11.1 Solar Thermal Energy

11.1 Solar Thermal Energy Frank R. Leslie, B. S. E. E., M. S. Space Technology, LS IEEE 2/12/2010, Rev. 2.0 fleslie @fit.edu; (321) 674-7377 www.fit.edu/~fleslie http://www.freeenergynews.com/Directory/Solar/Tesla/Experimentor_1916_Solar_Article.pdf

In Other News . . . • Senate passed the energy bill; now consolidation with House bill forms a new H.R.1 bill at $789B • Some rail enhancements, some renewables, some RE job training • In Florida, push to regulate tailpipe emissions starting with new models in 2013 (CAFÉ standards) that will lead to more electric and hybrid cars • Push to approve FPSC recommendations to require utilities to produce 20% power from RE by 2020 and 7% by 2013 • FPL decides to build 10 MWp solar thermal plant at KSC 090212

11.1.1 Overview of Solar Thermal Systems • Solar thermal systems convert sunlight to heat • Categorized by reflector/collector types • None; uses lens; regular or Fresnel • Flat mirror (possibly many of them) • Parabolic/cylindrical: single axis forms “trough” • Paraboloidal: axis of revolution forms “dish” • Spherical: approximates paraboloid, but focus can move to track sun 080205

11.1.1 About This Presentation • 11.1.2 US Solar Energy Distribution • 11.1.3 Flat Collector Types • 11.1.3.2 Water Heaters • 11.1.4 Reflectors • 11.1.5 Solar Thermal Electric Power • 11.1.6 Balance of System • 11.1.7 Food Processing and Cookers • 11.1.8 Advantages and Disadvantages • 11.2 Conclusion 060205

11.1.2 US Solar Energy: Thermal • Quality of heat; the value in temperature • Low-temperature extraction of heat from ground; ~70° F to 80° F • Water heating for home and business; ~90° F to 120° F • High-temperature process-heating water for industry; ~200° F to 400° F • Solar thermal power plants; ~1000° F or higher From www.energy.ca.gov/education/story/story-images/solar.jpeg Arizona has clearer skies than Florida. Ref.: Innovative Power Systems 100212

11.1.3.1.1 Flat-Plate Absorbers • Perforated black metal sheet leaks air in through slots, and a fan pushes/pushes hot air to desired area • Trombe Wall absorbs solar heat and stores it • Glass wall plus water barrels often used • Warmed air is slowly released into the building at night • Water heater with roof solar collector (I like mine) • Food dryers circulate warmed air over cut food to remove moisture and preserve it; dried fruit, etc. • Wood dryers “cure” green wood to reduce shrinkage after it is cut to size (manufactured) 090211

11.1.3.1.2 A Solar Wall Collector • This perforated black sheet metal is fastened directly to a building exterior • A small computer fan pulls outside air into the slots, it is warmed, and the air is pushed through a pipe to the interior of the building Photo by F. Leslie, 2003 Sustainable Living and Renewable Energy Fairat Ft. Collins CO, 2003 050210

11.1.3.1.3 Trombe Wall Collector • A Trombe wall has thermal mass placed behind a south wall of glass • Sometimes barrels filled with water are stacked in this space as a thermal storage capacitor • The air in this area is heated and then passes into the rest of the house • At night, the thermal inertia of the water-filled drums keeps heating the air • These areas are often used to grow plants in winter http://www.dal.ca/~arch/architecture/visitors/faculty/procos/solarhouse.htm 090211

11.1.3.1.4 Typical Water Heater • A small pump moves colder water into the collector whenever a controller senses that the panel is hotter than the tank • Electrical heating is used if there is no sunshine • The system shown adapts a conventional tank http://hem.dis.anl.gov/eehem/picts/93050710.gif 050210

