Difference between revisions of "Projects:2019s1-180 Nanogrid Development for Households Applications"
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− | ''' | + | =='''Project team'''== |
+ | === '''Supervisors''' === | ||
Supervisor -Dr.Nesimi Ertugrul | Supervisor -Dr.Nesimi Ertugrul | ||
+ | === '''Project members''' === | ||
Members: Shuting Dai, Wassim Saad, Dehong Wang | Members: Shuting Dai, Wassim Saad, Dehong Wang | ||
+ | == '''Introduction''' == | ||
'''Introduction''' | '''Introduction''' | ||
Due to the recent blackouts and load shedding in Australia, energy costs become higher.The project is for the purpose of providing higher quality reliable electrical power with lower costs.The aim of this project is to design, develop and implement a small scale standalone renewable nanogrid for households and small business applications. A traditional electrical grid can be referred as a typical centralised macrogrid while the nanogrid is a localised power distribution system that is less than 5kW. The nanogrid is a mobile system that can be deployed without additional electricity approval and with lower installation costs. | Due to the recent blackouts and load shedding in Australia, energy costs become higher.The project is for the purpose of providing higher quality reliable electrical power with lower costs.The aim of this project is to design, develop and implement a small scale standalone renewable nanogrid for households and small business applications. A traditional electrical grid can be referred as a typical centralised macrogrid while the nanogrid is a localised power distribution system that is less than 5kW. The nanogrid is a mobile system that can be deployed without additional electricity approval and with lower installation costs. | ||
+ | == '''System Design''' == | ||
'''System Design''' | '''System Design''' | ||
+ | [[File:Design123.png|800px|frameless|center]] | ||
AC coupled (left) and DC coupled (right) | AC coupled (left) and DC coupled (right) | ||
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Less cost due to the inverter | Less cost due to the inverter | ||
more suitable for households applications level | more suitable for households applications level | ||
+ | |||
+ | [[File:Dehong.png|700px|frameless|center]] | ||
The nanogrid system is setting up to 48V DC level for human safety operation and 1.3kW output power to satisfy household daily demand which is 14.2kWh in Australia , and central controller is monitoring and controlling voltage and current output from the converter and inverter to ensure the energy management of the system. | The nanogrid system is setting up to 48V DC level for human safety operation and 1.3kW output power to satisfy household daily demand which is 14.2kWh in Australia , and central controller is monitoring and controlling voltage and current output from the converter and inverter to ensure the energy management of the system. | ||
+ | == '''System Layout''' == | ||
− | ''' | + | '''Component Specification''' |
− | + | '''Solar panel ''' | |
− | |||
− | Solar panel | ||
Max power: 260W | Max power: 260W | ||
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Short circuit current: 9.00A | Short circuit current: 9.00A | ||
+ | [[File:Solar.png|500px|frameless|center]] | ||
− | Wind turbine | + | '''Wind turbine''' |
Rated power: 600W | Rated power: 600W | ||
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− | PV & battery controller | + | |
+ | '''PV & battery controller''' | ||
+ | |||
Output current rating: 60A continuously at 25 degree celsius ambient | Output current rating: 60A continuously at 25 degree celsius ambient | ||
+ | |||
Default battery system voltage: 12, 24, 36, 48 or 60VDC | Default battery system voltage: 12, 24, 36, 48 or 60VDC | ||
+ | |||
− | Wind & battery controller | + | '''Wind & battery controller''' |
Battery voltage: 24V | Battery voltage: 24V | ||
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Wind Max current: 35A | Wind Max current: 35A | ||
+ | |||
+ | |||
+ | '''Battery''' | ||
Battery 1 | Battery 1 | ||
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Capacity/voltage: 12V 40Ah | Capacity/voltage: 12V 40Ah | ||
− | |||
Battery 2 | Battery 2 | ||
− | Lithium | + | Lithium |
− | + | ||
Capacity/Voltage: 2.4kWh/ 50Ah/48V | Capacity/Voltage: 2.4kWh/ 50Ah/48V | ||
Charge voltage: 52.4-54V | Charge voltage: 52.4-54V | ||
− | Generator (back up) | + | |
+ | '''Generator (back up)''' | ||
Cont output: 2700W | Cont output: 2700W | ||
Line 83: | Line 97: | ||
Frequency: 50Hz | Frequency: 50Hz | ||
+ | =='''Component Testing'''== | ||
+ | In order to obtain accurate measurements and calculate the real system efficiency, a four-channel picoscope is used to measure input and output data with more decimal places during the whole testing procedure. Also, five-turn measurements of the probes are applied for higher data accuracy. | ||
− | |||
− | |||
− | Solar testing | + | '''Solar testing''' |
1. PV controller testing with power supply | 1. PV controller testing with power supply | ||
Line 102: | Line 116: | ||
With the addition of the variable resistances and the diode to control the direction of the current flow, the efficiency of the solar controller is in the range 86.5% - 91%. | With the addition of the variable resistances and the diode to control the direction of the current flow, the efficiency of the solar controller is in the range 86.5% - 91%. | ||
− | Wind generator testing | + | |
+ | '''Wind generator testing''' | ||
1.Wind turbine generator testing only | 1.Wind turbine generator testing only | ||
+ | |||
