Using Thermodynamics & 100-Year-Old Technology To Break The $20 Per MWh Barrier

This is a guest post by one of our regular, cleantech-obsessed readers, David Fuchs. Clearly, David thinks he’s on to something big. Enjoy the article!
For years, the production of energy has fascinated me. Over the past 20 years, I have experimented with solar cells made via inkjet printer, a hydraulically coupled compressor and turbine based on Tesla’s turbine, vertical wind turbines, high-temperature cracking of water, high COP heat pumps, all the different varieties of Stirling engines, and many other energy projects. Continuously going back to old projects to incrementally improve them and make them perfect has been fun, except perfect is the enemy of finished.
The week long power outage here in New Jersey, after hurricane Sandy, made me realize that we need simple, scalable, cheap, and locally produced power. Removing all distractions and giving an engineer of German lineage a week to think on a problem often gets the problem solved. After pulling out the 7-pocket expanding file with all my past Stirling designs, a couple notepads, my favorite gel pens, a dry erase board, and some reference books, I began designing. As with any engineering project, you need to describe what you want to accomplish, and your limiting factors. Due to cost constraints, engineering is always compromise.
What is the goal? An always-on (24 x 7 x 365) power supply that is inexpensive to produce, can be bulk produced with readily available materials, can be manufactured in any nation using 1950′s or earlier technology, and has a working lifespan greater than 20 years. (That sounds really simple, doesn’t it?)
What are the design criteria?

• Low Temperature Differential (LTD) Stirling based design.
• All parts must be designed for high-speed manufacture and assembly.
• All materials used must be inexpensive and readily available.
• The Stirling design must have the least number of wear points possible.
• It must use inexpensive solar thermal panels for gathering energy.
• The solar panels must be easily produced in an automated fashion.
• It must have inexpensive (dirt cheap) energy storage.
• It must produce at least 3 kW of power continuously (24 x 7 x 365 x 20).
• On a daily basis, it must be capable of gathering two to three times the energy required for a 24-hour period, on the least sunny day of the year. (NREL solar radiation manual)
• It must be capable of storing the energy required for 3 to 5 days of continuous usage with no energy input.
• Any person with basic mechanical skills should be able to install the system.
• The total Levelized Cost of Energy (LCOE) must be under $20 per MWh.

The basic system layout.

Semi-Steampunk Energy Flow Diagram

This system layout image represents the individual pieces and the energy flows between the individual components. The flow controller controls the heat distribution between components.
The system consists of six main components:

1. Solar thermal cells for gathering energy.
2. An insulated thermal mass for storing the energy (dirt or water).
3. A heat radiator for disposing of waste heat.
4. An LTD Stirling engine for generating energy.
5. A flow controller for for fluid flow, preventing energy loss from the system, and increasing efficiency.
6. An inverter to connect to the grid and convert DC power from the generator to AC usable in your house and power grid.

Each component is designed to be as inexpensive, modular, easily replaceable, and mass producible  as possible.


untuk melihat lebih jelas klik link dibawah ini ;
http://cleantechnica.com/2012/12/29/using-thermodynamics-100-year-old-technology-to-break-the-20-per-mwh-barrier/