11.1.3.2 Solar Water Heaters • Household Use • Rooftop; one or two panels about 3 ft x 10 ft • Rather standard appearance water tank, but has multiple water connections for collector in and out; more insulation • Pipes are cold in, hot out, collector in, and collector out • A temperature sensitive resistor is built in for control 10 kilohm thermistor • Ingenious designs allow a standard water heater tank to be used by tapping the safety thermostat port and the drain port • Industrial-grade Parabolic Heaters • Multiples of collectors used to achieve more Btus • Used at schools, prisons, or military bases 090211

11.1.3.2 Rooftop Heaters Thermosyphon units place the storage tank above the panels, and heated water rises into the tank. Cooler return water flows from the tank to the bottom of the collectors to enter at the cold end. No pump is needed to circulate the water. http://www.open.ac.uk/StudentWeb/t265/update/solar.htm 090211

11.1.3.2 Solar Ponds This El Paso solar pond is run by the Univ. of Texas • Fresh water floats on top of salt water • Solar heating of the brine raises its temperature to 85°C (185°F) • A Rankin Cycle engine turns a generator to drive the utility grid with up to 70 kW http://www.infinitepower.org/images/jspaerial.jpg http://www.solarpond.utep.edu/ 080205

11.1.4.1 Axicon Conical Reflector • A polished mirror cone reflects the sun onto a water-filled pipe and can boil the water • The surface of polished metal or foil is cheap to make and form • First used in the 1800s http://wg 090211

11.1.4.1 Solar Focusing Systems: Parabolic • Focuses parallel rays to a line • A black pipe is placed with its center at the focus • Pipe can be in a vacuum or could have a glass cover tube to reduce convection • Cylindrical reflector can be on one half of the vacuum tube and approximates the parabolic shape http://freespace.virgin.net/gareth.james/astro/alevel/parabolic.gif Y = 3/16 * X2 040208

11.1.4.2 Solar Focusing Systems: Paraboloidal • The focus at one spot is achieved by the parabolic cross-section • Flat mirror segments may be used to approximate the curve at much lower expense http://www.mellesgriot.com/glossary/wordlist/glossarydetails.asp?wID=186 050210

11.1.5.1 Solar Electricity Generation System (SEGS) • SEGS are a well developed design, and thus the systems may be reproduced and installed readily • FPL owns California plants in the Mohave Desert • There are ten SEGS in all http://www.ecobuild.info/renewable/solar/segs.jpg 090211

11.1.5.1 SEGS (Solar Electricity Generation System) • Luz International, an Israeli company, built these nine large systems in California • Luz went bankrupt in 1991, but the systems are still supplying power • Sunray Energy, Inc is an owner • FPL Energy Group is the owner of SEGS III through IX http://www.eere.energy.gov/troughnet/deployed.html engnet.anu.edu.au http://www.ecobuild.info/renewable/solar/segs.jpg 090211

11.1.5.1 Parabolic Trough Collectors • This large array shows the gaps needed to keep one row from shadowing the next row • Note the flexible pipe at this end that circulates the thermal oil regardless of the tilt angle • In the background is the control and engineering building www.me.washington.edu/~malte/engr342 090211

11.1.5.1 Parabolic Trough System Schematic www.me.washington.edu/~malte/engr342 • Natural gas is used to increase the temperature of the steam 090211

11.1.5.1 Eurotrough Reflector • The focus pipe has flexible pipes on the ends to allow rotary motion to track the sun, while the absorber pipe is kept at the heat focus http://www.eurotrough.com/downloads/EuroTroughPaperZurich2002_web.pdf 050210

11.1.5.1 Eurotrough Field Layout • Each pair of tubes forms a loopfrom the central manifolds • The power block is centrally located to minimize thermal losses • Oil is heated to ~500°C http://www.eurotrough.com/downloads/EuroTroughPaperZurich2002_web.pdf 050210

