MBA Polymers

Last updated

MBA Polymers
Founded1994;30 years ago (1994) in the United States
FounderTrip Allen and Michael Biddle
Headquarters,
USA
ServicesRecycling
Website www.mbapolymers.com

MBA Polymers is a recycling company [1] with operations globally that recovers plastics from waste electrical and electronic equipment (WEEE) and auto-shredder residue from end-of-life automobiles (ELV). [2]

Contents

Company history

MBA Polymers was founded in 1994 [3] in California [4] [5] by Laurence "Trip" Allen III [6] [7] and Mike Biddle. [8] [9] Allen and Biddle were coworkers at Dow Chemical in Walnut Creek, CA where Allen developed a novel approach to recycling packaging plastics. The pair left Dow in 1992 and initially wanted to prove that it was possible to recycle plastics from complex packaging waste streams but they ultimately focused on durable goods recovery. [10] The company now specializes in recycling durable goods from waste streams such as waste electrical and electronic equipment and auto-shredder residue. [1] [11] MBA Polymers raised money to develop its technology for extracting and recycling plastic from many stakeholders. [12] [13] In 2017 Elephant Equity, a private equity investor based in Munich with focus on cleantech activities, has taken over 100% of the shares. [14]

Development of the recycling process

The key innovation of the MBA Polymers approach was that a mixed waste plastic stream could be sorted into usable pure plastic varieties. Recovery of durable plastic products in earlier processes required that each type of plastic part be identified and sorted by hand into separate batches. The sorted parts were ground and could then be pelletized for reuse but it was costly and difficult to acquire enough of any given type of plastic to justify the expense. Once a mixture of durable goods such as refrigerators are ground into chips, the metal may be removed by magnets and other magnetic-based separators such as eddy-current sorters. This leaves a mixture of perhaps dozens of different polymers. The American Plastics Council guided by Director of Technology, Dr. Michael Fisher [15] funded MBA Polymers Advanced Technology Plastic Recycling Pilot Line In 1994 to exploit a novel approach to density sorting with hydrocyclones among other processes. [16] In the mid-1990s the key challenge to durable plastic recycling was separation of impact resistant polystyrene, often called HIPS for High Impact Polystyrene from Acrylonitrile Butadiene Styrene (ABS). These two plastics types were commonly used and have overlapping densities that make density sortation alone insufficient. The two plastics are incompatible and so a mixture of the two is not generally valuable. A kitchen experiment Allen performed in 1994 revealed a mechanism for separating a mixture of HIPS and ABS that relied on the fact that ABS absorbs more water than HIPS. When heated slightly a mixture of the two plastic will soften and the ABS will swell which reduces its apparent density. The mixture can then be sorted by a simple sink/float separation in water. This discovery lead to an important patent [17] and an Advanced Technology Program Grant award [18] from the National Institute of Standards and Technology worth $687,000 to help MBA develop the process. The technique remains the only reliable process to separate two different varieties of the same plastic such a two commercial grades of ABS with different melt flow properties. The separation process used by MBA Polymers eventually matured to include a sophisticated collection of integrated processes which was robust and very reliable. [19] Based on the promise of this process equity investment was raised to spread the technology to Europe and Asia.

WEEE and ELV arrives at MBA Polymers’ recycling facilities shredded, often from other recyclers that do not handle plastic. [20] With complex in-house developed patented processes the input material is separated and processed to high-quality plastics. Compared to the production of virgin plastics, one metric ton of plastic generated by the process invented by MBA Polymers saves 4.8 metric tons of CO2. [21] MBA works with manufacturers around the world to replace virgin plastics with MBA plastics in their new products. [2] Customers of the company are inter alia AEG, Ford, HP and Canon. [21]

Global operations

Having opened its first pilot-recycling facility in 1994, [22] MBA Polymers also has built recycling plants in the UK, China, Austria and Germany [1] [23] [24] [25]

In 2004 MBA Polymers created a joint venture with Guangzhou Iron and Steel Enterprises Holdings Ltd to establish its sustainable recycling operations in China. [26] MBA Polymers' operations in China now employ over 160 people. The company has invested $15 million in the recycling plant. [26]

The company expanded its operations to Austria in 2006 with a joint venture with the Müller-Guttenbrunn Group (MGG). [27] The plant in Austria has a recycling capacity of over 50,000 metric tons per year.

