled (see, e.g., [1]), the concentration of recent efforts has been on the vehicle sub-systems which are mostly non-metal - for instance, the polymers in the bumper systems, the instrument panel, the seats, and other interior trim components. The need to focus on non-metal parts is emphasized by the undeniable shift towards a lower metal content in most cars. Over the last 20 years, the metal percentage has dropped approximately 10% of the weight of the car - from about 85% to about 75%. This has translated to cars which are less recyclable, since the only well developed recycling infrastructure is for steel and other metals. However, the change has resulted in lighter, cheaper, more fuel efficient vehicles. Currently, automobiles are recycled aproximately 75 percent by weight and mainly the ferrous and non-ferrous metals are recycled from the discarded vehicle by shredding the vehicle and magnetically sorting the metals. The remaining 25 percent is known as automobile shredder residue. This residue contains potentially recycleable materials including polyurethane foams and thermoplastics. Currently the residue is landfilled. However as tipping fees increase, legislative recycling recycling targets increase, and the use of plastics in automobiles also increases, it will become necessary to find ways to divert this material from the landfill and utilize it in a profitable manner, either through energy recovery, or by separating the different types of plastics, removing contaminants, and recycling different plastics contained in the shredder residue. In recent years, a great number of publications are available which deal directly with “designing for disassembly”. However, it must be emphasized that disassembly is only one step in the recycling process. In the German recycling guideline VDI 2243 [2], three generic sub-processes are identified which typically occur in a material recycling process, namely: • material separation, –3 – • material sorting, and • material reprocessing. In addition, practical experiments and findings indicate that although it is theoretically possible to dismantle and recycle a vehicle completely (100 %), it is not economically feasible. In promotional videos on automobile recyclingBMW and Mercedes both cite that it costs money to recycle cars. Studies at the VRDC and independent research on recycling cost assessments tend to confirm this (see, e.g., [3-5]). In this context, the objectives of the work presented in this paper were to catalog different types of plastic-from-plastic and plastic-from-metal separation technologies that exist in the recycling industry which may lead to economically feasible recycling. In addition, we investigated whether these technologies were commercially available or still under development. A number of plasticfrom-plastic and plastic-from-metal separation technologies were identified, as well as at least some of the companies/institutions which are either using or researching these technologies. The technologies and researchers/institutions were identified through an extensive literature search in both academic and trade literature, as well as through personal conversations and interviews. Though it is unlikely that all existing technologies have been identified, we feel that those technologies which were identified represent the majority of those in existence. Also, many of the companies and institutions identified are considered to be the prime movers and developers of such technologies in both the United States and Europe. In this paper, we will discuss • the role of manual dismantling, • mechanical separation technologies, • plastic identification technologies, • chemical recycling technologies. Prior to discussing the various technologies, we will first give an overview of the current vehicle recycling practice and recycling guidelines. 2 CURRENT AUTOMOBILE DISMATLING AND RECYCLING PRACTICE Recycling efforts in the U.S. exist because a profit can be made; without this incentive vehicles would simply be sent to landfills. Current recycling efforts for a vehicle consists of manual and mechanical separation (Figure 1). Reusable/remanufacturable components (such as engines and alternators) are manually removed from the car by dismantlers. These components are resold in a market limited to other vehicles of the same model, and often limited to the same year of manufacture. The vast majority of reusable/remanufactured items are powertrain components. –4 – When all these components are removed, materials with high value are removed by the dismantlers. For the most part, this consists of aluminum, magnesium, and other large pieces of pure metal. These materials are removed by hand because separate piles of aluminum and steel are worth significantly more than a commingled pile of the two metals. Vehicle Reusable/Remanufacturable Parts Dismantler Easily Accessible Pure Materials Hammer Mill or other Shredder Magnet Eddy Current Separator Ferrous Metals Non-ferrous metals Automotive Shredder Residue Figure 1 – Current Vehicle Dismantling and Separation Process Following this, the vehicle is sent to a shredder, shredded, and the pieces mechanically separated based on the properties. The only requirements for shredding are that the tires and gas tank (and preferably also other fluids like oils) are removed; the rest of the car (or whatever portions have not been removed by a dismantler) will be sent into a hammer mill or similar piece of equipment which reduces the vehicle to fist-sized pieces. The ferrous metals are magnetically separated into one pile, and the non-ferrous metals are generally separated using an eddy-current machine into another pile. The ferrous metals are then sold to a smelter. The non-ferrous metals, which are worth significantly more, are then separated into specific types of metal, either by the shredder or another company. The remainder of the car, about 25% by weight currently, is generally called Automotive Shredder Residue (ASR) or “fluff”. This ASR, which consists of plastics, rubber, glass, dirt, fluids, and other materials, is currently sent to a landfill. 