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Retail Beamed Power for a Micro Renewable Energy Architecture: Survey. Opportunities In Power Beaming For Micro Renewable Energy. Narayanan Komerath Professor, Daniel Guggenheim School of Aerospace Engineering Georgia Institute of Technology Atlanta, Georgia USA. - PowerPoint PPT Presentation
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Experimental Aerodynamics and Concepts Group
Retail Beamed Power for a Micro Renewable Energy Architecture: Survey Opportunities In Power Beaming For Micro Renewable Energy
Narayanan KomerathProfessor, Daniel Guggenheim School
of Aerospace EngineeringGeorgia Institute of Technology
Atlanta, Georgia USA
Concept development work was supported by NASA under the EXTROVERT cross-disciplinary innovation initiative. Mr. Tony Springer is the Technical Monitor.
Experimental Aerodynamics and Concepts Group
•Breakthroughs in renewable energy require cross-disciplinary innovation.
•Developing advanced concepts that go well beyond today’s practices, is a useful way for students to learn about innovation across discipline barriers. •Issue: How to develop a power transmission and distribution architecture based on wireless beaming.
•Processes of defining requirements and selecting parameters.
•Education through cross-disciplinary learning on projects. Student experience over the years starting from initial concept exploration to present.
•Idea of “concept resilience” as it applies to students and faculty developing advanced concepts.
Summary
Experimental Aerodynamics and Concepts Group
•Renewable energy: constraints and innovations come from a very broad range of disciplines within and outside science and engineering.
•Paper is about how learners from traditional disciplines deal with grand challenges and opportunities to innovate towards far-off goals, learning what they must learn, wherever that knowledge can be found, and surviving the continuous onslaught of superstitions without losing sight of reality.
“Learning is not just through courses”.
Introduction
Experimental Aerodynamics and Concepts Group
•Concept: electric power delivery to customer sites through narrow beams of electromagnetic waves, •Essential component in Space and atmospheric Power Grid. •Enables solar or wind power plants to be built at remote sites. •Reduces amount of auxiliary generation capacity required to meet “baseload supplier” criterion. •Power delivery to islands and mountainous sites using towers, mountain ridges or lighter-than-air platforms. •Retail scale, power delivery to rural homes and villages, and allows micro power generation systems to become viable. •At a very small scale, power beaming provides essential services to people who have no other access to electric power other than portable batteries or fossil-powered generators. •Massive significance for rural electrification and renewable power generation.
Why study power beaming
Experimental Aerodynamics and Concepts Group
Aerospace Interest: 3-stage Approach to Power DeliveryAerospace Interest: 3-stage Approach to Power Delivery1. Tower to village (KW-1MW per tower )2. Regional plant or Space – stratospheric platform – customer (10-100MW per platform)3. Space Power Grid – national /global needs (100MW per satellite)Beamed delivery to remote sites and islands is possible from Space / Stratospheric Platforms/ UAVsRetail beaming can close the business case for beamed power, while enabling many communities to leap ahead of terrestrial power grid
expansion
Relay height AGL, km
Regional
global
Surf
ace
rang
e to
vis
ible
hor
izon
, km
Local
Experimental Aerodynamics and Concepts Group
Baseline economic model for rural BPTS
• Wired or Strat-form power delivery to rural station• Beamed “last kilometer” to customer antenna• Synergy with mobile phone and railway infrastructure where possible• Local industry/major users must subsidize costs of reaching small users
Experimental Aerodynamics and Concepts Group
Potential Near-Term ApplicationsPotential Near-Term Applications
Broad area low intensity power distribution for emergencies
Deliver to local village grid Remote military or scientific outposts High endurance miniature robots Distributed micro power generation Remote area exploration Increased range for electric vehicles Rapid restructuring of grid topology for
damage mitigation
Experimental Aerodynamics and Concepts Group
•How does one go about developing such an idea?•How will students learn the basic issues, concepts, theory and skills required to develop the concept?
Central Issue of this paper
Experimental Aerodynamics and Concepts Group
To understand the issues in power beaming, enough to consider developing viable solutions, the learner must surmount a daunting array of obstacles.
Usual Conclusion: Need a cross-disciplinary team of specialists, which is an expensive proposition, to be deferred until a major project is funded.
Corollary: No such project can be contemplated until concept development has shown that there is a feasible path in the near term, and only the detailed design remains to be developed, with all required technological solutions well established and available.
“surviving the continuous onslaught of superstitions without losing sight of reality.”