In 2010 the company expanded to Worksop, United Kingdom, in a joint venture with the largest metal recycler in the British Isles and one of the largest in the world (EMR). The plant produces post-consumer plastics from automotive shredder residue, appliances and electronics and has a processing capacity of over 40,000 metric tons per annum. [28]

MBA has more than 150,00 metric tons per year of processing capacity in Europe, China and the U.S. to turn waste into recycled plastics. [21]

With its new facility in Germany, in Mauna near Meissen, the company wants to make use of the growing quantities of WEEE in Germany and Europe and the global demand for post-consumer plastics. The site has a capacity of 20,000 metric tons per year and employees 20 people. [28]

Furthermore, MBA Polymers has administration offices in Hong Kong, USA, Germany and India.

The company has developed over 40 patents. MBA Polymers’ technology and patents are registered in Australia, Canada, China, Europe and USA. The patents are 100% owned by MBA Polymers Inc, including any improvements made at the plant level. The highly automated polymer separation technology developed and patented by MBA Polymers encompasses over 20 complex separation procedures to facilitate the recovery, purification and monetization of plastics by type and grade at attractive commercial economics.

The latest patent was issued on 17.01.2019 by the European Patent office is Nr EP14707916.4: Process and Requirement for the recovery of plastic from durable goods (ASR, ESR, WSR).

Awards

Related Research Articles

<span class="mw-page-title-main">Recycling</span> Converting waste materials into new products

Recycling is the process of converting waste materials into new materials and objects. This concept often includes the recovery of energy from waste materials. The recyclability of a material depends on its ability to reacquire the properties it had in its original state. It is an alternative to "conventional" waste disposal that can save material and help lower greenhouse gas emissions. It can also prevent the waste of potentially useful materials and reduce the consumption of fresh raw materials, reducing energy use, air pollution and water pollution.

Thermal depolymerization (TDP) is the process of converting a polymer into a monomer or a mixture of monomers, by predominantly thermal means. It may be catalysed or un-catalysed and is distinct from other forms of depolymerisation which may rely on the use of chemicals or biological action. This process is associated with an increase in entropy.

<span class="mw-page-title-main">Polyethylene terephthalate</span> Polymer

Polyethylene terephthalate (or poly(ethylene terephthalate), PET, PETE, or the obsolete PETP or PET-P), is the most common thermoplastic polymer resin of the polyester family and is used in fibres for clothing, containers for liquids and foods, and thermoforming for manufacturing, and in combination with glass fibre for engineering resins.

Eastman Chemical Company is an American company primarily involved in the chemical industry. Once a subsidiary of Kodak, today it is an independent global specialty materials company that produces a broad range of advanced materials, chemicals and fibers for everyday purposes. Founded in 1920 and based in Kingsport, Tennessee, the company operates 36 manufacturing sites worldwide and employs approximately 14,000 people.

<span class="mw-page-title-main">PET bottle recycling</span> Recycling of bottles made of polyethylene terephthalate

Although PET is used in several applications, as of 2022 only bottles are collected at a substantial scale. The main motivations have been either cost reduction or recycle content of retail goods. An increasing amount is recycled back into bottles, the rest goes into fibres, film, thermoformed packaging and strapping. After sorting, cleaning and grinding, 'bottle flake' is obtained, which is then processed by either:

<span class="mw-page-title-main">Materials recovery facility</span> Plant to process recyclates

A materials recovery facility, materials reclamation facility, materials recycling facility or multi re-use facility is a specialized plant that receives, separates and prepares recyclable materials for marketing to end-user manufacturers. Generally, there are two different types: clean and dirty materials recovery facilities.

<span class="mw-page-title-main">Plastic recycling</span> Processes which convert waste plastic into new items

Plastic recycling is the processing of plastic waste into other products. Recycling can reduce dependence on landfill, conserve resources and protect the environment from plastic pollution and greenhouse gas emissions. Recycling rates lag those of other recoverable materials, such as aluminium, glass and paper. From the start of production through to 2015, the world produced some 6.3 billion tonnes of plastic waste, only 9% of which has been recycled, and only ~1% has been recycled more than once. Of the remaining waste, 12% was incinerated and 79% either sent to landfill or lost into the environment as pollution.

<span class="mw-page-title-main">Disposable product</span> Product designed to be discarded after use

A disposable is a product designed for a single use after which it is recycled or is disposed as solid waste. The term is also sometimes used for products that may last several months to distinguish from similar products that last indefinitely. The word "disposables" is not to be confused with the word "consumables", which is widely used in the mechanical world. For example, welders consider welding rods, tips, nozzles, gas, etc. to be "consumables", as they last only a certain amount of time before needing to be replaced. Consumables are needed for a process to take place, such as inks for printing and welding rods for welding, while disposable products are items that can be discarded after they become damaged or are no longer useful.