3 VEHICLE RECYCLING GUIDELINES Due to the increased emphasis on product take-back and recycling, a wide variety of guidelines and methods for designing for recycling have been proposed in recent years. It would go beyond of the scope of this paper to provide a comprehensive list. The German national standard VDI 2243 represents a good example of the state of the art in design for recycling [2, 6]. Admittedly, –5 – the standard is still evolving and not completely applicable to US situations. To our knowledge, VDI 2243 has not been officially translated into English yet, but Beitz provides a general overview [6]. Many researchers have placed high emphasis on Designing for Disassembly (DFD). Boothroyd and Alting provide a good overview [7]. Extensive overviews are given in [8, 9]. Noller states some of the differences between design for disassembly and DFA [10]. For example, complete nesting can slow disassembly by not providing a location for the disassembler to reach, grasp, or otherwise handle. Other sources for design guidelines and efforts facilitating recycling are, e.g., [11-19]. However, many of the DFD guidelines focus on manual disassembly and fail to take destructive disassembly through automated processes into account. In [5], the argument is made that a component designed for manual disassembly is not necessarily easy to disassemble mechanically. In the U.S., two major organizations which are very involved in the development of automotive dismantling technology are the American Plastics Council (APC) and the Vehicle Recycling Partnership (VRP). The VRP is managed by the United States Council for Automotive Research (USCAR) [1]. One APC project involved the collection of automotive plastic from both new cars and older cars dating from the 1970’s. The cars were manually disassembled and the plastics were sorted by resin type before being sent to the wTe Corporation’s Multi-Products Recycling Facility (MPRF) recycling operation for processing. The APC noted that newer cars required significantly less effort in the removal of the plastic, and that almost 40% of the parts recovered from newer cars had some sort of resin identification [20]. This is in part due to the increase in attention that vehicle recycling has gotten from automobile manufacturers and suppliers. Most automobile manufacturers have established vehicle recycling guidelines. In the U.S., Chrysler, Ford and General Motors each have their own recycling guidelines. Although slightly different in detail, they are very similar and all focus on the following issues: • material selection, e.g., reduce overall material diversity, avoid the use of laminates or make them out of compatible materials which can be recycled as a mixture, • fastener selection, e.g., reduce fastener count and diversity, avoid incompatible adhesives which degrade recyclability of materials, use snap fits where appropriate, and • component design issues, e.g., avoid paints and laminates, build in planes for easy separation and access. GM also includes packaging issues in their GM-520M recycling standard. It should be noted that all auto-makers are emphasizing the link between use of regulated substances and recycling and refer from their recycling guidelines to appropriate regulated substance elimination guidelines (e.g., Chrysler’s CS9003 and GM’s 1000M standards) because many components with regulated –6 – substances will have to be recycled, whether it is profitable or not. For example, chromium plated plastics may not be landfilled in Europe. Although many suppliers have been exposed to the various recycling standards, these recycling guidelines are not (yet) disseminated on a large scale by the automakers. 4 MANUAL DISASSEMBLY AND ITS ROLE IN PLASTIC RECOVERY In the automobile industry, an extensive infrastructure for ferrous and non-ferrous metal recycling is present, but no such infrastructure exists yet for plastics. It is only recently in the context of European take-back legislation that recycling of plastics embedded in products is being pursued in order to meet the stringent recycling levels set by those legislative initiatives. In this context, a report published by the American Plastics Council in August of 1994 [21] states that, “Hand removal today is the only demonstrated technology for recovery of plastic parts or assemblies from vehicles”. A year later, our survey of the industry indicates that the same is still true. So although a number of sophisticated automated separation techniques are currently being developed, it is useful to examine current manual disassembly practices and what technologies are being developed to facilitate economical manual disassembly. The advantage of manual separation over many other techniques is that the material recovered is more pure, and thus higher value. The disadvantage is that the cost is also high due to the worker labor cost. As the mechanical separation techniques are improved, the disadvantages of manual recycling will become overwhelming for materials used in small quantities or with low weight. However, the presence of dirt, oil, and other contaminants which are not completely removed by mechanical separation techniques make manual separation a viable, and even preferable, option. In the automotive industry, a large number of metal and plastic parts, from taillight assemblies to fenders, are removed and resold into the used parts market. Plastic parts which are components of larger assemblies (such as doors, front ends, seats, etc.) are typically sold as part of the complete assembly. Other plastics remain in the stripped vehicles, which are stored in outside yards. Mechanics and the general public remove specific parts, as needed, from the vehicles while stored in the yards. In preparation for shredding, dismantlers usually remove tires, exhaust systems including the catalytic converter, batteries, and fuel tanks and recover fluids (anti-freeze, oils, and