11.1.5.2.1 Solar Power Towers • Solar power towers were developed at Sandia, south of Albuquerque, New Mexico • Salt was melted by the focused heat • If the sun was blocked, the salt could harden in the pipes, requiring torches to get it flowing again • The heliostat mirrors are about ten feet square and mounted on the azimuth-elevation mounts (like a radar antenna mount) about 10 feet off the ground • The larger version with a full circle array, Solar One, was built near Barstow, CA • Water is used, but the system is being modified for molten salt http://www.sandia.gov/Renewable_Energy/solarthermal/NSTTF/question.htm 090211

11.1.5.2.2 Solar Power Towers: Sandia CRTF • Flat mirrors are aimed to focus sun at the receiver target to melt salt www.me.washington.edu/~malte/engr342 030215

11.1.4.2.3 Solar Power Towers: Sandia CRTF • The Receiver Tower has multiple target areas 5 MW power Flux to 280 W/cm2 Each heliostat is separately driven to focus its beam on the receiver Missile nosecones have been tested in the hot spot http://www.sandia.gov/Renewable_Energy/solarthermal/NSTTF/tower1.htm 030214

11.1.4.2.4 Solar Power Towers: Sandia CRTF • The large tank stores energy to use during cloud passage or at dusk • The output power is extracted at a constant rate http://www.sandia.gov/Renewable_Energy/solarthermal/NSTTF/feature.htm 090211

11.1.4.2.4 Solar Power Towers: Barstow CA • Flat mirrors are aimed to melt salt at the receiver target http://www.sandia.gov/Renewable_Energy/solarthermal/nsttf.html 030207

www.ecobuild.info/ renewable/solar/ 11.1.5.3 Solar Power Mirrors • Disks of thin aluminized mylar are pulled into rings under slight vacuum to form a paraboloidal surface www.me.washington.edu/~malte/engr342 050210

11.1.5.3.1 75 kW Solar Thermal Test Facility • These Sandia trackers have a paraboloidal dish surface similar to a radar antenna http://www.sandia.gov/Renewable_Energy/solarthermal/NSTTF/dishes.htm 050210

11.1.5.3.2 The Axicon Steam Generator Collins 1_29

11.1.5.3 Solar Path vs. Collector Weight and Size • The Sun’s changing position requires moving the focus during the day • Solar noon elevation changes annually as the sun declination angle changes • Massive structures require high power to move them • The STTF has 11-meter reflectors • Lighter components can move sun’s image • Structures have a lot of sail area, and high winds could damage the reflectors • Reflectors are moved to a vertical stow position that minimizes wind torques when weather warnings arise 090211

11.1.6 Balance of System (BOS) • You need all this other stuff to make it work! • Heat exchangers, boilers • Circulating pumps for the heat fluid • Heat storage tanks, special thermal oils • Automated controls • Natural gas peaking for steam high temperature • Rotary expanders (positive displacement steam motors) can substitute for a turbine • Wash truck and sprayer to clean the desert dust off the mirrors 090211

11.1.7.1 Food Dryers • Heated air passes over the food  drying the moisture and preserving it • Separate trays allow keeping fruits or nuts of the same dryness together for processing http://www.arc.agric.za/institutes/ili/main/publications/dryer.htm • The glass or plastic top allows sunlight in but reflects infrared energy back onto the food • The food is in the thick end of the box http://www.avinsolar.com/dryer.htm 060205

11.1.7.2.1 Solar Coffee Bean Dryers • Coffee is normally dried on open tables in the sun • These solar dryers were built to speed the process • Heat retention increases the inside air temperature • Materials are inexpensive and local workers can build the driers http://www.resource-solutions.org/GGIfcoffeegallery.htm 050210

11.1.7.2.2 Solar Coffee Bean Roaster • The Solar Roast coffee company built and uses this segmented mirror to heat the receiver and roast the coffee (incredibly expensive) • Roasting coffee beans sound like popcorn popping • They will move from Oregon to Southern Colorado for more sun and year-around operation • Find out more at www.solarroast.com or their ad in Home Power magazine • (not a paid announcement!) http://www.solarroast.com/news.html 090211