<span class="mw-page-title-main">Electronic waste</span> Discarded electronic devices

Electronic waste describes discarded electrical or electronic devices. It is also commonly known as waste electrical and electronic equipment (WEEE) or end-of-life (EOL) electronics. Used electronics which are destined for refurbishment, reuse, resale, salvage recycling through material recovery, or disposal are also considered e-waste. Informal processing of e-waste in developing countries can lead to adverse human health effects and environmental pollution. The growing consumption of electronic goods due to the Digital Revolution and innovations in science and technology, such as bitcoin, has led to a global e-waste problem and hazard. The rapid exponential increase of e-waste is due to frequent new model releases and unnecessary purchases of electrical and electronic equipment (EEE), short innovation cycles and low recycling rates, and a drop in the average life span of computers.

Coated paper is paper that has been coated by a mixture of materials or a polymer to impart certain qualities to the paper, including weight, surface gloss, smoothness, or reduced ink absorbency. Various materials, including kaolinite, calcium carbonate, bentonite, and talc, can be used to coat paper for high-quality printing used in the packaging industry and in magazines.

<span class="mw-page-title-main">Automotive shredder residue</span>

The shredding of automobiles and major household appliances is a process where a hammermill acts as a giant tree chipper by grinding the materials fed into it to fist-size pieces. The shredding of automobiles results in a mixture of ferrous metal, non-ferrous metal and shredder waste, called automotive shredder residue or automobile shredder residue (ASR). ASR consists of glass, fiber, rubber, automobile liquids, plastics and dirt. ASR is sometimes differentiated into shredder light fraction and dust. Sometimes these residual materials are called "car-fluff".

<span class="mw-page-title-main">Recycling codes</span> Code identifying material, for recycling

Recycling codes are used to identify the materials out of which the item is made, to facilitate easier recycling process. The presence on an item of a recycling code, a chasing arrows logo, or a resin code, is not an automatic indicator that a material is recyclable; it is an explanation of what the item is made of. Codes have been developed for batteries, biomatter/organic material, glass, metals, paper, and plastics. Various countries have adopted different codes. For example, the table below shows the polymer resin (plastic) codes. In the United States there are fewer, because ABS is placed with "others" in group 7.

<span class="mw-page-title-main">Plastic</span> Material of a wide range of synthetic or semi-synthetic organic solids

Plastics are a wide range of synthetic or semi-synthetic materials that use polymers as a main ingredient. Their plasticity makes it possible for plastics to be molded, extruded or pressed into solid objects of various shapes. This adaptability, plus a wide range of other properties, such as being lightweight, durable, flexible, and inexpensive to produce, has led to their widespread use. Plastics typically are made through human industrial systems. Most modern plastics are derived from fossil fuel-based chemicals like natural gas or petroleum; however, recent industrial methods use variants made from renewable materials, such as corn or cotton derivatives.

Recycling can be carried out on various raw materials. Recycling is an important part of creating more sustainable economies, reducing the cost and environmental impact of raw materials. Not all materials are easily recycled, and processing recyclable into the correct waste stream requires considerable energy. Some particular manufactured goods are not easily separated, unless specially process therefore have unique product-based recycling processes.

Products made from a variety of materials can be recycled using a number of processes.

<span class="mw-page-title-main">Chinook Sciences</span>

Chinook Sciences is a US and UK based technology company that specializes in waste to energy and metal recovery.

A scrap metal shredder, also sometimes referred to as a metal scrap shredder, is a machine used for reducing the size of scrap metal. Scrap metal shredders come in many different variations and sizes.

<span class="mw-page-title-main">Appliance recycling</span> We should recycle every plastic and polymer things

Appliance recycling is the process of dismantling scrapped home appliances to recover their parts or materials for reuse. Recycling appliances for their original or other purposes, involves disassembly, removal of hazardous components and destruction of the equipment to recover materials, generally by shredding, sorting and grading. The rate at which appliances are discarded has increased due in part to obsolescence due to technological advancement, and in part to not being designed to be repairable. The main types of appliances that are recycled are televisions, refrigerators, air conditioners, washing machines, and computers. When appliances are recycled, they can be looked upon as a valuable resources; if disposed of improperly, they can be environmentally harmful and poison ecosystems.

Plastic roads are paved roadways that are made partially or entirely from plastic or plastic composites, which is used to replace standard asphalt materials. Most plastic roads make use of plastic waste a portion the asphalt. It is currently unknown how these aggregates will perform in the mid- to long-term, or what effect their degradation might have on surrounding ecosystems.

