[GRASS-SVN] r66735 - in grass-addons/grass7/raster/r.green: . r.green.hydro r.green.hydro/r.green.hydro.delplants r.green.hydro/r.green.hydro.recommended r.green.hydro/r.green.hydro.structure

[svn_grass at osgeo.org]

Author: Giulia
Date: 2015-11-04 02:05:24 -0800 (Wed, 04 Nov 2015)
New Revision: 66735

Modified:
   grass-addons/grass7/raster/r.green/r.green.html
   grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.delplants/r.green.hydro.delplants.html
   grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.html
   grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.recommended/r.green.hydro.recommended.html
   grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.structure/r.green.hydro.structure.html
Log:
r.green: html revision

Modified: grass-addons/grass7/raster/r.green/r.green.html
===================================================================
--- grass-addons/grass7/raster/r.green/r.green.html	2015-11-04 10:01:11 UTC (rev 66734)
+++ grass-addons/grass7/raster/r.green/r.green.html	2015-11-04 10:05:24 UTC (rev 66735)
@@ -1,10 +1,18 @@
 <h2>DESCRIPTION</h2>
 
-Compute the energy potential of different renewable energies, 
-considering different limits and constraints (e.g. legal, technical, economic).
+<em>r.green</em> computes the residual energy potential of different renewable energies like biomass or hydropower.<br>
+The tool is organized in the modules r.green.hydro and r.green.biomassfor which are composed of several programs considering different limits (e.g. theoretical, recommended, legal, technical, ecological and economic constraints).<br>
+These different scenarios can be compared so that the residual energy potential and the suitable places for constructing a new power plant can be identified.<br>
+All the modules of the tool r.green can be installed in GRASS as following:
+<div class="code"><pre>
+g.extension r.green</pre></div>
 
 <h2>NOTES</h2>
 
+the basis for creating the modules to calculate the energy potential is shown in the following image:<br><br>
+
+<img src="/home/sscheunert/Desktop/Picture3.png" alt="energy potential modelling"><br></center><br>
+
 <h2>EXAMPLE</h2>
 
 <h2>REFERENCE</h2>
@@ -18,11 +26,6 @@
 
 <h2>AUTHORS</h2>
 
-Giulia Garegnani,
-Julie Gros,
-Francesco Geri,
-Pietro Zambelli,
-Sandro Sacchelli,
-Marco Ciolli
+For authors, please refer to each module of r.green.
 
 <p><i>Last changed: $Date$</i>

Modified: grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.delplants/r.green.hydro.delplants.html
===================================================================
--- grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.delplants/r.green.hydro.delplants.html	2015-11-04 10:01:11 UTC (rev 66734)
+++ grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.delplants/r.green.hydro.delplants.html	2015-11-04 10:05:24 UTC (rev 66735)
@@ -26,12 +26,12 @@
 <h2>SEE ALSO</h2>
 <em>
 <a href="r.green.hydro.discharge.html">r.green.hydro.discharge</a><br>
+<a href="r.green.hydro.financial.html">r.green.hydro.financial</a><br>
 <a href="r.green.hydro.theoretical.html">r.green.hydro.theoretical</a><br>
 <a href="r.green.hydro.optimal.html">r.green.hydro.optimal</a><br>
 <a href="r.green.hydro.recommended.html">r.green.hydro.recommended</a><br>
 <a href="r.green.hydro.structure.html">r.green.hydro.structure</a><br>
 <a href="r.green.hydro.technical.html">r.green.hydro.technical</a><br>
-<a href="r.green.hydro.financial.html">r.green.hydro.financial</a><br>
 </em>
 
 <h2>AUTHORS</h2>

Modified: grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.html
===================================================================
--- grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.html	2015-11-04 10:01:11 UTC (rev 66734)
+++ grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.html	2015-11-04 10:05:24 UTC (rev 66735)
@@ -1,15 +1,47 @@
 <h2>DESCRIPTION</h2>
 
-Compute the hydro-power potential, 
-considering different limits and constraints (e.g. legal, technical, economic).
+The module r.green.hydro computes the hydropower potential. <br>
+It is composed of several programs considering different limits (e.g. theoretical, recommended, legal, technical, ecological and economic constraints).<br>
 
-<h2>SEE ALSO</h2>
+The module r.green.hydro consists of the following six different parts:<br><br>
 
