This week has been unusually hectic.
I had to spend a lot of time working on a resume for the first half of the week, since I'm hoping to get a job over the summer. Then I got my college decisions from Rice and Columbia, both of which denied me, so it looks like I'll be going to ASU in the fall (which I don't mind). Other than that I had to fully convert two days worth of experiments into only a few spread sheets on Monday, which took all day. All in all, I've had little time this week for supplementary research.
However, I have begun working on an outline for the paper that will be the "final product" of this project! With a few more hours of work I hope to have it all finished up and I'll be posting it here!
Congratulations to all of my classmates for the college acceptances! I hope you guys have a good time where ever you decide to go!
Friday, March 28, 2014
Friday, March 21, 2014
Thermal Energy Storage
As mentioned previously, one of the advantages of solar thermal energy collection is that the energy collected can be more easily stored. This is advantageous because it allows solar thermal power plants to store energy during the day so that it may later be used during hours of peak energy usage, the night, and on cloudy days.
Thermal energy can be stored in many different ways. Many home systems simply use water as a means of storage. The advantages of this comes from water's high specific heat, meaning that it is more difficult for water to gain and lose thermal energy. In an insulated container, hot water can be collected in the summer, and used in the winter to heat a house. However, water is limited in that it can only be heated to 100 degrees Celsius. Because of this, some systems use solids like rocks, concrete, or iron to store thermal energy. These solids are often immersed in water or synthetic oil and kept inside an insulated chamber. While solids have a lower specific heat than water, they can reach much higher temperatures. For Solar Thermal plants, the heat transfer fluid itself can be used to store thermal energy by keeping hot heat transfer fluid in an insulated tank.
sources:
Glatzmair G. Summary Report for Concentrating Solar Power Thermal Workshop. Rep. no. NREL/TP-5500-52134. Washington D.C.: US. Dept. of Energy, 2011. Print.
Chen, C. Julian. Physics of Solar Energy. Hoboken, NJ: Wiley, 2011. Print
Dinçer, İbrahim, and Marc Rosen. Thermal Energy Storage: Systems and Applications. Chichester: Wiley, 2011. Print.
Thermal energy can be stored in many different ways. Many home systems simply use water as a means of storage. The advantages of this comes from water's high specific heat, meaning that it is more difficult for water to gain and lose thermal energy. In an insulated container, hot water can be collected in the summer, and used in the winter to heat a house. However, water is limited in that it can only be heated to 100 degrees Celsius. Because of this, some systems use solids like rocks, concrete, or iron to store thermal energy. These solids are often immersed in water or synthetic oil and kept inside an insulated chamber. While solids have a lower specific heat than water, they can reach much higher temperatures. For Solar Thermal plants, the heat transfer fluid itself can be used to store thermal energy by keeping hot heat transfer fluid in an insulated tank.
sources:
Glatzmair G. Summary Report for Concentrating Solar Power Thermal Workshop. Rep. no. NREL/TP-5500-52134. Washington D.C.: US. Dept. of Energy, 2011. Print.
Chen, C. Julian. Physics of Solar Energy. Hoboken, NJ: Wiley, 2011. Print
Dinçer, İbrahim, and Marc Rosen. Thermal Energy Storage: Systems and Applications. Chichester: Wiley, 2011. Print.
Monday, March 10, 2014
They can't all be scientists...
For the past month, my bicycle has been an important part of my commute to the lab at the University (drive to a friends house, bike the rest of the way). Guess what happened today? The bicycle chain broke! Terrific! Wonderful! Applause!
It was probably my fault for riding around slowly on high gear, I was giving Joyce a ride home today so I was basically walking when it happened. For the rest of the way, about 2/3 of the leg I had to walk my bike while the pedals rolled around freely by their own momentum, frequently fitting my leg causing me great annoyance and misery. Joyce is probably going to talk about this too, and now theres a video of me uselessly trying to use the pedals somewhere in the internet.
They can't all be scientists, next weeks post will be cool and sciency and relevant.
P.S. Someone know how to fix a bicycle chain?
It was probably my fault for riding around slowly on high gear, I was giving Joyce a ride home today so I was basically walking when it happened. For the rest of the way, about 2/3 of the leg I had to walk my bike while the pedals rolled around freely by their own momentum, frequently fitting my leg causing me great annoyance and misery. Joyce is probably going to talk about this too, and now theres a video of me uselessly trying to use the pedals somewhere in the internet.
They can't all be scientists, next weeks post will be cool and sciency and relevant.
P.S. Someone know how to fix a bicycle chain?