China's waste import ban, instated at the end of 2017, prevented foreign inflows of waste products. Starting in early 2018, the government of China, under Operation National Sword, banned the import of several types of waste, including plastics with a contamination level of above 0.05 percent. The ban has greatly affected recycling industries worldwide, as China had been the world's largest importer of waste plastics and processed hard-to-recycle plastics for other countries, especially in the West.

References

  1. 1 2 3 "Plastics News, "MBA Polymers relocating R&D to the UK", by Jessica Holbrook 15th July 2013". Prw.com. Retrieved 18 September 2013.
  2. 1 2 Caliendo, Heather (5 August 2013). "Entrepreneur looks to reduce both plastic waste and poverty". Plastics Today. Retrieved 18 September 2013.
  3. "MBA Polymer Articles of Incorporation CA Secretary of State".
  4. "MBA Polymers". MBA Polymers.
  5. "Amended articles of Incorporation MBA CA 1998".
  6. "Recycling_Intl_4_04 Breaking_Plastics_Mould.pdf - MBA Polymers ..." yumpu.com.
  7. "SEC filing" (PDF). 2001.
  8. "CNN.com, "How companies grow through a recession", by Kevin Voigt, 11th September 2009" (PDF). Retrieved 18 September 2013.
  9. "CNN.com, "Will green tech be the next investment bubble?", by Matt Ford" (PDF). Retrieved 18 September 2013.
  10. We can recycle plastic - Mike Biddle , retrieved 23 August 2019
  11. Holbrook, Jessica (15 July 2013). "US-based recyclers may gain from China's Green Fence". wasterecyclingnews.com. Waste & Recycling News.
  12. "MBA Polymers". EquityNet.
  13. Saporito, Bill (12 December 2005). "Time, "A flash of the future"" (PDF). Archived from the original (PDF) on 16 May 2013. Retrieved 18 September 2013. This technology means that material that might otherwise end up in landfill can be more easily recycled and is an important step in creating sustainable business processes
  14. "Recently". Elephant Equity GmbH. Retrieved 23 August 2019.
  15. Fisher, Michael M. (1996). Meeting Customer Expectations- Exploring the Frontiers of Plastics Recovery and Recycling Technology. Indianapolis, IN: Society of Plastic Engineers, Antec Conference proceedings. p. 2877.
  16. Allen, Laurence. "Technique for Enhancing the Effectiveness of Slurried Dense Media Separations".
  17. Allen, Laurence. "Differential Density Alteration Patent".
  18. "MBA Polymers ATP Grant announcement". 6 March 1997.
  19. Allen, Laurence. "Multistep Separation of Plastics".
  20. "Silicon Valley Business Journal, "Recycling executive makes his mark with trashed computers", by David Bragi" (PDF). 18 March 2001. Retrieved 18 September 2013.
  21. 1 2 3 "MBA Polymers". MBA Polymers. Retrieved 23 August 2019.
  22. "Forbes, "Where does it go?", by Kerry A. Dolan, 31st October 2005" (PDF). Retrieved 18 September 2013.
  23. Earley, Katharine (27 August 2013). ""Could China's green fence prompt a global recycling innovation?"". The Guardian . Retrieved 18 September 2013.
  24. "Müller-Guttenbrunn Gruppe » MGG takes over 100% of MBA Polymers Austria" (in German). Retrieved 23 August 2019.
  25. "MBA Polymers adding e-waste recycling plant in Germany". Plastics News. 20 August 2019. Retrieved 23 August 2019.
  26. 1 2 Xinlian, Liu (8 August 2011). "New Life for Old Plastics". Beijing Review. Bjreview.com.cn. Retrieved 18 September 2013.
  27. derStandard.at (1 August 2013). ""Wirtschaftspark Kematen auf Erfolgskurs", The Standard, 1st August 2013". Derstandard.at. Retrieved 18 September 2013.
  28. 1 2 "Locations • MBA Polymers". MBA Polymers. Retrieved 23 August 2019.
  29. "[node:Title]". www.csrwire.com.
  30. 1 2 "Dr Mike Biddle to receive Gothenburg Sustainable Development Award". www.electronic-recycling.ie. Retrieved 23 August 2019.
  31. "Tech Pioneer Award winners".
  32. "Tech Laureate Award winners 2006". Archived from the original on 31 January 2014. Retrieved 23 April 2014.
  33. G. Miller & Scott Spoolman, Living in the Environment: Principles, Connections, and Solutions, 2009, p572