air conditioner refrigerant) [14]. Visual identification of plastic type for purposes of recycling is possible by labeling of the individual parts. This practice is only partially established in industry. Although (inter)national –7 – labeling standards exists (e.g., SAE J1344 and ISO 1043), there is no uniform enforcement on labeling parts for identification for recycling. In the absence of such labeling, another means of identification of plastic type which we found was infra-red (IR) spectrometry (discussed in more detail later in this paper). This method is applied by the Appliance Recycling Centers of America, Inc., where an employee manually “guns” the parts which are still on the appliance to determine if they are of a type of plastic which is economical to remove and recycle. A major factor which facilitates economic manual removal is the use of fewer varieties of plastic in a single assembly. Large, single-polymer components and assemblies such as dashboards, consoles and bumpers offer better opportunities for economic recycling. European companies have been giving attention to this point for some time. As of 1991, the German Association for Research in Automotive Engineering had commissioned Porsche to investigate a scheme for designing a vehicle that would lend itself to easy dismantling [19]. Also in 1991, BASF was developing a dashboard constructed entirely of polypropylene. At that time it was anticipated that the development process would take some time due to problems related to installation. BASF also found that if the entire bumper system consisted exclusively of a single polymer such as polypropylene, recovery was facilitated and usually economic. BASF has developed (1991) a bumper/grill/spoiler system constructed entirely of polypropylene. Also in 1991, Dutch State Mines (DSM) in Europe was processing bumpers from Volkswagen and Audi cars to produce material which Volkswagen molded into new bumpers [19]. As of 1993, the Porsche 911 had a bumper made from 100% bumper scrap. BMW was using wheel arch and luggage component liners made from recovered polycarbonate/ polyester blends. DSM had designed an allpolypropylene dashboard for easy disassembly and recycling, and was still actively involved with Volkswagen/Audi in recovery of bumper plastics. Door panels in polypropylene can be developed more easily and the technique is already at an advanced stage [19]. [17, 22] provide additional information on European initiatives in plastics recycling. It is difficult to find instances of successful large scale recovery of single-polymer automotive components in the United States. However, a program has just been initiated by GE Plastics and Ford Motor Company in which GE Plastics will buy intact Ford bumpers made of XENOY resin from auto dismantlers. GE Plastics has officially announced that they will buy the bumpers, and now it will be up to the auto dismantlers to take advantage of the infrastructure which has been created. GE will remove the paint from the XENOY resin using a water-based process developed with funding from GE and Ford [23]. Another promising development is the recycling of polyurethane foam recovered from automobile seats. The recycling of polyurethane foam into carpet padding is already an established practice in –8 – the carpet industry, and all that remains to link this infrastructure with the automotive recycling industry is an economical means of removing the seats from the vehicles and separating the foam from the other seat components. Research on manual removal of the foam is underway at the University of Illinois, and wTe Corporation’s pilot recycling facility in Boston is investigating automated separation of the foam from other seat components [24]. An example of a more established plastic recycling process in the automotive industry is the separation of the polypropylene battery case from the battery’s lead is an established practice in the battery lead recovery industry. Reference [25], an English publication, says that the recovery of polypropylene battery cases has been a profitable activity when linked with the associated recovery of lead. The polypropylene is recovered and converted back into battery cases or other items like horticultural containers. Exxon Chemical in the United States and the C2P (Cookson Penarroya Plastics) subsidiary of Metaleurop Group in Europe are both major recyclers of leadacid batteries. Reference [26] describes the battery composition and the recycling and separation process used by C2P. C2P the European leader in the recycling of polypropylene from automotive battery cases produces more than 40 tons of polypropylene chips daily resulting from the crushing of fifty thousand batteries. 5 PLASTIC IDENTIFICATION TECHNOLOGIES The identification of plastics prior to recycling is of crucial importance in order to avoid contamination of plastic batches to be recycled. Standards exist for labeling plastic components (e.g., SAE J1344). These labels and markings are intended to be read by human dismantlers. However, there is a need for more advanced identification technologies because: • Even though plastic parts may be labeled by the generally preferred practice of molded in markings, these markings may be incorrect. For example, a company may change the resin type used for an injection molded component, but may not change the mold used and, hence, the molded in plastic identification will be incorrect for the newer components. • Human labor is expensive and automation of plastic identification is preferred, especially when large scale recycling is sought. In the following, we will discuss some plastic identification technologies that are available in addition to visual markings. –9 – 5.1 FT-IR, FT-NIR, FT-Raman, and X-Ray Because different plastics have distinguishable light absorption spectra, a simple way to sort them out is accomplished by electromagnetic absorption and reflectance measurements. The plastic specimen is illuminated by infrared, YAG laser, or X-ray