Difference between revisions of "Design of Photovoltaic (PV) Pumping"
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For domestic water supply, the first data needed is to estimate the water requirement for one person/day. | For domestic water supply, the first data needed is to estimate the water requirement for one person/day. | ||
| − | + | A good estimate can be found in "[http://www.pacinst.org/reports/basic_water_needs/basic_water_needs.pdf Basic Water Requirements for Human Activities: Meeting Basic Needs]" , that relate how much water required to sustain particular activities. <u>Here is the estimate</u><u><ref name="Basic Water Needs for Human Activities">http://www.pacinst.org/reports/basic_water_needs/basic_water_needs.pdf</ref></u><u>:</u> | |
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The detailed explanation can be found on "[http://www.raeng.org.uk/education/diploma/maths/pdf/exemplars_advanced/17_pumping_water.pdf The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering"]. | The detailed explanation can be found on "[http://www.raeng.org.uk/education/diploma/maths/pdf/exemplars_advanced/17_pumping_water.pdf The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering"]. | ||
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= Estimation of Solar Resource<br/> = | = Estimation of Solar Resource<br/> = | ||
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#Instantaneous Solar Power ► cited on unit of W/m2 (only used for complex modelling) | #Instantaneous Solar Power ► cited on unit of W/m2 (only used for complex modelling) | ||
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| + | = Finding Appropriate Solar Pump and Inverter = | ||
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| + | The most important criteria on determining the optimum solar pump is by finding the pump that can satisfy both of daily water flow and pumping head requirement. Normally a solar pump can operate on wide range of water flow rate in response to variation of solar radiation. Generally there are three kinds of pump normally used as solar pump: | ||
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| + | 1. Centrifugal pump | ||
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| + | 2. Helical rotor pump | ||
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| + | 3. Piston (diapraghm) pump | ||
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| + | Here is the table that explain the different characteristic of solar pump <ref name="Solar Water Pumps in Namibia">http://www.drfn.info/docs/cbend/energy_factsheets/solar_water_pumps.pdf</ref>: | ||
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| + | |- | ||
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| + | Type | ||
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| + | Pumping Head (m) | ||
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| + | Flow Rate (m3/day) | ||
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| + | | | ||
| + | Mechanism | ||
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| + | |- | ||
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| + | Centrifugal pump | ||
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| + | | | ||
| + | 0 to 80 | ||
| + | |||
| + | | | ||
| + | 6 to 20 | ||
| + | |||
| + | | | ||
| + | Similar to conventional pump | ||
| + | |||
| + | |- | ||
| + | | | ||
| + | Helical rotor pump | ||
| + | |||
| + | |||
| + | |||
| + | | | ||
| + | 50 to 150 | ||
| + | |||
| + | | | ||
| + | > 20 | ||
| + | |||
| + | | | ||
| + | Robust, only one turning part | ||
| + | |||
| + | |- | ||
| + | | | ||
| + | Piston (diapraghm) pump | ||
| + | |||
| + | |||
| + | |||
| + | | | ||
| + | 0 to 150 | ||
| + | |||
| + | | | ||
| + | 2 to 5 | ||
| + | |||
| + | | | ||
| + | Complex, lot of moving parts, require oil lubrication | ||
| + | |||
| + | |} | ||
= Further Information<br/> = | = Further Information<br/> = | ||
| − | *[[ | + | *[[Photovoltaic (PV) Pumping|Photovoltaic (PV) Pumping]] |
*[http://www.raeng.org.uk/education/diploma/maths/pdf/exemplars_advanced/17_pumping_water.pdf The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering] | *[http://www.raeng.org.uk/education/diploma/maths/pdf/exemplars_advanced/17_pumping_water.pdf The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering] | ||
*[http://www.pacinst.org/reports/basic_water_needs/basic_water_needs.pdf Basic Water Requirements for Human Activities: Meeting Basic Needs] | *[http://www.pacinst.org/reports/basic_water_needs/basic_water_needs.pdf Basic Water Requirements for Human Activities: Meeting Basic Needs] | ||
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Revision as of 06:31, 16 October 2012
Overview
In order to implement cost effective photovoltaic (PV) pumping system, it is necessary to follow some basic guidelines to design and size every system component. This page will explain about detailed calculation needed for sizing every system component.
The basic step to design photovoltaic (PV) pumping system is:
- Determination of water supply need
- Calculation of pumping head
- Estimation of solar resource
- Finding appropriate solar pump and inverter
- Calculation of PV panel required
Determination of Water Supply Need
There are two distinct application for photovoltaic (PV) pumping system[1]:
- Drinking water supply (domestic water supply)
- Irrigation water supply
Domestic Water Supply
For domestic water supply, the first data needed is to estimate the water requirement for one person/day.
A good estimate can be found in "Basic Water Requirements for Human Activities: Meeting Basic Needs" , that relate how much water required to sustain particular activities. Here is the estimate[2]:
|
For example:
|
Calculation of Pumping Head
Pumping head is normally measured in meter (m), so sometimes there are misconception that pumping head is equal to pumping elevation. In actual, pumping head is divided into three components: elevation head, major losses head, and minor losses head.
Pumping Head (m) = Elevation Head (m) + Major Losses Head (m) + Minor Losses Head (m)
- Elevation head is measured from the water source surface level to the point of outlet pipe level.
- Major losses head is influenced by water flow rate, diameter of pipe, length of pipe, and type of pipe (PVC, HDPE etc)
- Minor losses head is influenced by piping accessories including valve, elbow, inlet pipe etc
The detailed explanation can be found on "The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering".
Estimation of Solar Resource
Ideally, a ground based solar radiation measurement in location to be installed with solar water pumping system, is required in order to measure accurately the solar resource available for every part of the year. However, due to expensive equipment required, alternative data can be obtained from "Surface meteorology and Solar Energy" (NASA) for every part of the world freely or other solar resource data website available in the internet.
Solar resources available per day is cited on unit of kWh/m2/day or PSH (peak sun hour) with 1 kWh/m2/day = 1 PSH. Common confusion of solar resource data understanding is usually with solar data cited on unit of W/m2 that describe power.
What is needed on solar pumping design is data cited on energy:
- Solar Energy / Day ► cited on unit of kWh/m2/day or PSH (commonly used for solar pumping design)
- Instantaneous Solar Power ► cited on unit of W/m2 (only used for complex modelling)
Finding Appropriate Solar Pump and Inverter
The most important criteria on determining the optimum solar pump is by finding the pump that can satisfy both of daily water flow and pumping head requirement. Normally a solar pump can operate on wide range of water flow rate in response to variation of solar radiation. Generally there are three kinds of pump normally used as solar pump:
1. Centrifugal pump
2. Helical rotor pump
3. Piston (diapraghm) pump
Here is the table that explain the different characteristic of solar pump [3]:
|
Type |
Pumping Head (m) |
Flow Rate (m3/day) |
Mechanism |
|
Centrifugal pump
|
0 to 80 |
6 to 20 |
Similar to conventional pump |
|
Helical rotor pump
|
50 to 150 |
> 20 |
Robust, only one turning part |
|
Piston (diapraghm) pump
|
0 to 150 |
2 to 5 |
Complex, lot of moving parts, require oil lubrication |
Further Information
- Photovoltaic (PV) Pumping
- The Mathematics of Pumping Water, AECOM Design Build Civil, Mechanical Engineering
- Basic Water Requirements for Human Activities: Meeting Basic Needs