Learning Issue #1: Concept Resilience
Experimental Aerodynamics and Concepts Group
Issues and discipline areas involved in power beaming
Experimental Aerodynamics and Concepts Group
•Initial concept exploration•Identifying the required and achievable bounds on efficiency•Minimum power transaction level for system breakeven•Argument for millimeter wave beaming•Finding sources and strengthening cost estimation•Satellite orbits and propagation loss refinement•Course development and iterative refinement of knowledge•Retail power beaming•Formalizing resources for knowledge establishment and transfer
Other Learning issues:
Experimental Aerodynamics and Concepts Group
Summary: Learning opportunities in power beaming
Experimental Aerodynamics and Concepts Group
1. Expense of solid state arrays vs. PV arrays
Issues and solutions
Issue Solution/Argument
Low efficiency of generation and transmission.
Compare value of 1st watt-hourOpportunity cost of waiting for grid
Expense of solid state arrays vs. PV arrays
Design for synergy. PV panels as mm wave antennae at night. Integrated PV/mmwave chips toreceive, convert and transmit power
Atmospheric Propagation Losses Minimize horizontal path at low altitude.Use burn-through or Evaporation Ducts
High Beam Intensity Automatic cutoff unless link is functioning
Health Effects of Millimeter Waves Unknown – needs research
Generation of Millimeter Waves Mass-produced solid-state arrays; Photonic approaches
Infrastructure Mobile Telephone Infrastructure as convenient “last kilometer” transmitters
Experimental Aerodynamics and Concepts Group
Conclusions
•Power beaming enables breakthroughs in renewable power architectures, both on earth and in Space.
•Beamed power can reach islands, remote communities, and hundreds of millions of people in less developed nations, giving them access to many essential services and to global connectivity.
•Study of power beaming opens several leading edge opportunities. •Concept development helps student realize how advances fit in with each other, and allow progress towards larger goals.
•Successfully involves students at all levels and from various disciplines.• Developers must first develop “Concept Resilience”. •Typical learning methods of students include discussions with other students and faculty, as well as internet search techniques, and reading textbooks.
Experimental Aerodynamics and Concepts Group
Antenna Size Dictates Millimeter Wave RegimeAntenna Size Dictates Millimeter Wave Regime(GEO receiver size is off the chart)(GEO receiver size is off the chart)
Frequency, GHz
Rec
eive
r Dia
met
er, m
•Frequencies below 100GHz are not viable for delivery from Space, due to costs of space and ground infrastructure. Hence interest in millimeter waves.
•Mmwave infrastructure is suitable for retail family / village sized receivers
Experimental Aerodynamics and Concepts Group
http://images.gizmag.com/hero/6358_20100630239.jpg
http://www2.nict.go.jp/q/q262/3107/end101/ENG/FAQ/FAQ-E1.htm
http://images.gizmag.com/hero/6358_20100630239.jpg
Regional power plant to stratospheric platform (Stratoform) to customer siteRegional power plant to stratospheric platform (Stratoform) to customer site
•Range to 600 km •Power level ~10 to 100 MW•Multiple receivers•“Burnthrough” beam to handle bad weather
Experimental Aerodynamics and Concepts Group
Dealing With Low Efficiency•Value of first watt-hour
•Opportunity cost of waiting for wired grid
Experimental Aerodynamics and Concepts Group
TABLE 1. User Requirements for Micro Renewable Energy Systems
Use Cold-Region KW rating
Cold-region KWh per day
Warm-region KW rating
Warm-region KWh per day
Lighting1 0.020 0.200 0.020 0.120 Fan2 0.034 0.407 0.034 0.407
Communications3 0.004 0.012 0.004 0.012 Computers4 0.113 0.452 0.113 0.452
TV5 0.100 0.400 0.100 0.400 Wireless Router6 0.007 0.007 0.056 0.056
Refrigerator7 0.400 6.800 0.400 9.600 Total Electric 0.678 8.278 0.727 11.048
Cooking8 1.000 2.000 1.000 2.000 Water Heating9 1.000 2.000 1.000 1.000
Air Heat or A/C10 1.350 10.801 1.900 4.275 Total Heat Energy 3.350 14.801 2.713 4.603
Total Energy 4.028 23.079 3.440 15.651 1 LEDs equivalent to 200watts of incandescent lamps 2 Lasko vertical fan, 120vAC, 0.4A 3 Cellphone charger, Samsung 2004 model 4 Sony VAIO 17 inch-display laptop charger, 2010 model 5 LCD/LED Flat panel TV average, 2010. 6 2010 Average 7 18 cu. ft. US average, 2010 8 Electric cooktops, 2010 9 Electric showerhead heater takes 2.75KW, 2.5GPM flow 10 Cold regions use AC 3 months, warm regions 6 months, but have natural ventilation. Only
cold regions use heat.
