Canadienito (talk | contribs) No edit summary |
Canadienito (talk | contribs) No edit summary |
||
| Line 24: | Line 24: | ||
*Second, and perhaps imperatively, the potential to displace the ecological and social externalities associated with [[http://en.wikipedia.org/wiki/Water_heating conventional methods for heating water]] in the more affluent and developed regions on the planet where there is a path dependency to use hot water regularly and in abundance, even for such luxuries as long, hot showers, clothes washing and heated tubs and pools is extremely important for many SDHW applications are cost-effective and available and thus there could be a significant reduction in the size of a regions Ecological Footprint associated with conventional means of heating water (site Wiki for conventional hot water). | *Second, and perhaps imperatively, the potential to displace the ecological and social externalities associated with [[http://en.wikipedia.org/wiki/Water_heating conventional methods for heating water]] in the more affluent and developed regions on the planet where there is a path dependency to use hot water regularly and in abundance, even for such luxuries as long, hot showers, clothes washing and heated tubs and pools is extremely important for many SDHW applications are cost-effective and available and thus there could be a significant reduction in the size of a regions Ecological Footprint associated with conventional means of heating water (site Wiki for conventional hot water). | ||
==Energy from the Sun== | |||
Solar radiation reaches the Earth's upper atmosphere at a rate of 1366 watts per square meter (W/m2).[1] The first map shows how the solar energy varies in different latitudes. | |||
While traveling through the atmosphere, 6% of the incoming solar radiation (insolation) is reflected and 16% is absorbed resulting in a peak irradiance at the equator of 1,020 W/m².[2] Average atmospheric conditions (clouds, dust, pollutants) further reduce insolation by 20% through reflection and 3% through absorption.[3] Atmospheric conditions not only reduce the quantity of insolation reaching the Earth's surface but also affect the quality of insolation by diffusing incoming light and altering its spectrum. | |||
The second map shows the average global irradiance calculated from satellite data collected from 1991 to 1993. For example, in North America the average insolation at ground level over an entire year (including nights and periods of cloudy weather) lies between 125 and 375 W/m² (3 to 9 kWh/m²/day).[4] This represents the available power, and not the delivered power. At present, photovoltaic panels typically convert about 15% of incident sunlight into electricity; therefore, a solar panel in the contiguous United States on average delivers 19 to 56 W/m² or 0.45 - 1.35 kWh/m²/day.[5] | |||
The dark disks in the third map on the right are an example of the land areas that, if covered with 8% efficient solar panels, would produce slightly more energy in the form of electricity than the total world primary energy supply in 2003.[6] While average insolation and power offer insight into solar power's potential on a regional scale, locally relevant conditions are of primary importance to the potential of a specific site. | |||
After passing through the Earth's atmosphere, most of the sun's energy is in the form of visible and infrared radiation. Plants use solar energy to create chemical energy through photosynthesis. Humans regularly use this energy burning wood or fossil fuels, or when simply eating the plants. | |||
A recent concern is global dimming, an effect of pollution that is allowing less sunlight to reach the Earth's surface. It is intricately linked with pollution particles and global warming, and it is mostly of concern for issues of global climate change, but is also of concern to proponents of solar power because of the existing and potential future decreases in available solar energy. The order of magnitude is about 4% less solar energy available at sea level over the timeframe of 1961–90, mostly from increased reflection from clouds back into space.[7] | |||
==Appropriate Techology== | ==Appropriate Techology== | ||
Revision as of 00:33, 9 August 2007
Introduction
Solar Hot Water describes active and passive solar technologies that utilize the sun’s freely abundant solar thermal energy in order to heat water for a desired application.
If you have ever felt hot water trickle out of a garden hose that’s been sitting in the sun, you’ve experienced solar hot water in action.
Essentially, a solar hot water system is made up of a solar thermal collector’, a well-insulated storage container, and a system for transferring the heat from the collector to the container vis-à-vis a fluid medium, which in some circumstances is the water to be used itself.