light and the reflected spectrum is detected and analyzed to determine the type of plastic. This is possible because each type of plastic has its own “fingerprint” in the electromagnetic spectrum [27]. FT-IR stands for Fourier Transform - Infrared. FT-NIR uses Near Infrared light. FT-Raman uses a YAG laser. This means of identifying and separating mixed plastics is the only plastic-from-plastic identification technology we found in wide use in the plastics recycling industry. As mentioned before, Appliance Recycling Centers of America, Inc., makes limited use of IR spectrometry to identify plastic resin type before manual disassembly. A more sophisticated application that is widespread in the plastic bottle recycling industry is in the automated separation of bottles of different resin types, and even different colors, in preparation for recycling. We found no other industry application of this separation technology. The reason given by the companies with whom we spoke was that no one perceives a market for any other recycled plastics. FT-IR, FT-NIR, FT-Raman, and X-Ray identification are means of identifying polymer type, after which some action must be taken to actually separate the different types. Current industry separation practice is either to eject the discovered plastic type via air jet or to route the detected plastic via an actuated gate in the material flow path. Though the theory of operation of each of these identification methods is similar, the capabilities of each vary. Some of the differences are shown in Table 1. [30] is a June, 1993 report on the operation of an installed identification/separation system by Magnetic Separation Systems (Nashville, TN) at Eaglebrook Plastics, Inc. This system, designed for recycling of plastic bottles and containers, began operation in January of 1992. The system uses FT-NIR and X-ray sensing, and is capable separation into the following categories: • PVC - colored: up to seven different color classifications • PET - clear • PET - colored: up to seven different color classifications • HDPE - natural • HDPE - colored: up to seven different color classifications • PP Overall accuracy of the system under production conditions was found to be 85% to 95%, except for PVC, which was detected (via X-ray) with an accuracy of 99.3 to 99.5%. Sources of – 10 – inaccuracy are detailed in [30]. [30] also acknowledges APC and Exxon Chemical Company for received funding. In August of 1994, [21] recommended to the APC that funding be given to support Magnetic Separation Systems (MSS) in the further development of this system. APC contracted with MSS to construct a bottle separation system in late 1994. [31], a more recent (November, 1994) report from MSS, contains detailed descriptions of a number of domestic and overseas systems designed and installed by MSS. All are centered around the recycling of plastic bottles. Specific volume and efficiency figures are given, but are not included in this report as they are similar to the figures for the Eaglebrook installation. According to [30], other companies involved in this technology are: • Automation Industrial Control • National Recovery Technologies • Buhler AG (Uzwil, Switzerland) Table 1 - Distinctions Between Different Spectrographic Identification Methods FT-IR Reference [27] indicates that FT-IR has greater discriminative power than FT-NIR and Xray techniques, and can discriminate between “a diversity of engineering plastics”. [27] discusses the principles of FT-IR in great detail. FT-IR is very sensitive to the condition of the surface being identified [28]. Because most consumer plastics carry different types of commercial labeling, it is often not possible to obtain any surface IR spectral measurement reliably [29]. Problems may arise with stickers, lacquers, contaminations, etc. on the surface of the plastic products. The IR spectra have to be recorded from “clean” surfaces [27]. FT-IR has difficulty identifying very thin plastic such as for plastic bags, and cannot identify blown polystyrene (PS). FT-NIR Unlike FT-IR, the FT-NIR reflection technique cannot identify black materials [27] [30] goes into some detail on the identification process using FT-NIR. FT-Raman FT-Raman has no difficulty identifying very thin plastic such as plastic bags. FT-Raman is able to identify rough surfaces and powders, can accommodate almost any shape, color, and surface condition, and is at least 50 times faster than FT-IR. However, FT-Raman cannot identify black or darkly-colored surfaces [28]. We have found no use of FT-Raman in industry, and the only research we found was being conducted in France as of April 1994. X-Ray The use of X-ray techniques is restrict to specific problems, like the separation of PVC and PET (plastic bottles) [27]. [30] goes into some detail on the identification process using X-ray. [31] also says that sensing units based on FT-NIR were introduced by the following companies: – 11 – • Buhler AG (Uzwil, Switzerland), developed by Optan (Switzerland) - 1993 • Laser Labor Adelshof GmbH (Berlin, Germany) - 1994 • Massen Machine Vision Systems GmbH (Konstanz, Germany) - 1994 [31] says that processing lines using the Laser and Massen sensors respectively are being offered by Mashcinenfabrik Bezner GmbH based in Ravensburg, Germany and Binder & Company AG in Gleisdorf, Austria. According to Joe Taylor of Carpco Inc., Simco-Ramic and Buhler AG were developing optical and NIR systems. [32] indicates that research is underway (June 1994) at Rutgers University in New Brunswick, NJ, as well as in Europe, on detection-and-route systems based on electromagnetic spectra. Bruker Instruments, in conjunction with the APC, recently developed an infrared identification instrument that can distinguish between 23 different types of plastic, including black plastics. As of August, 1995, this device was scheduled to be evaluated at the Vehicle Recycling Development Center in Highland Park, MI, which is managed by the Vehicle Recycling Partnership (VRP). Perhaps the