Solar mirror

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A solar mirror in the Solar Collector Laboratory at Lewis Research Center, November 1966 Solar Mirror - GPN-2000-001455.jpg
A solar mirror in the Solar Collector Laboratory at Lewis Research Center, November 1966

A solar mirror contains a substrate with a reflective layer for reflecting the solar energy, and in most cases an interference layer. This may be a planar mirror or parabolic arrays of solar mirrors used to achieve a substantially concentrated reflection factor for solar energy systems.

Contents

See article "Heliostat" for more information on solar mirrors used for terrestrial energy.

Components

Glass or metal substrate

The substrate is the mechanical layer which holds the mirror in shape.

Glass may also be used as a protective layer to protect the other layers from abrasion and corrosion. Although glass is brittle, it is a good material for this purpose, because it is highly transparent (low optical losses), resistant to ultraviolet light (UV), fairly hard (abrasion resistant), chemically inert, and fairly easy to clean. It is composed of a float glass with high optical transmission characteristics in the visible and infrared ranges, and is configured to transmit visible light and infrared radiation. The top surface, known as the "first surface", will reflect some of the incident solar energy, due to the reflection coefficient caused by its index of refraction being higher than air. Most of the solar energy is transmitted through the glass substrate to the lower layers of the mirror, possibly with some refraction, depending on the angle of incidence as light enters the mirror.

Metal substrates ("Metal Mirror Reflectors") may also be used in solar reflectors. NASA Glenn Research Center, for example, used a mirror comprising a reflective aluminum surface on a metallic honeycomb [1] as a prototype reflector unit for a proposed power system for the International Space Station. One technology uses aluminum composite reflector panels, achieving over 93% reflectivity and coated with a speciality coating for surface protection. Metal reflectors offer some advantages over glass reflectors, as they are lightweight and stronger than glass and relatively inexpensive. The ability to retain parabolic shape in reflectors is another advantage, and normally the subframe requirements are reduced by more than 300%. The top surface reflection coating allows for better efficiency.

Reflective layer

The reflective layer is designed to reflect the maximum amount of solar energy incident upon it, back through the glass substrate. The layer comprises a highly reflective thin metal film, usually either silver or aluminum, but occasionally other metals. Because of sensitivity to abrasion and corrosion, the metal layer is usually protected by the (glass) substrate on top, and the bottom may be covered with a protective coating, such as a copper layer and varnish.

Despite the use of aluminum in generic mirrors, aluminum is not always used as the reflective layer for a solar mirror. The use of silver as the reflective layer is claimed to lead to higher efficiency levels, because it is the most reflective metal. This is because of aluminum's reflection factor in the UV region of the spectrum.[ citation needed ] Locating the aluminum layer on the first surface exposes it to weathering, which reduces the mirror's resistance to corrosion and makes it more susceptible to abrasion. Adding a protective layer to the aluminum would reduce its reflectivity.

Interference layer

An interference layer may be located on the first surface of the glass substrate. [2] It can be used to tailor the reflectance. It may also be designed for diffuse reflectance of near-ultraviolet radiation, in order to prevent it from passing through the glass substrate. This substantially enhances the overall reflection of near-ultraviolet radiation from the mirror. The interference layer may be made of several materials, depending on the desired refractive index, such as titanium dioxide.

Passive mirror cooling applications

The use of solar mirrors as a form of passive daytime radiative cooling for solar radiation management has been proposed to address local temperature increases as well as to decrease global warming. [3] Propositions have focused on the usage of solar mirrors both on the Earth's surface and in space.

Terrestrial applications

Passive mirror cooling systems reduce temperatures by reflecting solar radiation while shielding the base of the mirrors from heat penetration. [4] The effectiveness of such systems may be reduced with the accumulation of dust on mirrors, with maximum dust accumulation reducing mirror effectiveness by 63%. However, mirrors may be "self-cleaned" by rain (reducing the soiling rate to 18.6%) or cleaned by humans. [5]

On a local scale, passive mirror cooling systems have been implemented to lower the energy consumption used to cool residential and commercial buildings and thus offset the need for air-conditioning. [3] When passive mirrored surfaces are placed on roofs, they have been shown to reduce electricity consumption and costs for cooling, with one case study reducing costs by 15%. [6]

While the use of solar mirrors as a form of solar radiation management on a global scale has been proposed, more data and funding is required. Increasing awareness of passive radiative cooling's potential to lower costs as well as its role in reducing solar radiation may increase applications. [6] Researchers who support passive mirror cooling applications on a mass scale, such as Ye Tao of MEER, argue that carbon dioxide removal alone will not work fast enough to prevent global temperature increases from surpassing life-threatening levels. [7]

Space-based applications

Solar thermal applications

The intensity of solar thermal energy from solar radiation at the surface of the earth is about 1 kilowatt per square metre (0.093 kW/sq ft), of area normal to the direction of the sun, under clear-sky conditions. When solar energy is unconcentrated, the maximum collector temperature is about 80–100 °C (176–212 °F). This is useful for space heating and heating water. For higher temperature applications, such as cooking, or supplying a heat engine or turbine-electrical generator, this energy must be concentrated.