11.1.7.3 A Traditional Sun Cooker This cooker at the 2003 Ft. Collins CO Sustainable Living Fair was in too shady a location to work The polished aluminum wings provide more reflected light energy into the box to increase the temperature to about 270 ºF 090211

11.1.7.4 A Paraboloidal Sun Cooker The black pot suspended at the focus can be moved on and off for loading and serving The mount allows vertical shifts while the entire unit is turned to track the sun The mirror is made of segments to approximate a paraboloid http://www.cuisinesolaire.com/F/cuiseurs.htm 090211

11.1.7.4.1 A Paraboloidal Solar Cooker This massive servotracker unit was originally developed at Sandia and later given to the local Renewable Energy Society An oven area at the back can cook three pans of cookies A twin unit was shown at the 2004 MREA Fair in WI Photo by F. Leslie, 2003 The segments approximate a paraboloidal 060205

11.1.7.4.3 Making Solar Pancakes A whimsical way to make money at a European renewable energy fair! Solar pancakes from two reflectors that are offset sections of a paraboloid http://www.cuisinesolaire.com/E/Benicarlo.htm 090211

11.1.8 Advantages and Disadvantages • Solar thermal systems work efficiently at lower temperatures since cheap flat collectors can work economically • Reflecting systems need broad acceptance angles so that the optics don’t cost too much • The beam need only strike the absorber, not form a picture image (noncoherent) • Reflectors must be kept clean by frequent washing • Reflectors wouldn’t be wise in hailstorm country! • Could be protected by a quickly erected tarp 090211

11.1 Conclusion: Solar Thermal • Solar thermal systems are cost effective at low temperatures for water heating or cooking • Water heaters are energy savers, but initial cost dissuades many from using them • Power tower electricity cost is at $6/W peak, too high to compete with PV power • Massive power tower yields 10 MWe, while a typical utility plant is 500-1500 MWe • Power towers aren’t likely to be economically practical for some time • Solar dryers, cookers, and ovens are relatively inexpensive and available for remote cooking • Backpack versions are sold for camping 090211

Questions? Olin Engineering Complex 4.7 kW Solar PV Roof Array 080116

References: Books • Brower, Michael. Cool Energy. Cambridge MA: The MIT Press, 1992. 0-262-02349-0, TJ807.9.U6B76, 333.79’4’0973. • Duffie, John and William A. Beckman. Solar Engineering of Thermal Processes. NY: John Wiley & Sons, Inc., 920 pp., 1991 • Patel, Mukund R. Wind and Solar Power Systems. Boca Raton: CRC Press, 1999, 351 pp. ISBN 0-8493-1605-7, TK1541.P38 1999, 621.31’2136 • Sørensen, Bent. Renewable Energy, Second Edition. San Diego: Academic Press, 2000, 911 pp. ISBN 0-12-656152-4. 030202

References: Websites, etc. www.me.washington.edu/~malte/engr342 Excellent site! www.doe.gov www.sandia.org www.nrel.doe.gov http://solarcooking.org/ http://home.earthlink.net/~drduggee/solar.htm http://journeytoforever.org/sc.html http://dir.yahoo.com/Society_and_Culture/Food_and_Drink/Cooking/Cooking_Techniques/Solar_Cooking/ http://www.nal.usda.gov/afsic/AFSIC_pubs/qb9606.htmhttp://peswiki.com/energy/Main_Page http://www.solar2006.org/presentations/tech_sessions/t33-a166.pdf ___________________________________________________________________ www.dieoff.org. Site devoted to the decline of energy and effects upon population www.ferc.gov/ Federal Energy Regulatory Commission www.google.com/search?q=%22renewable+energy+course%22 solstice.crest.org/ dataweb.usbr.gov/html/powerplant_selection.html 080206

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11.1 Solar Thermal Energy

11.1 Solar Thermal Energy

Presentation Transcript

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