most interesting information in [31] is the development of new sensor technology for separation on the flake level. Separation of granulated plastic is now operating on a commercial basis. Simco-Ramic of Medford, Oregon has installed several systems capable of separating colored HDPE from natural HDPE, green PET from clear PET and PP and mixed color HDPE. Flake sorter volumes of up to 6,000 pounds per hour are available. One such system is in use at Productivity Corporation (Richmond, Indiana) sorting PET and PP flakes by color. The quality of these systems is reported as “quite good”. MSS also offers an automated system for the separation of PVC flakes from mixed plastics flake streams. Flakes down to 3/16” are removed with typical removal efficiencies of greater than 98% and a throughput of up to 4,000 lb/hr. [31] indicates that there are 23 multi-resin processing lines operating world wide, 20 of which were provided by MSS. Of the non-MSS lines, one is a prototype system installed by NRT and Sorema in Italy, and two lines are provided by Govoni, one in Japan and one in France. 5.2 Photoacoustics As with FT-IR and similar techniques, photoacoustics is only a means of identification after which some action must be taken to separate the material. In 1994, researchers in the Department of Chemistry at Queen’s University in Kingston, Ontario conducted a small-scale study to demonstrate the application of photoacoustics to on-line sorting of waste plastics. This material identification process is generally similar to the use of IR in that the sample is exposed to a light of known frequency and a reaction of the material is observed. The differences are that the green – 12 – light of a Nd:YAG laser is used and that it is an acoustic emittance, not a light reflectance/absorbance, that is measured. The advantage is that the identification of the material is not limited by surface modifications such as color, printed labels, etc. Other incidental advantages over IR include lower cost and portability. The plastics tested in the study were HDPE #2, HDPE #7, and PP #5. As of 1994, this process was still very much in the research stage [29]. 6 MECHANICAL PLASTIC SEPARATION TECHNOLOGIES Mechanical separation has a relatively lower cost than manual separation. Mechanical separation, however, requires significant differences in easily measurable properties of the materials. For instance, ferrous metals are very easy to separate from other materials with a simple magnet. Non-ferrous metals can be separated with an eddy current separator with somewhat less accuracy. In this section, we will highlight a number of separation technologies that are under development and show promise. It should be emphasized that most are in a prototypical stage and are not commercially available yet for plastic recycling. 6.1 Float-Sink Method Using Supercritical Fluids This plastic-from-plastic separation technique was developed in the Department of Chemical Engineering, University of Pittsburgh, PA. Reference [33] is the original proposal to begin the research, and discusses theory in detail. Reference [34] is the first report on the findings of the research. This method involves placing the mixed waste to be separated into a sealed pressure vessel with CO2 or a mixture of CO2 and SF6. The pressure inside the vessel is varied so as to vary the density of the fluid over the range of the mixed waste ingredients. This control over the fluid density gives the operator the ability to float different materials in stages, removing the floating material before proceeding to the next density. Density can be closely controlled, allowing the process to closely discriminate between types of plastics. Additional details of this process are contained in [34]. Several thermoplastic mixtures have been tested, including HDPE/LDPE/PP and PVC/PET. The purity of the separated homopolymers ranged from 77% to 100% by weight, with most runs yielding 96%-100% purity [34]. As of 1993, this process was still very much in the research stage – 13 – [34]. In August of 1994, [21] recommended that funding be given to support the continuation of this research. That is the most recent information we have found. 6.2 Float-Sink Using Other Fluids According to Joe Taylor of Carpco, Inc., float-sink with brine solutions is established practice in wire industry. [31] indicates that Rensselaer Polytechnic Institute recently installed a float-sink system for separation of granulated PVC from PET. wTe Corporation’s Multi-Products Recycling Facility uses float-sink classifiers as one of its many stages of separation. wTe was reluctant to release any details to us due to funding received from the APC [20]. 6.3 Air Classification Conventional air classification uses a steady, rising current of air to separate lighter particles from heavier ones. An example of such a process is found in the food industry in the separation of wheat from chaff in a grainery [32]. However, the separation is affected by both density and particle size. Thus a less dense, larger particle can be mistaken to be equivalent to a smaller, more dense one [34]. Clear separation can never be achieved by steady airflow because separation occurs by aerodynamic lightness, not density [32] .. Thus, although air classification has been shown to effectively remove the polyurethane foam component of ASR [35], discrimination between plastics with similar densities, such as PET and PVC, cannot be achieved at all [34]. Stessel is developing an air classifier that uses pulsed airflow, as opposed to continuous airflow, to overcome the above-mentioned disadvantage [32]. It is recommended as an inexpensive preliminary step to more sophisticated and costly separation technologies. Separation of plastics from other materials and perhaps even separation into different plastic types is expected. This method has received only limited testing due to lack of funding. The APC and MBA Polymers, Inc. have opened a new recycling facility in Berkeley, CA, which focuses on