Terrestrial applications

Solar thermal systems have been constructed to produce concentrated solar power (CSP), for generating electricity. [8] [9] The large Sandia Lab solar power tower uses a Stirling engine heated by a solar mirror concentrator. [10] Another configuration is the trough system. [11]

Space power application

"Solar dynamic" energy systems have been proposed for various spacecraft applications, including solar power satellites, where a reflector focuses sunlight on to a heat engine such as the Brayton cycle type. [12]

Photovoltaic augmentation

Photovoltaic cells (PV) which can convert solar radiation directly into electricity are quite expensive per unit area. Some types of PV cell, e.g. gallium arsenide, if cooled, are capable of converting efficiently up to 1,000 times as much radiation as is normally provided by simple exposure to direct sunlight.

In tests done by Sewang Yoon and Vahan Garboushian, for Amonix Corp. [13] silicon solar cell conversion efficiency is shown to increase at higher levels of concentration, proportional to the logarithm of the concentration, provided external cooling is available to the photocells. Similarly, higher efficiency multijunction cells also improve in performance with high concentration. [14]

Terrestrial application

To date no large scale testing has been performed on this concept. Presumably this is because the increased cost of the reflectors and cooling generally is not economically justified.

Solar power satellite application

Theoretically, for space-based solar power satellite designs, solar mirrors could reduce PV cell costs and launch costs since they are expected to be both lighter and cheaper than equivalent large areas of PV cells. Several options were studied by Boeing corporation. [15] In their Fig. 4. captioned "Architecture 4. GEO Harris Wheel", the authors describe a system of solar mirrors used to augment the power of some nearby solar collectors, from which the power is then transmitted to receiver stations on earth.

Space reflectors for night illumination

Another advanced space concept proposal is the notion of space reflectors which reflect sunlight on to small spots on the night side of the Earth to provide night time illumination. An early proponent of this concept was Dr. Krafft Arnold Ehricke, who wrote about systems called "Lunetta", "Soletta", "Biosoletta" and "Powersoletta". [16] [17]

A preliminary series of experiments called Znamya ("Banner") was performed by Russia, using solar sail prototypes that had been repurposed as mirrors. Znamya-1 was a ground test. Znamya-2 was launched aboard the Progress M-15 resupply mission to the Mir space station on 27 October 1992. After undocked from Mir, the Progress deployed the reflector. [18] [19] This mission was successful in that the mirror deployed, although it did not illuminate the Earth.[ citation needed ] The next flight Znamya-2.5 failed. [20] [21] Znamya-3 never flew.

In 2018, Chengdu, China, announced plans to place three solar reflectors in orbit around the Earth in hopes of reducing the amount of electricity required to power streetlights. [22] Skepticism has been voiced regarding the technological feasibility of the plan. [23]

See also

Related Research Articles

A Trombe wall is a massive equator-facing wall that is painted a dark color in order to absorb thermal energy from incident sunlight and covered with a glass on the outside with an insulating air-gap between the wall and the glaze. A Trombe wall is a passive solar building design strategy that adopts the concept of indirect-gain, where sunlight first strikes a solar energy collection surface which covers thermal mass located between the Sun and the space. The sunlight absorbed by the mass is converted to thermal energy (heat) and then transferred into the living space.

<span class="mw-page-title-main">Passive solar building design</span> Architectural engineering that uses the Suns heat without electric or mechanical systems

In passive solar building design, windows, walls, and floors are made to collect, store, reflect, and distribute solar energy, in the form of heat in the winter and reject solar heat in the summer. This is called passive solar design because, unlike active solar heating systems, it does not involve the use of mechanical and electrical devices.

<span class="mw-page-title-main">Radiative cooling</span> Loss of heat by thermal radiation

In the study of heat transfer, radiative cooling is the process by which a body loses heat by thermal radiation. As Planck's law describes, every physical body spontaneously and continuously emits electromagnetic radiation.

