J.-F. Borny and S. CHAKRABORTY, Lummus Technology, Houston, Texas
Today, the world produces twice as much plastic waste as it did two decades ago, with the majority ending up in landfills, being incinerated or leaking into the environment. According to a report by the Organization for Economic Cooperation and Development (OECD), only 9% of this plastic is successfully recycled, and 22% of plastic waste is mismanaged.1
The report states that nearly half of all plastic waste is generated by the 37 countries that comprise the OECD. Plastic waste generated annually per capita varies from 221 kg in the U.S., to 114 kg in European OECD countries to 69 kg in Japan and Korea. Most plastic pollution comes from inadequate collection and the disposal of larger plastic debris known as macro plastics. Leakage of microplastics smaller than 5 mm in diameter from industrial plastic pellets, synthetic textiles, road markings and tire wear are a growing cause for concern.
Virgin—or primary—plastics made from crude oil or gas comprise most of today’s plastics production. While global production from recycled—or secondary—plastics has more than quadrupled from 6.8 MMt in 2000 to 29.1 MMt in 2019, this still represents only 6% of total global plastics production. Additional development is required to create a separate and sustainable market for recycled plastics, which are still considered substitutes for virgin plastic. Setting recycled content targets and investing in improved recycling technologies could help make secondary markets more competitive and profitable.
Mechanical and chemical recycling methods have gained considerable attention in recent years in the pursuit of reducing waste plastic generation, addressing serious environmental issues caused by plastic waste mismanagement and reducing the use of fossil fuels to produce fresh plastic. While mechanical recycling is still the main recycling method, chemical recycling is expected to become a significant means to achieve recycled plastic content targets by 2030.
This article reviews the chemical recycling method of pyrolysis to convert waste plastics into useful pyrolysis oil, a valuable feedstock for producing new plastics with a lower carbon footprint. The article also reviews the authors’ company’s development of a new analysis methodology to completely characterize the composition of waste process pyrolysis oil and harness its full potential as a plastic feedstock.
Pyrolysis pathways and stages. Pyrolysis is the primary reaction pathway for chemically recycling mixed plastic waste by converting it into valuable pyrolysis oil and gas. A thermal degradation process, pyrolysis heats the waste plastic in the absence of oxygen to break down the long polymer chains and, through a series of complex chemical reactions, recombine the smaller hydrocarbons into various products, including waste process pyrolysis oil (WPPO).
The process typically involves three stages:
WPPO possesses several properties that make it an attractive alternative to conventional fossil fuels:
While WPPO holds significant promise, several challenges must be addressed:
Analytical innovations unlock pyrolysis oil’s potential. The authors’ company is actively working to address these challenges through ongoing technology innovations. For example, the company set up a partnershipa to develop an advanced pyrolysis process that utilizes the principle of thermal conversion to continuously produce pyrolysis oil and gas from a mixed plastic stream comprising PP, high- and low-density polyethylene (HDPE/LDPE), and some polystyrene.
Simultaneously, the authors’ company is working with industry partners to develop a comprehensive framework for characterizing, testing and applying pyrolysis oil—a framework that promises vital insights to researchers, industry professionals and policymakers seeking to harness the full potential of this fuel.
One of the greatest challenges in analyzing pyrolysis oil is determining its detailed chemical composition to differentiate the carbon number and hydrocarbon classes of all the compounds present. The current technology uses a well-established methodology that relies on the natural composition of crude oil and its derivatives. Nature provides familiar patterns from similar sources. Regardless of whether a crude sample was sourced from Nigeria or Saudi Arabia, it will contain similar analytical patterns that serve as a reference when analyzing naturally occurring fuels derived from that crude.
Such patterns do not exist in WPPO analysis since the oil is synthetically produced from polymer chains. Therefore, a new analysis methodology is required to characterize a pyrolysis oil’s chemical composition, physical properties, stability and impurities. A standardized characterization technique will enable effective quality control and facilitate comparisons across various sources and production processes.
The authors’ company has worked with gas chromatography–vacuum ultraviolet (GC-VUV) spectroscopy detector developers to reliably analyze complex pyrolysis oil and determine the carbon numbers and the classes of the compounds. Classic GC flame ionization detection depends on the elution order and a reference pattern to extrapolate the composition of the pyrolysis oil. However, the lack of pattern in WPPO makes it impossible for current analysis methods to correctly determine the proper compound classes. This results in such erroneous outcomes as aromatics being mistaken for olefins and paraffins being misidentified.
VUV renders an additional layer of assessment by providing a spectral analysis of each component as it eludes the gas chromatogram. TABLE 1 compares a typical WPPO between detailed hydrocarbon analysis (DHA) and vacuum ultraviolet hydrocarbon analysis (VHA). VHA is a modern approach to DHA that uses VUV spectroscopy and spectral validation to deconvolve and identify critical components accurately and without human intervention, and in a fraction of the time of traditional DHA.
The difference between the results is significant. GC-VUV offers a simplified, affordable analytical tool that can analyze normal paraffins, isoparaffins, aromatics, naphthenes and olefins with greater accuracy.
Early results prove promising. VUV analysis was performed on multiple light pyrolysis oil fraction samples (at 750°F) generated from a commercial plant processing HDPE/LDPE/PP (both rigid and film) (FIGS. 1–5). The following are characteristics of typical pyrolysis oil:
By providing a more detailed understanding of the nature of the pyrolysis oil, VUV helps estimate the possible yield structure from a steam cracker, downstream hydroprocessing or fluid catalytic cracking (FCC) type units.
The authors’ company is also working with the ASTM D02.P Recycle Product subcommittee to develop an industry standard guide for the basic analytical needs for WPPO. By establishing a common ground for the development of WPPO, the guide will help the industry further enhance WPPO’s composition and how it can be best used in different industries. The mutual benefit will be building on the strength of WPPO toward more environmentally friendly solutions.
TABLE 2 presents some of the basic analytical methodologies that will be covered in the ASTM guide to WPPO.
Takeaway. As the world seeks sustainable alternatives to traditional energy sources, WPPO stands out as a remarkably innovative technology that offers a way to alleviate the burden of plastic waste and produce a versatile energy source with reduced emissions. By harnessing the potential of this oil, societies can simultaneously address the plastic waste crisis and move toward a more sustainable and circular economy. The first step is accurate and thorough analyses of the WPPO. This will convert to more reliable process technology and improved advancements in analytical techniques for WPPO. HP
NOTE
a Lummus Technology and New Hope Energy
LITERATURE CITED
Jean-François Borny is the Analytical Services Manager for Lummus Technology. In his present role, Borny leads lab services for Lummus Technology, managing facility setup, personnel training and support programs for Lummus’ process technologies. He has more than 35 yr of experience in the analytical chemistry field, working for refining and petrochemical companies, instrument manufacturers, commercial labs and pharmaceutical companies. Borny serves as the scientific chair for the GCC Technical Committee, the ASTM D02.P and the ASTM D02.93.2. He earned degrees in chemistry and computer science from Texas A&M University.
Sudipto Chakraborty is the Technology Manager, Advanced Plastic Pyrolysis Technology for Lummus Technology’s Green Circle business. Chakraborty leads technology development at Green Circle, a Lummus Technology business, directing R&D and engineering teams to develop and commercialize circular economy initiatives, with a focus on converting waste plastic mix to fresh plastic raw material using chemical recycling routes. He has more than 20 yr of experience in the refining industry, specifically with hydroprocessing units and HPC catalyst design. Chakraborty earned a B.E degree in chemical engineering with gold medalist honors from Jadavpur University, India.