+- <a href="r.green.hydro.theoretical.html">r.green.hydro.theoretical</a><br>
+  calculates for each basin the theoretical maximum hydropower energy potential<br>
+  input raster maps:    - discharge along river network      - elevation of the considered region<br>  
+  input vector map:       existing plant position<br>
+  output vector maps: - available river segments               - optimal plant position<br><br>
+
+- <a href="r.green.hydro.recommended.html">r.green.hydro.recommended</a><br>
+  detects the potential plant position considering legal and ecological constraints and the user's recommendations<br>
+  input raster maps:    - discharge along river network      - elevation of the considered region     - minimum flow discharge<br>  
+  input vector maps:    - existing plant position                    -  areas excluded from calculation<br>
+  output vector maps: - available river segments               - optimal plant position<br><br>
+
+- <a href="r.green.hydro.technical.html">r.green.hydro.technical</a><br>
+  calculates the hydropower potential considering technical constrains (head losses, efficiency of turbine)<br>
+  input vector map:       intakes and restitutions of the potential plants<br>
+  output vector map:  - structure (derivation channel and penstock) on both sides of the river for each potential plant<br><br>
+
+- <a href="r.green.hydro.financial.html">r.green.hydro.financial</a><br>
+  computes the economic costs and values of the plants<br>
+  input raster maps:    - landuse      - slope<br>  
+  input vector maps:   - segments of the potential plants   - plant structure     - electric grid<br>
+  output vector map:    structure of the potential plants with a re-organized table with e.g. power, gross head, total cost<br><br>
+
+- <a href="r.green.hydro.structure.html">r.green.hydro.structure</a><br>
+  computes the derivation channel and the penstock for each potential plant on both sides of the river<br>
+  input raster map:       elevation of the considered region<br>  
+  input vector map:       segments of the potential plants<br>
+  output vector map:    structure for each plant on both sides of the river<br><br>
+
+- <a href="r.green.hydro.optimal.html">r.green.hydro.optimal</a><br>
+  detects the position of the potential hydropower plants that can produce the highest possible power<br>
+  input raster maps:    - discharge along river network      - elevation of the considered region <br>  
+  input vector map:       considered rivers<br>
+  output vector maps: - potential river segments               - intake and restitution of each potential plant<br><br>
+
 <h2>AUTHORS</h2>
 
-Giulia Garegnani,
-Pietro Zambelli,
-Sandro Sacchelli,
-Julie Gros
+For authors, please refer to each module of r.green.
 
 <p><i>Last changed: $Date$</i>

Modified: grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.recommended/r.green.hydro.recommended.html
===================================================================
--- grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.recommended/r.green.hydro.recommended.html	2015-11-04 10:01:11 UTC (rev 66734)
+++ grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.recommended/r.green.hydro.recommended.html	2015-11-04 10:05:24 UTC (rev 66735)
@@ -1,5 +1,5 @@
 <h2>DESCRIPTION</h2>
-<em>r.green.hydro.recommended</em> detects the position of the potential hydropower plants including legal or ecological constrains and the user's recommendations that can limit the technical potential to a more sustainable one. <br>
+<em>r.green.hydro.recommended</em> detects the position of the potential hydropower plants including legal or ecological constraints and the user's recommendations that can limit the technical potential to a more sustainable one. <br>
 Deciding the range of plant length, the distance between plants, the legal discharge we can exploit and the areas we want to exclude from the calculation (ex. protected areas and the ones according to user's recommendations), the module returns two different vector files with recommended available river segments, optimal position of the plants with their powers and their intakes and restitutions. <br>
 
 <h2>NOTES</h2>

Modified: grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.structure/r.green.hydro.structure.html
===================================================================
--- grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.structure/r.green.hydro.structure.html	2015-11-04 10:01:11 UTC (rev 66734)
+++ grass-addons/grass7/raster/r.green/r.green.hydro/r.green.hydro.structure/r.green.hydro.structure.html	2015-11-04 10:05:24 UTC (rev 66735)
@@ -5,7 +5,7 @@
 
 The input maps are the elevation raster map and the one with the segments of potential plants (vector map which can be computed by r.green.hydro.optimal or r.green.hydro.recommended). <br>
 In the section "Input column", the column names in the table of the map with potential plants have to be reported in order to read correctly the corresponding values.<br>
-The module returns a vector map with the structure for each plant and on both sides of the river. The derivation channel and the penstock are distinguished and reported in the table.<br>
+The module returns a vector map with the structure for each plant on both sides of the river. The derivation channel and the penstock are distinguished and reported in the table.<br>
 In option, the module can also compute the vector map with the intake and restitution of each potential plant.<br><br>
 
 As the current potential concerns especially small hydropower (inferior to 20 MW), the structure suggested is the one for small hydropower detailed in the picture below. It is composed of an intake (A) which diverts water from the river. This water is conveyed into a derivation channel (B) with a very low slope and arrives in a forebay tank (C) which regulates the fluctuation of discharge. Finally, the penstock (D) conveys the water with the highest possible head to the turbine-alternator group (E) which produces electricity. The water is then released in the river (restitution F). We use the following vocabulary: the structure of the plant corresponds to the part with the derivation channel, the forebay tank and the penstock, whereas the segment of the plant corresponds to the part of the river (water not diverted) between the intake (A) and the restitution (F).<br><br>