<span class="mw-page-title-main">Solar thermal energy</span> Technology using sunlight for heat

Solar thermal energy (STE) is a form of energy and a technology for harnessing solar energy to generate thermal energy for use in industry, and in the residential and commercial sectors.

<span class="mw-page-title-main">Radiant barrier</span>

A radiant barrier is a type of building material that reflects thermal radiation and reduces heat transfer. Because thermal energy is also transferred by conduction and convection, in addition radiation, radiant barriers are often supplemented with thermal insulation that slows down heat transfer by conduction or convection.

<span class="mw-page-title-main">Selective surface</span> Ordinary surfaces re-radiate heat they absorb. Selective ones re-radiate only a little.

In solar thermal collectors, a selective surface or selective absorber is a means of increasing its operation temperature and/or efficiency. The selectivity is defined as the ratio of solar radiation absorption (αsol) to thermal infrared radiation emission (εtherm).

<span class="mw-page-title-main">Solar thermal collector</span> Device that collects heat

A solar thermal collector collects heat by absorbing sunlight. The term "solar collector" commonly refers to a device for solar hot water heating, but may refer to large power generating installations such as solar parabolic troughs and solar towers or non water heating devices such as solar cooker, solar air heaters.

Silvering is the chemical process of coating a non-conductive substrate such as glass with a reflective substance, to produce a mirror. While the metal is often silver, the term is used for the application of any reflective metal.

Low emissivity refers to a surface condition that emits low levels of radiant thermal (heat) energy. All materials absorb, reflect, and emit radiant energy according to Planck's law but here, the primary concern is a special wavelength interval of radiant energy, namely thermal radiation of materials. In common use, especially building applications, the temperature range of approximately -40 to +80 degrees Celsius is the focus, but in aerospace and industrial process engineering, much broader ranges are of practical concern.

Thermophotovoltaic (TPV) energy conversion is a direct conversion process from heat to electricity via photons. A basic thermophotovoltaic system consists of a hot object emitting thermal radiation and a photovoltaic cell similar to a solar cell but tuned to the spectrum being admitted from the hot object.

<span class="mw-page-title-main">Infrared heater</span> Device designed to create radiative heat

An infrared heater or heat lamp is a heating appliance containing a high-temperature emitter that transfers energy to a cooler object through electromagnetic radiation. Depending on the temperature of the emitter, the wavelength of the peak of the infrared radiation ranges from 750 nm to 1 mm. No contact or medium between the emitter and cool object is needed for the energy transfer. Infrared heaters can be operated in vacuum or atmosphere.

<span class="mw-page-title-main">Thermal management of high-power LEDs</span>

High power light-emitting diodes (LEDs) can use 350 milliwatts or more in a single LED. Most of the electricity in an LED becomes heat rather than light. If this heat is not removed, the LEDs run at high temperatures, which not only lowers their efficiency, but also makes the LED less reliable. Thus, thermal management of high power LEDs is a crucial area of research and development. It is necessary to limit both the junction and the phosphor particles temperatures to a value that will guarantee the desired LED lifetime.

<span class="mw-page-title-main">Thin-film solar cell</span> Type of second-generation solar cell

A thin-film solar cell is a second generation solar cell that is made by depositing one or more thin layers, or thin film (TF) of photovoltaic material on a substrate, such as glass, plastic or metal. Thin-film solar cells are commercially used in several technologies, including cadmium telluride (CdTe), copper indium gallium diselenide (CIGS), and amorphous thin-film silicon.

Space mirrors are satellites that are designed to change the amount of solar radiation that impacts the Earth as a form of climate engineering. Since the conception of the idea in the 1980s, space mirrors have mainly been theorized as a way to deflect sunlight to counter global warming and was seriously considered in the 2000s.

<span class="mw-page-title-main">Crystalline silicon</span>

Crystalline silicon or (c-Si) Is the crystalline forms of silicon, either polycrystalline silicon, or monocrystalline silicon. Crystalline silicon is the dominant semiconducting material used in photovoltaic technology for the production of solar cells. These cells are assembled into solar panels as part of a photovoltaic system to generate solar power from sunlight.

<span class="mw-page-title-main">Solar-cell efficiency</span> Ratio of energy extracted from sunlight in solar cells

Solar-cell efficiency refers to the portion of energy in the form of sunlight that can be converted via photovoltaics into electricity by the solar cell.

