Team:Imperial College/Industrial Implementation
From 2013.igem.org
Products
Recycling mixed plastic waste will utilise two processes in two joint bioreactors to produce:
Biopolymer poly 3-hydroxybutyrate (P3HB) , resynthesised in the second batch from post-consumer P3HB bioplastic products. Ethylene glycol, produced in the first batch by digesting polyurethane (PUR) and polyethylene terephthalate (PET).
Product description
P3HB is degraded by specialised microorganisms without releasing of toxic products or intermediates. Meanwhile, P3HB has a low water solubility [1] and medium-low water and CO2 permeability [2], as well as very good barrier properties, enabling application in packaging. This biopolymer also has a high degree of crystallinity, high melting temperature [3], and good tensile strength, making it comparable to one of the most common petroplastic isotactic polypropylene [3]. In addition, there are many processing methods for P3HB [4], such as injection molding and extrusion, which are required in manufacture of most plastic products. Although the impact strength is relatively weaker compared to petroplastics, P3HB nanocomposites have shown significantly improved impact strength as well as other properties [3].
Ethylene glycol is a valuable by-product obtained in the process of recycling PUR and PET. Due to the high affinity for water, ethylene glycol has been commercialised for a wide range of uses including desiccant and vaccine manufacture.
Technology
Two bioreactors will be used for dedicated plastic degradation and synthesis respectively. Same plasmid will be used for all the genes, so that one type of antibiotic is used to eliminate undesirable microbes. The detailed design of the technology can be found here (link to modules).
Sourcing
Every year, about 320,000 tonnes solid recovered fuel (SRF) is produced per recycling site in the UK, from where SRF is shipped to other countries for incineration. SRF is a cost to these recycling companies as they pay approximately £65 per tonne for shipping. SRF contains at least 30% plastic. Therefore, we plan to use SRF from the recycling companies as the feedstock, and charge them less than incineration sites.
Market analysis
Market for bioplastics
Plastics represent a large percentage of materials used, as they can be applied in products ranging from water bottles and EE (electrical and electronic) equipments to agricultural mulch film and textiles.
At the present, bioplastics are approximately twice the price of petroplastics, limiting large-scale implement of bioplastics. Although bioplastics count only a small percentage of the total plastics currently, the market for bioplastics is predicted to grow 30% per year [3], and market share is predicted to approach 25%-30% by 2020 [5]. This fast growth rate predominantly come from the increasing price of petroleum and consumer pressure of using greener products.
Competitive comparison
There are existing P3HB producing companies that utilise genetically modified plants or microbes to produce P3HB. However, the technologies they developed cost higher than our technology, as shown in the graph. Plant-based technology cost estimation is based on switchgrass, which shows the highest P3HB production efficiency (3.7% of total dry mass) compared to other plants [6]. Apart from the cost, many other problems are potentially associated with existing technologies. For instance, plant-based technologies require a large growth area, plants have slow growth rate compared to bacteria, and current microbe-based methods demands glucose produced from corn as the feedstock.
References