Many needs are met by a few watt-hours
Experimental Aerodynamics and Concepts Group
Dry Atmospheric Absorption for Vertical Transit
Good windows at ~100, 140, 220GHz
Need: Narrow-band datato identify best windowsnear 100 GHz and 220GHz
Experimental Aerodynamics and Concepts Group
Line A: Average absorption at sea level, 20C, 1atm, H2O vapor 7.5 g/m3) Line B: Altitude 4 kilometers pressure altitude, (0C, Water Vapor Density= 1 g/m3)
Atmospheric Absorption for Horizontal Propagation (Why go up instead)
http://ops.fhwa.dot.gov/publications/viirpt/sec5.htm
Experimental Aerodynamics and Concepts Group
Impact of rain and fog: Need “burn-through”.
220GHz
94GHz
DSP/solid state generation permits use of an initial burn-through frequency followed by main power beam
Experimental Aerodynamics and Concepts Group
Technology OpportunitiesTechnology Opportunities
• Integrate mm-wave receivers with solar panels• Narrow-band phase-array receivers for laser and mm-waves, integrated with PV panels• Nanotube broadband direct solar conversion antenna• Burn-through rain, clouds and fog using mmwave and other wavelengths• Lightning analogy: Create conductive path for mm-wave beam using “seed” beam• Use waste heat on relay platforms to generate burn-through beam• Co-use communications and power transfer control equipment• Improve conversion efficiency to & from 200-220 GHz• Satellite waveguides• Thermal management• Effects of scattered 220Ghz radiation on humans/animals
Experimental Aerodynamics and Concepts Group
1. Rising demand for connectivity and personal electronics, creates an opportunity to leap-frog grid expansion using retail power beaming.
2. Millimeter wave beaming brings antenna sizes practical for retail installation.3. Enables retail power distribution to off-grid locations and islands. 4. Closes the business case for distribution through Space and statospheric platforms.5. Enables synergy with distributed micro renewable power architectures.6. Value of first few watts and watt-hours >> marginal cost of utility power. 7. Synergy with photovoltaic arrays multiplies cost-effectiveness of micro power architectures8. Optimal frequencies for moist atmospheres differ from those for long-distance dry air and
vacuum beaming. 9. Solid-state arrays enable several beam frequencies from the same arrays in order to serve
multiple purposes. 10. Indian village electrification offers an opportunity to establish a retail beaming infrastructure.
Rural economics model works best with stratospheric platforms, local beamed delivery and subsidized cost to small users.
11. High-resolution data needed for 100GHz and 220GHz bands12. Low efficiency and weather issues are not show-stoppers for retail millimeter wave power
beaming.
Conclusions
Experimental Aerodynamics and Concepts Group
Beamed Retail Power Transmission/ Distribution SystemBeamed Retail Power Transmission/ Distribution System
mm wave to DC
conversion
mm wave to DC
conversion
DC to mm wave
conversion
DC to mm wave
conversion
Beam Formation Transmission &
Reception
•Wireless transmission of power (not just signals with information) over relatively short distances to multiple end-user receivers.
•Usually implies focused point-to-point transmission with highly directional antennae, and provisions for energy storage at either end.
•Conventional solutions using <10GHz microwave, and some proposed solutions using lasers.
•Our interest is in the millimeter wave regime, specifically near 220 GHz
Experimental Aerodynamics and Concepts Group
140GHz Propellant Heating Beam Being Considered by NASA/USAF
Space Power Grid Concept:220 GHz
Experimental Aerodynamics and Concepts Group
3. Space Power Grid Use space-based infrastructure to
boost terrestrial “green” energy production from land and sea: argument for public support.
Full Space Solar Power (very large collectors in high orbit) will add gradually to revenue-generating infrastructure.
Exploit large geographical, daily and seasonal fluctuations in power cost (Landis 2004, Bekey 1995).Beam to other satellitesRetail delivery (SPS2000).
Technical risks in dynamic beaming/reception/ transaction system.
Inefficient conversion to and from microwave vs. terrestrial high-voltage transmission lines.