<span class="mw-page-title-main">Spacecraft thermal control</span> Process of keeping all parts of a spacecraft within acceptable temperature ranges

In spacecraft design, the function of the thermal control system (TCS) is to keep all the spacecraft's component systems within acceptable temperature ranges during all mission phases. It must cope with the external environment, which can vary in a wide range as the spacecraft is exposed to the extreme coldness found in the shadows of deep space or to the intense heat found in the unfiltered direct sunlight of outer space. A TCS must also moderate the internal heat generated by the operation of the spacecraft it serves. A TCS can eject heat passively through the simple and natural infrared radiation of the spacecraft itself, or actively through an externally mounted infrared radiation coil.

Solar energy – radiant light and heat from the sun. It has been harnessed by humans since ancient times using a range of ever-evolving technologies. Solar energy technologies include solar heating, solar photovoltaics, solar thermal electricity and solar architecture, which can make considerable contributions to solving some of the most urgent problems that the world now faces.

<span class="mw-page-title-main">Concentrated photovoltaic thermal system</span>

The combination of photovoltaic (PV) technology, solar thermal technology, and reflective or refractive solar concentrators has been a highly appealing option for developers and researchers since the late 1970s and early 1980s. The result is what is known as a concentrated photovoltaic thermal (CPVT) system which is a hybrid combination of concentrated photovoltaic (CPV) and photovoltaic thermal (PVT) systems.

<span class="mw-page-title-main">Passive daytime radiative cooling</span> Management strategy for global warming

Passive daytime radiative cooling (PDRC) is a renewable cooling method proposed as a solution to global warming of enhancing terrestrial heat flow to outer space through the installation of thermally-emissive surfaces on Earth that require zero energy consumption or pollution. Because all materials in nature absorb more heat during the day than at night, PDRC surfaces are designed to be high in solar reflectance and strong in longwave infrared (LWIR) thermal radiation heat transfer through the atmosphere's infrared window to cool temperatures during the daytime. It is also referred to as passive radiative cooling (PRC), daytime passive radiative cooling (DPRC), radiative sky cooling (RSC), photonic radiative cooling, and terrestrial radiative cooling. PDRC differs from solar radiation management because it increases radiative heat emission rather than merely reflecting the absorption of solar radiation.

References

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  4. Leonov, E; Chernykh, A; Shanin, Yu (2021). "Heat transfer in laser passive and deformable mirrors". Journal of Physics: Conference Series. 2088: 012042. doi: 10.1088/1742-6596/2088/1/012042 . S2CID   244571579.
  5. El boujdaini, Latifa; Merzrhab, Ahmed; Amine Moussaoui, Mohammed; Antonio Carballo Lopez, Jose; Wolfertstetter, Fabian (October 2022). "The effect of soiling on the performance of solar mirror materials: Experimentation and modeling". Sustainable Energy Technologies and Assessments. 53 (C) via Elsevier.
  6. 1 2 Lim, XiaoZhi (31 December 2019). "The super-cool materials that send heat to space". Nature.
  7. Dana, Joe (20 June 2022). "A nonprofit is using mirrors as a climate solution to a heating planet. Could MEER be in Arizona's future?". 12News. Retrieved 21 September 2022.
  8. Sandia Labs - CSP Technologies Overview
  9. PowerTower The large design developed by Sandia National Labs Archived 2004-11-17 at the Wayback Machine
  10. Sandia Lab - Solar Dish Engine Archived 2004-11-17 at the Wayback Machine
  11. Sandia Lab - Trough System Archived 2004-10-28 at the Wayback Machine
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  16. Ehricke, Krafft Arnold (September 1–4, 1999). "Power Soletta: An industrial sun for Europe - Possibilities for an economically feasible supply with solar energy". Raumfahrtkongress, 26th (in German). Vol. 14. Berlin, West Germany: Hermann-Oberth-Gesellschaft. pp. 85–87. Bibcode:1977hogr...14...85E.
  17. Ehricke, Krafft Arnold (January–February 1978). "The Extraterrestrial Imperative". Air University Review. United States Air Force. XXIX (2). Retrieved 2007-02-25.
  18. McDowell, Jonathan (1993-02-10). "Jonathan's Space Report - No 143 - Mir". Jonathan's Space Report . Jonathan McDowell. Retrieved 2007-02-25.
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  22. Xiao, Bang (2018-10-18). "China plans to launch artificial moon bright enough to replace streetlights by 2020". ABC News. Retrieved 2019-10-04.
  23. Friday, Nathaniel Scharping | Published; October 26; 2018. "Why China's artificial moon probably won't work". Astronomy.com. Retrieved 2020-09-18.{{cite web}}: CS1 maint: numeric names: authors list (link)
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