Applications
Being as there are on a global scale near countless applications using domestic, commercial and industrial hot water, there are also many opportunities to apply solar thermal technologies to heat this water. Solar hot water is not a new phenomena and was in fact widely used in the United State up into about the 1920's when cost-effective and consistent hot water systems using gas or electricity moved the technology towards it current position in the market.
But today the market is changing, and both the economic and environmental costs associated with using gas and electricity to heat water is being challenged by both more efficient, less costly conventional systems
Background
Hot water is considered by some to have less application in the field of appropriate technology and to mostly be a luxury afforded the developed world. One text on the subjects suggests that what hot water is needed in the "3rd World" can be heated using a fuel such wood while simultaneously heating their home. Such dismissals are dangerous on two counts:
- First, if appropriate technology is at all concerned with reducing waste and increasing efficiency in use of precious natural resources then there appear to be many opportunities to do so using solar thermal energy and technologies that utilize itin the context of sustainable development for 1st, 2nd or 3rd.
- Second, and perhaps imperatively, the potential to displace the ecological and social externalities associated with [conventional methods for heating water] in the more affluent and developed regions on the planet where there is a path dependency to use hot water regularly and in abundance, even for such luxuries as long, hot showers, clothes washing and heated tubs and pools is extremely important for many SDHW applications are cost-effective and available and thus there could be a significant reduction in the size of a regions Ecological Footprint associated with conventional means of heating water (site Wiki for conventional hot water).
Energy from the Sun
Solar radiation reaches the Earth's upper atmosphere at a rate of 1366 watts per square meter (W/m2).[1] The first map shows how the solar energy varies in different latitudes.
While traveling through the atmosphere, 6% of the incoming solar radiation (insolation) is reflected and 16% is absorbed resulting in a peak irradiance at the equator of 1,020 W/m².[2] Average atmospheric conditions (clouds, dust, pollutants) further reduce insolation by 20% through reflection and 3% through absorption.[3] Atmospheric conditions not only reduce the quantity of insolation reaching the Earth's surface but also affect the quality of insolation by diffusing incoming light and altering its spectrum.
The second map shows the average global irradiance calculated from satellite data collected from 1991 to 1993. For example, in North America the average insolation at ground level over an entire year (including nights and periods of cloudy weather) lies between 125 and 375 W/m² (3 to 9 kWh/m²/day).[4] This represents the available power, and not the delivered power. At present, photovoltaic panels typically convert about 15% of incident sunlight into electricity; therefore, a solar panel in the contiguous United States on average delivers 19 to 56 W/m² or 0.45 - 1.35 kWh/m²/day.[5]
The dark disks in the third map on the right are an example of the land areas that, if covered with 8% efficient solar panels, would produce slightly more energy in the form of electricity than the total world primary energy supply in 2003.[6] While average insolation and power offer insight into solar power's potential on a regional scale, locally relevant conditions are of primary importance to the potential of a specific site.
After passing through the Earth's atmosphere, most of the sun's energy is in the form of visible and infrared radiation. Plants use solar energy to create chemical energy through photosynthesis. Humans regularly use this energy burning wood or fossil fuels, or when simply eating the plants.
A recent concern is global dimming, an effect of pollution that is allowing less sunlight to reach the Earth's surface. It is intricately linked with pollution particles and global warming, and it is mostly of concern for issues of global climate change, but is also of concern to proponents of solar power because of the existing and potential future decreases in available solar energy. The order of magnitude is about 4% less solar energy available at sea level over the timeframe of 1961–90, mostly from increased reflection from clouds back into space.[7]
Appropriate Techology
System Types
Availability of Solar Thermal Energy
Direct solar heat gain is one of the most efficient ways to heat water (in terms of energy/waste), as it requires no energy conversion, unlike electric-resistance heating or fuel burning. It is a simple transfer and concentration of heat energy from one place to another.
Hot water can be used for a number of applications, including sanitation (it's easier to wash a lot of things with hot water), and space heating.