Monday, March 3, 2014
So, whats this all for again?
As cool as the lab work is, its meaningless without the context of what its ultimately being used for and the overall subject of this project, Solar thermal energy. Solar thermal energy collection comes in many forms, from solar ovens, solar water heaters, to solar thermal power plants, but all of them follow the basic principle of converting solar energy to thermal energy to eventually perform work.
The project is mostly concerned with the large scale solar thermal power plants. At such a large scale, almost all solar thermal power plants rely in some way on the concentration of solar energy to achieve maximum efficiency. Two of the most common ways are doing this are solar power towers and parabolic trough collectors. Solar power towers, also known as heliostats, use a massive field of mirrors to focus sunlight to the top of a tower in the center of the field, where as parabolic trough collectors use lines of parabolic mirrors to focus sunlight along a line that runs along them. The sunlight collected from all solar thermal power plants is used to heat a so called "heat transfer fluid" (HTF) to temperatures ranging from 400 degrees Celsius to 600 degrees Celsius. This HTF is then pumped to a heat exchange where the heat is transferred to water, creating steam to spin turbines like other fossil fuel based power power plants. While the conversion of solar energy to thermal energy of the HTF is very efficient, the second part of the process, the transfer of heat from HTF to water is not. This inefficiency is a major factor contributing to the high price of solar thermal power generation. The graph below shows how the efficiency of solar thermal power plants is dependent on the temperature at which they operate.
However, solar thermal power generation is promising because it allows energy to be stored in the form of thermal energy, allowing electricity to be generated during the night and while intermittent clouds are over head. There are many ways to store this thermal energy (which I need to research more), but the freezing of HTF must be avoided, which currently occurs at temperatures higher than room temperature.
Therefore, the development of better HTFs will both mitigate the limitations and heighten the advantages of solar thermal power generation. At temperatures approaching 1000 degrees Celsius, the efficiency of the heat transfer between HTF and water increases dramatically. At such high temperatures, heat transfer by radiation can be considered, potentially increasing the efficiency further. At higher temperatures, heat transfer fluid can be stored for longer periods of time, and research is being conducted to find a HTF that can remain liquid at lower temperatures, making it easier to store. The lab work that I am involved with is trying to develop these new HTFs and quantify the radiative properties of the fluid.
Citation
Glatzmair G. Summary Report for Concentrating Solar Power Thermal Workshop. Rep. no. NREL/TP-5500-52134. Washington D.C.: US. Dept. of Energy, 2011. Print.
The project is mostly concerned with the large scale solar thermal power plants. At such a large scale, almost all solar thermal power plants rely in some way on the concentration of solar energy to achieve maximum efficiency. Two of the most common ways are doing this are solar power towers and parabolic trough collectors. Solar power towers, also known as heliostats, use a massive field of mirrors to focus sunlight to the top of a tower in the center of the field, where as parabolic trough collectors use lines of parabolic mirrors to focus sunlight along a line that runs along them. The sunlight collected from all solar thermal power plants is used to heat a so called "heat transfer fluid" (HTF) to temperatures ranging from 400 degrees Celsius to 600 degrees Celsius. This HTF is then pumped to a heat exchange where the heat is transferred to water, creating steam to spin turbines like other fossil fuel based power power plants. While the conversion of solar energy to thermal energy of the HTF is very efficient, the second part of the process, the transfer of heat from HTF to water is not. This inefficiency is a major factor contributing to the high price of solar thermal power generation. The graph below shows how the efficiency of solar thermal power plants is dependent on the temperature at which they operate.
However, solar thermal power generation is promising because it allows energy to be stored in the form of thermal energy, allowing electricity to be generated during the night and while intermittent clouds are over head. There are many ways to store this thermal energy (which I need to research more), but the freezing of HTF must be avoided, which currently occurs at temperatures higher than room temperature.
Therefore, the development of better HTFs will both mitigate the limitations and heighten the advantages of solar thermal power generation. At temperatures approaching 1000 degrees Celsius, the efficiency of the heat transfer between HTF and water increases dramatically. At such high temperatures, heat transfer by radiation can be considered, potentially increasing the efficiency further. At higher temperatures, heat transfer fluid can be stored for longer periods of time, and research is being conducted to find a HTF that can remain liquid at lower temperatures, making it easier to store. The lab work that I am involved with is trying to develop these new HTFs and quantify the radiative properties of the fluid.
Citation
Glatzmair G. Summary Report for Concentrating Solar Power Thermal Workshop. Rep. no. NREL/TP-5500-52134. Washington D.C.: US. Dept. of Energy, 2011. Print.
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