Space Power Grid: Redistributing EnergySpace Power Grid: Redistributing Energy
FIGURE 1. Space Power Grid Satellite Receving And Redistributing Beamed Power.
Team: Brendan Dessanti, Janek Witharana
Experimental Aerodynamics and Concepts Group
Power delivery to points of local distribution
•Low-altitude horizontal beaming is inefficient unless burn-through techniques are perfected.
•Use vertical beaming to and from high-altitude platforms wherever possible.
Experimental Aerodynamics and Concepts Group
The Dream of Energy Independence •Terrestrial solar, wind and biomass power plants•Space-delivered solar power•Beamed power to complement local generation, in off-grid communities•Hydrogen generation using excess / spike power•Stored hydrogen and bio-gas for fuel cells and transportation
Experimental Aerodynamics and Concepts Group
Burn-through rain, clouds and fog using mmwave and other Burn-through rain, clouds and fog using mmwave and other wavelengthswavelengths
Options to investigate:
1.Find narrow lines in 220GHz window, where propagation efficiency is higher. 2.Saturate? No experiments found so far on the effect of sustained beam energy addition on wet air for durations of minutes2. Deliberately heat using selected frequencies and create low-density path?3.Lightning analogy? Create conductive path for mm-wave beam using “seed” beam
Solid state arrays / DSP-PLL generation approach allows consideration of tuning to narrow bands, and shifting to a pilot beam for a short duration toprepare the path for the main beam
Experimental Aerodynamics and Concepts Group
•India: 638,000 villages, 80 percent have at least one electric line.
•415 million people have no access to electricity
•Over 450 million mobile phone accounts (Multiple accounts per user).
•Retail Power Beaming is a viable alternative to constructing wired grids for several future applications, despite low efficiency.
•Route for the small electronic devices market to leapfrog the centralized power grid, in many parts of the world.
Demand for mobile connectivity and other electric devices far outpaces power grid expansion.
Experimental Aerodynamics and Concepts Group
Summary Observations -2
•Direct conversion from broad-band solar to beamed mmwave appears feasible. •Integrated antenna / PV generators already in use•Large-scale arrays of solid-state devices with DSP and PLL to generate mmwave•Laser efficiencies may be on cusp of breakthrough but need changes in laws/treaties
Most current “systems analyses” of SSP prospects appear to assume <$400/lb launch coststo LEO. This is not realistic. Must insist on disciplined costing to see the real technology opportunities.
Experimental Aerodynamics and Concepts Group
The Space Power Grid Approach
•Exploit large geographical, daily and seasonal fluctuations in power cost.•Beam to other satellites.•Retail delivery (SPS2000).
Use space-based infrastructure to boost terrestrial “green” energy production from land and sea: argument for public support.
Full Space Solar Power (very large collectors in high orbit) will add gradually to revenue-generating infrastructure.
Experimental Aerodynamics and Concepts Group
AcknowledgementAcknowledgement
Support from NASA under the “EXTROVERT” cross-disciplinary learninginitiative is gratefully acknowledged.
Experimental Aerodynamics and Concepts Group
http://www.newscientist.com/data/images/archive/2631/26311601.jpg
Space Solar Power the old way
GEO: S=36000km
LEO: ~400km
MEO: ~10000km
Earth Radius ~6370km
Experimental Aerodynamics and Concepts Group
Afternoon Sun system.
•80 minutes of access per 24 hours per location. •This orbit performs 23 revolutions around the earth every 48 hours.
Ground Tracks of 6 sun-synchronous satellites at 1900 km
Experimental Aerodynamics and Concepts Group
Absorption vs. Spillover
Most GEO/ 5.8GHz architectures assume receivers sized for 83% beam capturebecause of the large receiver size
Example:
5.8GHz: 84% Beam capture, 95% Transmission through atmosphereNet capture = 0.95*0.84 = 80%
220GHz: 99% Beam capture, 90% transmission = 89%
Benefits of compact antenna are far beyond this.
Both laser and mmwave enable compact, 99% capture receivers.
Experimental Aerodynamics and Concepts Group
“Shown: An array of aligned, but randomly placed, carbon nanotubes which can act like a radio antenna for detecting light at visible wavelengths. The scale bar is one micron in length.Wang et al., Applied Physics Letters, 27 September 2004.”
Antenna for Visible Light
Nanotube broadband direct solar conversion antenna, with narrow-band high-efficiency receivers for mm wave.
http://www.aip.org/png/2004/221.htm