Polyethylene from Ethanol: Difference between revisions

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Introduction: Polyethylene

Polyethylene (PE) is a polymer of long chains of the monomer ethylene (IUPAC name "ethene"). It is one of the world’s most common plastics, with a wide range of uses and over 60 million tons produced worldwide every year. Several different categories exist, based on density and branching. Common types are high-density PE (HDPE; plastic # 2) and low-density PE (LDPE; plastic # 4). Polyethylene is not biodegradable, therefore significant environmental issues are associated with its use. Recycling of PE is relatively straightforward. When disposables are involved, every effort should be made to replace PE with biodegradable alternatives. However, resistance to biodegradation can also be a desired effect for some applications. For example, geomembranes are often made of HDPE and are widely used as liners for fish ponds, constructed wetlands and biogas digesters. Its resistance to degradation also warrants its use in the natural gas industry in transporting natural gas underground in high density PE pipes. Excellent chemical resistance of PE allows for widespread use in storage applications. PE is also useful as a material for digital fabrication. It can be used in the RepRap 3D printer.

Polyethylene from ethanol two step conversion

Ethene is a very simple two-carbon organic molecule (C₂H₄) that does not have to be derived from petroleum. In fact, it can easily be produced from ethanol in a dehydration reaction. This has been known for many decades, but was not cost-competitive at low oil prices. Recently, a Brazilan-Japanese joint venture announced the "Green Polyethylene Project", with sugarcane as the feedstock. Commercial-scale introduction of this "BIO-polyethylene" is planned for 2011. We welcome PE to the club of bioplastics and believe that small-scale production from ethanol can be made practical.

Dehydration of ethanol seems fairly simple to do with an aluminum oxide catalyst. This method is well suited to small batches and could be easily scaled up to larger batch sizes. It sounds fairly easy to test out. They don't mention the required temperature but it has to be lower than the ignition point of ethanol(~362°C). If we want food-independent ethylene production, especially for larger scale use, we could go from carbon dioxide and water to syngas (a mixture of carbon monoxide and hydrogen) and then finally to ethylene [1]. This [2] may be useful for producing the syngas.using a fluid bed reactor or recently in a microreactor. The production of a distillation chamber capable of lowering pressure may also benefit the aluminum refining process. Aluminum is a favored catalyst for ethanol dehydration to ethylene but additional compounds such as transition metals increase yield and selectivity while other zeolite catalysts have also been described (Chen et al.).

Polymerization of ethylene is an exothermic reaction with multiple generations of catalysts. Phosphoric acid is the earliest catalyst under high pressure and temperature. Zeolite initially of silicates and then other matrices made the second generation of catalysts and still operated under elevated pressures and temperature. The third and currently evolving class of catalysts are known as Ziegler-Natta catalyst use an activator molecule of the (Al)C2H5n organoaluminum cocatalyst or methylaluminoxane and a titanium catalyst (TiCl3 or TiCl4 etc).

There are a number of steps involved in polyethylene production from a biotic feedstock; selection of a feedstock, construction of open source fermentors, purification equipment, and fluid bed reactors, along with methods of measuring yield and quality of each step will be require bringing a diverse background of knowledge together.

Status Brief

Almost all PE today is derived from petroleum. In a very energy-intensive process, a petroleum feedstock is cracked at high temperatures. After distillation and purification in large, capital-intensive facilities, ethylene is produced. This is then polymerized to polyethylene, a process that again involves high temperatures, high pressures and often toxic organic solvents. Clearly not an ideal situation.

An OSE project to replace this process with a constructive route from organic feedstocks rather than degradative oil based processes is currently in the research and development phase. The process is being developed Extreme Manufacturing system and according to OSE guidelines. A literature review on Polyethylene from Ethanol/Research Development details the major steps of the process, technologies employed, and applicable details to an OSE standard. Scrum project management will be a used if a team comes together or an individual wants to take on a project. Current blockages: Help with technical review and people with experience in the field is needed. Expertise in fluid mechanics is needed for the reactor design. Graphic design or CAD of the system would be a big benefit. Interested autodidacts. Sourcing info. Completed work: system process reviewed, OSE concept, SEBD preliminary, catalysts reviewed, 1st generation catalysts proposed,

Documentation Brief

A thorough review of the process of creating polyethylene from ethanol is underway on this page. A catalyst protocol for the dehydration step is underway. A Systems Engineering Break Down is needed and an examination of the processes full product ecology. Assistance is needed summarize unreviewed literature and provide summaries of important information. A thorough review of the polymerization catalysts is needed.