identification and development of new mechanical recycling technologies. The facility is said to incorporate some of the most advanced plastics recycling technologies in the U.S. Among the many separation processes employed at the facility is a three-stage air classification system [20]. MBA was reluctant to release details on its operations for proprietary reasons. Air classification has the advantage over hydrocycloning of being a dry operation [32]. – 14 – 6.4 Hydrocycloning Hydrocycloning is similar to air classification, except that the fluid medium is a liquid, not a gas. Hydrocylconing is also plagued by the same shortcomings as air classifiers [34]. Although several hydrocylone manufacturers may be found in the Thomas Register [36], we have found only one confirmed application of hydrocyclones in the recycling industry; the new recycling facility opened by the APC and MBA Polymers, Inc. discussed under air classification. It is said to be much faster than float-sink methods [20]. 6.5 Electrostatic Separation This plastic-from-metal separation technology is discussed in the May 1994 issue of Wire Industry [37] in the context of recycling cable scrap. First, the cable is finely shredded to free the copper from the insulation. Then the shredder output is fed onto the top of a horizontal, rotating drum in the presence of a high electrostatic field which charges the particles. As the drum revolves, the particles are brought out of the electrostatic field and begin to lose their charge to the grounded drum. The copper, being a metal, loses its charge first and is flung quickly off the barrel due to the barrel’s rotation. The plastic insulation loses its charge more slowly, and clings to the barrel a little longer before it too is flung outward. In this way the copper and insulation are thrown in different directions and collected in separate containers. This technique has proven to be highly effective in this context. This process is in use by Hamos Elektronik, Ruhe am Bach 5, D-82377 Penzberg, Germany [37]. In August of 1994, [21] recommended that funding be given to support research by Kali and Salz of BASF. Carpco, Inc., located in Jacksonville, Florida, is a manufacturer of a great variety of separation devices for a great variety of applications. They are currently manufacturing electrostatic separators for cable recycling and fiber removal, and indicated that they had plastic-from-plastic separation technology under development that would be ready for sale towards the beginning of 1996. 6.6 Magnetic Separation Magnetic separation is currently used in industry to separate both ferrous and non-ferrous metals from the light fraction of ASR, as well as in many other industrial applications. Ferrous metals may be separated via a simple magnet mounted over a moving conveyor belt. Non-ferrous metals are separated by rapidly spinning magnetic pulleys in close proximity to the metal particles, which – 15 – induce eddy currents in the metals which can physically move the particles. separation is often referred to as “eddy current separation”. This type of According to the Thomas Register an extensive number of manufacturers are involved in magnetic separation. Because of this, and because the emphasis of this report is plastic-plastic separation, we have neither tried to locate current research nor included a listing of relevant manufacturers. 6.7 Paint/Coating Removal The removal of paint and other surface coatings from the plastic resins is one of the larger obstacles to overcome in the development of automotive plastics recycling. Two companies which have developed processes which appear to be economically viable are GE Plastics [23] and MBA Polymers, Inc. [20]. GE Plastics plans to use their process in the XENOY bumper recovery program in conjunction with Ford Company. MBA Polymers will use their process in their new plastics recycling pilot plant constructed in conjunction with the APC. Though we know that both process are “water-based”, we have been unable to obtain substantial amounts due to the proprietary nature of the technology. 6.8 Selective Solvent Extraction Argonne National Laboratory published a paper in 1991 summarizing the results of an endeavor to extract and separate plastics from ASR. The ASR was first sifted through a screen and then the plastics-rich stream was treated using acetone, xylene, and ethylene dichloride to obtain good recovery of an ABS/PVC blend and separate PP. Since 1991, a larger-scale testing of the process was undertaken [35]. According to Sam Jody of ANL, the process was successful with separating Polyethylene, Polypropylene, ABS and PVC. Due to market conditions, the recovery of ABS was emphasized. Results have been successful with 98% pure ABS being produced with less than 1% PVC contamination. [38] and [39] give detailed descriptions of the selective solvent extraction process developed at Argonne. [39] also indicates that the process is not only technically feasible using commercially available equipment and material, but is also potentially economical. In August of 1994, [21] recommended that funding be given to support research on solvent extraction at the Rensselaer Polytechnic Institute in Troy, New York. 6.9 Melt Temperatures [32] indicates that, as of June 1994, research was under way at the University of Tennessee in Knoxville on a separation technology using melt temperatures. – 16 – 6.10 Dielectric Characteristics [32] indicates that, as of June 1994, research was under way at Gannon University in Erie, PA on a separation technology using dielectric characteristics. 6.11 Separation in an Oxygen-free, Vacuum Oven This plastic-from-metal separation process had no formal name and was found in only one source, Wire Industry, where it was cited as being used in the recycling of cable scrap. The cable scrap is taken directly from the production line and placed in the self-contained separation device. The device is sealed, nitrogen is used to drive any oxygen from the system, and a vacuum is applied. The device takes over, heating its contents, and at the end of the run the copper and plastic are completely separated and in separate containers. Both he plastic and copper are immediately suitable for mixing with the virgin material at the head of the production line [40]. This process is in use by Swisscab in Yvonand, Switzerland. 