Sun-tracking: Difference between revisions
No edit summary |
|||
| Line 1: | Line 1: | ||
Sun-tracking is necessary to get the high power densities desired for [[Solar Concentrators]]. | Sun-tracking is necessary to get the high power densities desired for [[Solar Concentrators]]. | ||
PV panels also benefit from it. | |||
== Feedback based tracking == | == Feedback based tracking == | ||
| Line 14: | Line 15: | ||
==Sun's path calculation based trackers== | ==Sun's path calculation based trackers== | ||
Rather than relying on feedback, this method uses an equation (or tables of values) to calculate the sun's path and the appropriate rotation of the mirrors. Such could be implemented through a computer running a program with output to a stepper motor or linear actuator via parallel or serial port. It could also be implemented with a microcontroller ([http://www.arduino.cc/ Arduino board]), which would be a much lower power solution. | Rather than relying on feedback, this method uses an equation (or tables of values) to calculate the sun's path and the appropriate rotation of the mirrors. Such could be implemented through a computer running a program with output to a stepper motor or linear actuator via parallel or serial port. It could also be implemented with a microcontroller ([http://www.arduino.cc/ Arduino board]), which would be a much lower power solution. | ||
This is the current recommendation of the Redrok engineer for our project. | This is the current recommendation of the Redrok engineer for our project. | ||
Other options to implement are to use [https://www.climatecolab.org/contests/2015/energy-water-nexus/c/proposal/1318104 gravity-powered system]s or [https://www.motherearthnews.com/diy/solar-tracker-zmaz77ndzgoe hydraulic systems]. | |||
==PV panel mount== | |||
A simple PV panel mount (for 65" x 39" and 75" x 39" PV panels) that can rotate along the horizontal plane (single-axis) can be made using [[Modular_construction|gridbeam]]. It can be made 24 inch (=2 foot) high, 42 inch (=3,5 foot) long and 78 inch (=6,5 foot) wide. The panel can then be rotated by a stepper motor by putting it on a plywood supported by an axle. The axle needs to be at least 78 inch long (75" for the panel + 1,5" + 1,5" for the beams + space to mount the electric motor). | |||
== List of Solar Tracker Manufacturers == | == List of Solar Tracker Manufacturers == | ||
A list of global solar tracker manufacturers can be found here: | A list of global solar tracker manufacturers can be found here: | ||
[http://www.enfsolar.com/directory/component/tracker Solar Tracker Manufacturers] | [http://www.enfsolar.com/directory/component/tracker Solar Tracker Manufacturers] | ||
[https://www.eco-worthy.com/catalog/solar-panel-trackers-c-110.html Eco-worthy solar trackers] | |||
==Related pages== | ==Related pages== | ||
Revision as of 16:11, 2 September 2018
Sun-tracking is necessary to get the high power densities desired for Solar Concentrators. PV panels also benefit from it.
Feedback based tracking
Feedback based tracking relies upon a light sensitive electronic circuit which adjusts the inclination of the reflectors to maximize the amount of light received by the circuit.
The Redrok tracker is an example of this. However, the redrok circuit is a non-optical tracker, and adjusts itself to point towards the direction of the highest average light level. On a perfectly clear day, this would be directly at the sun. On a cloudy day (even when the sun is not obstructed), or in the presence of a snow covered hillside, house, etc., this direction would be towards some point in between the sun and the other sources of light (white cloud, snow bank, etc.)
I am told by the designer of the Redrok circuit that it would not perform adequately in a situation where the receiver aperture is about the same size as the reflected image due to this error. His circuit is used by (point focusing) solar cookers where the reflector target is 3 times the diameter of the solar image.
According to the Redrok engineer, an alternative to this would be an optical feedback circuit, where a lens focuses light on the photo sensor. this way, the focusable rays of the sun would give a very strong signal when the circuit is correctly aligned. This setup would be run in parallel with a non-optical tracker, which would track close enough to the sun for the lensing apparatus to begin to be effective and thus overpower the averaged signal of the non-optical sensors. For a linear collector arrangement, this would require a linear lens.
The redrok engineer however was once given the advise "don't try to invent to many things at once", and since he hasn't ever built a linear optical tracker (and doesn't have a source for linear lenses), his initial advise is to avoid trying to develop this technique right now.
Sun's path calculation based trackers
Rather than relying on feedback, this method uses an equation (or tables of values) to calculate the sun's path and the appropriate rotation of the mirrors. Such could be implemented through a computer running a program with output to a stepper motor or linear actuator via parallel or serial port. It could also be implemented with a microcontroller (Arduino board), which would be a much lower power solution.
This is the current recommendation of the Redrok engineer for our project.
Other options to implement are to use gravity-powered systems or hydraulic systems.
PV panel mount
A simple PV panel mount (for 65" x 39" and 75" x 39" PV panels) that can rotate along the horizontal plane (single-axis) can be made using gridbeam. It can be made 24 inch (=2 foot) high, 42 inch (=3,5 foot) long and 78 inch (=6,5 foot) wide. The panel can then be rotated by a stepper motor by putting it on a plywood supported by an axle. The axle needs to be at least 78 inch long (75" for the panel + 1,5" + 1,5" for the beams + space to mount the electric motor).
List of Solar Tracker Manufacturers
A list of global solar tracker manufacturers can be found here:
Solar Tracker Manufacturers Eco-worthy solar trackers