Revision as of 00:15, 17 February 2015

Solar Concentrator
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Overview

The Global Village Construction Set
Nickel-Iron Battery

Research pertaining to the Solar Concentrator.

Research

http://openframeworks.cc could have some useful code and application to this. It would probably only use one of these systems displayed. Also generally an amazing resource for realtime 3d, robotics, arduino control.

OSE Technical Requirements

as Open Source Ecologie team is moving forward developping the linear fresnel reflector is developing and request for your participation the complete set of technical requirements. the current work in progress is located here

Module breakdown for solar concentrator and its prove of concept.
Added to OSE Specification for product design and more specific	http://opensourceecology.org/wiki/OSE_Specifications_for_Product_Design
A score will be attributed on the designes based on the Ose Specifications evaluation Template	http://opensourceecology.org/wiki/OSE_Specifications_Assessment_Template
	Prototype A size 1 Solar concentrator	Proof of concept / Demonstrateur
General
must be DIY friendly (which gives advantage to the linear fresnel reflector type of concentrator)	100%	50%
Linear fresnel reflector with double concentration CPC	100%	50%
5KW heat power output (about 10m^2)	100%	10%
able to reach more than 250øC	100%	70%
must allow (with additional modules) both N/S and E/W axis of installation	60%	60%

Structure
Must support the whole Solar Concentrator system	100%	100%
Must allow mirrors rotation of 270ø with a complete reverse of the mirror in case of bad weather conditions	100%
structure and design OSE Compatible http://opensourceecology.	100%	70%
Ground implantation must assure sufficient stability
Sufficent rigidity to assure resistance to vibrations or impacts	70%	70%
Easily assembled with modular-easy to transport components	70%	70%
Easy optical alignment (assured by any mean - ie. Tracks, giudelines, holes, etc)	100%	100%
Mobile support of the mirrors to avoid deformation due to weight, wind, vibrations, etc	100%
must be designed to reduce any risk concern	80%	60%
Cost optimized	80%	60%
Optionally without any weldering as much as possible
optionally the concentrator and the absorber have indipendent structures (pro: less vibrations, cons: harder to align correctly)
Optionally, if N/S oriented, allow to move the mirrors toward south in order to allow seasonal optimization
with E/W axis, must allow 1*focal lenght of mirrors lenght more	100%	100%

Optical concentration
Mirror's Geometry to be (to define based on best optical optimization, in progress)
Mirrors with high reflectivity (>90% on wide spectrum)	100%	100%
resistant mirrors with high lifespan for external usage.	100%	100%
Mirrors easy to clean	100%	70%
Secondary concentration on the absorber higher than 2x	100%	70%
total factor of concentration 25	100%	70%
mirrors easy to fix and replace on their support	100%	70%
must be designed to reduce any risk concern	80%	60%
Cost optimized	80%	60%

Absorber
specially designed for the selected thermal fluid, with passive or forced circulation	100%	100%
Absorbing material with high optical absorbtion rate on wide spectrum	100%	100%
elevated thermal exchange Absorber / Fluid	80%	60%
high thermal insulation (from external air, from the point of contact with the structure, from IR radiations)	80%	60%
High resistance of thermal variation constraints (high temperatu	80%	60%
Specially designed for the secondary concentrator	80%	60%
must be designed to reduce any risk concern	80%	60%
Cost optimized	80%	60%


Motors, trackers, programs
Must allow for a real time follow & programmed sun follow based on Lat/long	80%	60%
Automatically detect and self protect in case of bad weather	80%	60%
Must be able to track the sun and send the correct angle in order to optimize concentration	80%	60%
Must be able to sense temperature and pressure at fluid input and output	80%	60%
programmable to stop automatically	80%	60%
must provide an easy GUI control interface (optionally handled through cloud, with data collection)	80%

Modeling and studies
Optimisation of Solar concentrator design	80%	60%
Self pilot of the solar concentrator (must perform a logical analysis of current solar concentrator of JB)	80%	40%
Tools to predict energetical production based on geography
Model of economical and technical conditions for optimal usage of the solar concentrator
Finalize localized business case	80%	40%
Identify technical modifications needed to adapt to new usage	80%	40%

The Global Village Construction Set
Habitat	CEB Press	Cement Mixer	Sawmill	Bulldozer	Backhoe
Agriculture	Tractor	Seeder	Hay Rake	Well-Drilling Rig
	Microtractor	Soil Pulverizer	Spader	Hay Cutter	Trencher
	Bakery Oven	Dairy Milker	Microcombine	Baler
Industry	Multimachine	Ironworker	Laser Cutter	Welder	Plasma Cutter
	CNC Torch Table	Metal Roller	Rod and Wire Mill	Press Forge	Universal Rotor
	3D Printer	3D Scanner	CNC Circuit Mill	Industrial Robot	Chipper Hammermill
	Drill Press	Induction Furnace
Energy	Power Cube	Gasifier Burner	Solar Concentrator	Electric Motor Generator	Hydraulic Motor
	Steam Engine	Heat Exchanger	Wind Turbine	Pelletizer	Universal Power Supply
	Nickel-Iron Battery
Materials	Aluminum Extractor	Bioplastic Extruder
Transportation	Car	Truck

Key	Design	Planning	Prototype	Almost done	Full Release

Solar Concentrator/Research Development: Difference between revisions

Revision as of 00:15, 17 February 2015

Contents

Overview

Research

OSE Technical Requirements

See Also

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Solar Concentrator/Research Development: Difference between revisions

Revision as of 00:15, 17 February 2015

Overview

Research

OSE Technical Requirements

See Also

Navigation menu

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