7 CHEMICAL RECYCLING PROCESSES In addition to mechanical separation and recycling processes there exists a large body of chemical recycling processes that can be applied. In the following we will outline some important technologies and their current state of application in the recycling industry. 7.1 Pyrolysis Pyrolysis is a chemical process which is currently being developed by a number of U.S. and European companies. In pyrolysis, mixed plastics can be decomposed into energy sources or monomers by ultrahigh temperature in the absence of oxygen [41]. This eliminates the need for separation of the plastics in the recycling process. In [19], it is stated that pyrolysis can reduce ASR to combustible gas, carbon black, and aromatic oils for petrochemical use. At that time, pyrolysis had been used to recover poleofins from scrapped cars but the process was then uneconomic because of the relatively low price of petroleum. According to [19] it is anticipated that if the price of crude oil were to rise by a factor of three, the process could be developed to provide a successful means of material recovery. – 17 – The January 1994 issue of Modern Plastics indicates that, as of January 1994, five European resin makers, Petrofina, DSM, Elf Atochem, Enichem, and BP, were pooling resources to commercialize a BP pyrolysis process [41]. [41] also says that, as of January 1994, the APC was funding several pyrolysis efforts. A project by Conrad Industries (Chehalis, WA) that converts comingled plastics into fuels. Early in 1994, Conrad was to have started operation of a 2000-lb/hr continuous pyrolysis unit that converts plastics into hydrocarbons. General Motors owns technology that converts ASR into energy and filler. The ASR is pyrolyzed at 1400 degrees Fahrenheit, converting organics into a carbon-rich stream of gases or liquids. Kadar Agarwal, sr. Project engineer at GM who holds patents on the process, says it has a higher energy value (15,000-18,000 BTU/lb) than No. 2 heating oil (13,000 BTU/lb). Inorganics undergo an added step that renders heavy metals inert for reuse in steel reinforcing rods. [41] said that some auto-shredder firms in Canada and the U.S. were considering using this technology, however, we did not encounter any such process in use in industry. 7.2 Glycolysis Glycolysis is a process that breaks down PET into short-chain oligomers. Ashland Chemical Company has developed a chemical process for the recycling of thermoset polyester composites. The composite is broken down into raw materials using heated glycols (glycolysis), and the resulting polyols have been used successfully in automotive sheet molding composite applications on a laboratory scale [23]. 7.3 Hydrolysis Polyurethanes, polyesters and polyamides can be treated by hydrolysis. Hydrolysis is similar to pyrolysis, with the plastics being disassociated at high temperatures in the presence of water [19]. We did not encounter either research on, or industry use of, hydrolysis for recycling purposes. 7.4 Methanolysis Polyesters can be treated by methanolysis. Methanolyisis is similar to pyrolysis and hyrdrolysis, with the plastic being disassociated at high temperature and pressure in the persence of methanol. The polymer is broken down into individual monomers and can remove all colorants and impurities. According to [42], Hoechst Celanese was using methanolysis to process post– 18 – consumer PET flakes and was completing (winter 1992) completion of an ultra-modern recycling complex at its Spartanburg, South Carolina plant. 7.5 Waste-to-Energy Conversion Waste-to-energy conversion varies from pyrolysis and hydrolysis in that the process simply uses the mixed plastics as fuel for combustion. This combustion generates heat which can be used to power both the combustion process itself and external devices such as steam turbines. Processes of this type appear to be more common outside the U.S. because of environmental issues. Because of this, it was difficult to obtain details of the many varieties of combustion systems. The only manufacturer located in the U.S. was Vortec Corporation, which is proposing to use its system in the recycling of automobile shredder residue (ASR). The solid byproduct of this system is a glass which can be used in the production of asphalt, brick, and mineral wool. [43] also discusses recent advances in energy recovery. 8 NON-SEPARABLE PLASTICS Even with all the preceding technologies available, there may still be components made out of thermo-plastic and thermo-set laminates that cannot be separated. The two main uses of such mixed plastics are energy recovery via combustion processes such as pyrolysis, and plastic lumber/concrete filler materials used in construction. One company involved in plastic lumber is Urban Resource Technologies in Canada. They are able to create a variety of products by varying the concentrations of plastics, paper, cardboard, and wood by-products which are ground, mixed, melted, and shaped in a “floating mold”. Another company involved in plastic lumber is Eaglebrook Products Inc. of Chicago IL. Eaglebrook has an integrated sortation, purification and extrusion capability which has been successful with post consumer HDPE that has been cleaned of contaminants. Though we know of the existence of concrete filler technologies in industry (see [34], [44]), we have been unable to locate specific companies involved in these technologies. In [20], it is indicated that the Department of Civil and Environmental Engineering at Michigan State University has done research on the practicality and environmental impact of using ASR as concrete filler. It is also known to us that thermo-set composite suppliers, like Premix, Inc. who is a Sheet Molding Compound (SMC) manufacturer, are actively pursuing ways to recycle/reuse their products. Chemical recycling processes are mostly favored for thermo-sets. [44-46] – 19 – describe some options for SMC scrap recycling. It should be noted that reuse of plastics as filler for construction material is often a downgrading of the material, especially for thermo-plastics. 