System Engineering Breakdown Diagram

Process design

Producing polyethylene from locally produced base materials and open source hardware will require the production of high purity molecules and machines capable of conversion at high efficiency and selectivity. The project can be broken down the three aims of producing high quality ethanol, ethylene, and polyethylene. The tasks need to be further divided into catalyst selection, hardware components, and substrate requirements to be worked on separately as part of the scrum process. Task 2, the dehydration of ethanol to ethylene, will be the first goal of the project as it has the largest value margin between substrate and product and the catalyst requirements are within the scope of OSE's currently proposed product ecology.

1. Production of ethanol on-site from sorghum utilizing yeast fermentation. A. Selection of yeast and/or bacterial strains that are optimal for sorghum fermentation and finding their optimal conditions. B. Construction of fermentation equipment. C. Construction of distillation equipment capable of operating under vacuum, which could possibly be attached to fermentation chamber. D. Method for measuring alcohol purity. Measuring specific gravity is means of getting a rough estimating ethanol yield and with internal improvements can achieve higher accuracy. Measurements against as internal standard and a pure ethanol standard can improve hydrometers accuracy.

2. Dehydration of ethanol using a catalyst and fluid bed reactor. A. Selecting a catalyst. AlO3 can be utilized as an initial catalyst after production by the aluminium extractor. A base wash with KOH or NaOH can be used to increase the specificity of catalyst. Improvements to the catalyst can be incrementally made as OSE technology becomes available. B. Constructing a reactor chamber capable of mixing the catalyst and substrates under optimal conditions. Reactor chamber must allow control over temperature, pressure, addition and removal of catalyst, control of feedrate and interaction time of substrate, and separation of production and should incorporate features that allow easy reconfiguration and recycling of catalysts, solvents, and unconverted substrate. C. A fractionation column will be used to remove byproducts, unreacted substrate, and inert gas, producing high purity ethylene suitable for polymerization. C. Measurement of ethylene yield and purity using spectroscopic methods.

3. Polymerization of polyethylene from ethylene using transition metal catalyst and fluid bed reactor. A. Selection of a catalyst for polymerization. B. Optimal configuration of reactor for polyethylene polymerization. C. Measurement of PE yield and purity. D. Ability to pass newly formed polyethylene to an extruder or storing as pellets for future extrusion. E. Investigate production of other polymers such as polyethylene vinyl acetate (for greenhouse materials).

4.Extrusion to final product A. Identify most desirable products for OSE product ecology and research optimal extrusion processes. Materials for greenhouses or windows are a high priority as mentioned by Marcin and this application could be the first aim. Identify ways to maximize translucence, increase UV resistance and filtering, and maximize material use with strength and durability (film versus panels) B. Value adding processes such as tensile polymer incorporation or shaping into useful products.

Design Rationale

The design rationale for the OSE agroecological approach is based upon OSE standards. The process design is meant to produce a needed product ecology using local feedstocks. By starting with high purity substrate and selective catalysts purification steps can be minimized and the process conducted on a small scale. A fluid bed reactor is a key piece of hardware that is used by the industry due to its superior performance. An OSE reactor is designed to be reconfigurable to a number of processes and be of appropriate scale.

Starting with commodity ethanol will allow OSE to apply itself to an area where the open source information and demonstration is lacking. Reactor and catalysts are selected based upon demonstrated and easily available chemicals and could open a new sector to open source entrepnuers. Demonstration of a few base applications thermomolding and greenhouse glazing will allow incremental development. Production of feedstock will be conducted as part of an integrated plant at FeF and fermentation and purification technology built to utilize it.

Tools including catalysts and process control should be developed to be multipurpose and modular. Development of multiple uses at once will maintain that focus. The aluminosilicate chemistry learned from this process may allow other products.

Conceptual Design

Specifications

Ability to produce high and low density polymers. Later ability to incorporate comonomers.

Design

Construction of fluid bed reactor

Ethylene polymerization catalyst preparation

Sourcing of substrates, catalysts, and materials