9 SUMMARY AND CLOSURE In this paper, we discussed a number of (future) technologies which may provide not only technically feasible, but also economically feasible options to separate, identify, and process plastic-metal and plastic-plastic automotive materials. It should be clear that a great variety of technologies are being developed. In order to summarize some of our findings, we have given a summary of companies, organizations and institutions that we have come accross who are actively working on applicable recycling technologies in Table 2. In Table 2, we have also indicated, to the best of our knowledge, the technological focus of each company, organization and institution, as well as the level of maturity of their technology ranging from laboratory, to pilot and commercial scale. Despite all these efforts and technologies, the only established commercial usage of those technologies in the automotive recycling industry is of manual disassembly and of plastic-from-metal separation via magnetic separators. At this stage, automated plastic-fromplastic separation technologies, though under development, are not used commercially in automobile recycling. However, given the increased interest from the automotive manufacturers in light of European take back legislation, we may see a move towards a greater commercialization and usage of these technologies in the next five to ten years. It should be pointed out that electronic and white good manufacturers who may also be subject of similar take back legislation are also pursuing many of the same technologies. Table 2 - Summary of Applicable Recycling Technologies and Associated Parties Company / Organization / Institution Name Technology BASF Hoechst Celanese Corp Fibers and Film Bayer (Miles Inc Polymers Div. is US Subsidiary) Huls (Huls America Inc.) BASF GE Plastics American Plastics Council Ashland Chemical Company (General Polymers Div.) Phoenix Fiberglass Owens-Corning (Composites Div) Dupont Automotive Appliance Recycling Centers of America, Inc. Porsche BASF Dutch State Mines Porsche BMW Recycling of Automotive Plastics Recycling of Automotive Plastics Recycling of Automotive Plastics Laboratory / Pilot / Commercial Scale Laboratory Laboratory Laboratory Recycling of Automotive Plastics Composite Separation Recycling of Automotive Plastics Many different technologies Composite Separation Laboratory Laboratory Laboratory Composite Separation Composite Separation Nylon Carpet Recycling Electromagnetic Spectrum Identification Manual Disassembly Manual Disassembly Recycling of Automotive Plastics Recycling of Automotive Plastics Recycling of Automotive Plastics Laboratory Laboratory Pilot Commercial Laboratory Laboratory Commercial Commercial Commercial – 20 – Laboratory Dutch State Mines Vehicle Recycling Partnership GE Plastics GE Plastics Urban Resource Technologies Dept. of Civil and Environmental Engineering at Michigan State Uni. Petrofina (FINA Inc) Dutch State Mines Elf Atochem North America Inc. Enichem Elastomers America Inc. BP Conrad Industries General Motors Energy and Environmental Research Center Magnetic Separation Systems Eaglebrook Plastics, Inc. Automation Industrial Control National Recovery Technologies (National Recovery Systems Inc.) Buhler Laser Labor Adelshof GmbH Massen Machine Vision Systems GmbH Maschinenfabrik Bezner GmbH Binder & Company AG Simco-Ramic Rutgers University Bruker Instruments Dept,. of Chemistry at Queen's University Dept. of Chemical Engineering at University of Pittsburg Rennselaer Polytechnic Institute wTe Corporation Dept. of Civil Engineering and Mechanics at the University of Florida MBA Polymers, Inc. MBA Polymers, Inc. MBA Polymers, Inc. Argonne National Laboratory Argonne National Laboratory Rennselaer Polytechnic Institute University of Tennessee Gannon University Swisscab Hamos Elektronik BASF Carpco, Inc. Custom Cryogenic Grinding Corporation VKE Polymer Products Vortec Corporation University of Illinois Automobile Dismantlers and Recyclers Association STIBA C2P Cookson Penarroya Plastics a Div of Metaleurop Group Manual Disassembly Manual Disassembly Recycling of Automotive Plastics Paint/Coating Removal Plastic Lumber Concrete Filler Laboratory Pilot Commercial Commercial Commercial Laboratory Pyrolysis Pyrolysis Pyrolysis Pyrolysis Pyrolysis Pyrolysis Pyrolysis Pyrolysis Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Commercial Commercial Commercial Commercial Commercial Pilot Laboratory Pilot Commercial Commercial Commercial Commercial Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Electromagnetic Spectrum Identification Photoacoustics Float-Sink Commercial Commercial Commercial Commercial Commercial Commercial Laboratory Pilot Laboratory Laboratory Float-Sink Float-Sink Air Classification Laboratory Pilot Laboratory Air Classification Hydrocycloning Paint/Coating Removal Float-Sink Solvent Extraction Selective Solvent Extraction Melt Temperatures Dielectric Characteristics Oxygen-free Vacuum Oven Electrostatic Separation Electrostatic Separation Electrostatic Separation Cryogenic Grinding Pyrolysis Plastic Lumber Waste-to-Energy Conversion Manual Disassembly Manual Disassembly Pilot Pilot Pilot Laboratory Pilot Laboratory Laboratory Laboratory Commercial Commercial Laboratory Commercial Commercial Pilot Commercial Commercial Laboratory Commercial Manual Disassembly Lead-Acid Battery Recycling Commercial Commercial – 21 – ACKNOWLEDGEMENTS This paper is based on a report commissioned by the Chrysler Corporation and compiled in September 1995 by Joerg Hendrix, Kevin A. 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