To simulate the wind generator under real life operation condition and easier to test the output performance, using the DC motor to drive the generator. The output voltage from the wind generator is balance smooth sine wave. | To simulate the wind generator under real life operation condition and easier to test the output performance, using the DC motor to drive the generator. The output voltage from the wind generator is balance smooth sine wave. | ||
2.Wind controller testing without load | 2.Wind controller testing without load | ||
+ | |||
The output voltage and current from generator have distortion due to load. | The output voltage and current from generator have distortion due to load. | ||
3.Wind controller testing with load | 3.Wind controller testing with load | ||
+ | |||
The result shows the efficiency of the wind turbine generator system under different power of load varied from 42% to 82%. | The result shows the efficiency of the wind turbine generator system under different power of load varied from 42% to 82%. | ||
− | + | =='''Conclusion'''== | |
− | '''Conclusion''' | ||
In general, the efficiency of the solar panel is 80% and an overall 90% average efficiency of the PV controller is achieved in the nanogrid solar system.The high efficiency PV controller is feasible and functional as required. Additionally, the efficiency of the wind generator system is varied from 42% to 82% based on the load, however, this controller is not stable enough to satisfy daily power demand. | In general, the efficiency of the solar panel is 80% and an overall 90% average efficiency of the PV controller is achieved in the nanogrid solar system.The high efficiency PV controller is feasible and functional as required. Additionally, the efficiency of the wind generator system is varied from 42% to 82% based on the load, however, this controller is not stable enough to satisfy daily power demand. |
Latest revision as of 12:15, 30 October 2019
Contents
Project team
Supervisors
Supervisor -Dr.Nesimi Ertugrul
Project members
Members: Shuting Dai, Wassim Saad, Dehong Wang
Introduction
Introduction
Due to the recent blackouts and load shedding in Australia, energy costs become higher.The project is for the purpose of providing higher quality reliable electrical power with lower costs.The aim of this project is to design, develop and implement a small scale standalone renewable nanogrid for households and small business applications. A traditional electrical grid can be referred as a typical centralised macrogrid while the nanogrid is a localised power distribution system that is less than 5kW. The nanogrid is a mobile system that can be deployed without additional electricity approval and with lower installation costs.
System Design
System Design
AC coupled (left) and DC coupled (right) Advantage of DC couple compare with AC couple: Easy to synchronise the system Easy to expand Less power transmission loss through the inverter Less cost due to the inverter more suitable for households applications level
The nanogrid system is setting up to 48V DC level for human safety operation and 1.3kW output power to satisfy household daily demand which is 14.2kWh in Australia , and central controller is monitoring and controlling voltage and current output from the converter and inverter to ensure the energy management of the system.
System Layout
Component Specification
Solar panel
Max power: 260W
Max power voltage: 30.6V
Max power current: 8.50A
Open circuit voltage: 38.2V
Short circuit current: 9.00A
Wind turbine
Rated power: 600W
Rated voltage: 24V
Rated current: 25A
PV & battery controller
Output current rating: 60A continuously at 25 degree celsius ambient
Default battery system voltage: 12, 24, 36, 48 or 60VDC
Wind & battery controller
Battery voltage: 24V
Rated wind power input: 600W
Wind Max current: 35A
Battery
Battery 1
Lead acid
Capacity/voltage: 12V 40Ah
Battery 2
Lithium
Capacity/Voltage: 2.4kWh/ 50Ah/48V
Charge voltage: 52.4-54V
Generator (back up)
Cont output: 2700W
Voltage: 240V
Frequency: 50Hz
Component Testing
In order to obtain accurate measurements and calculate the real system efficiency, a four-channel picoscope is used to measure input and output data with more decimal places during the whole testing procedure. Also, five-turn measurements of the probes are applied for higher data accuracy.
Solar testing
1. PV controller testing with power supply Generated solar power is simulated with DC power supply with average efficiency 86.7%.
2. Solar panel testing only The maximum power point is tracked to be 79.3W, roughly 80% of the rated maximum power of the tested solar panel.
3. PV controller testing without load This solar controller is functional as expected and the efficiency range from 87.5% to 92% is achieved.
4. PV controller testing with load With the addition of the variable resistances and the diode to control the direction of the current flow, the efficiency of the solar controller is in the range 86.5% - 91%.
Wind generator testing
1.Wind turbine generator testing only
To simulate the wind generator under real life operation condition and easier to test the output performance, using the DC motor to drive the generator. The output voltage from the wind generator is balance smooth sine wave.
2.Wind controller testing without load
The output voltage and current from generator have distortion due to load.
3.Wind controller testing with load
The result shows the efficiency of the wind turbine generator system under different power of load varied from 42% to 82%.
Conclusion
In general, the efficiency of the solar panel is 80% and an overall 90% average efficiency of the PV controller is achieved in the nanogrid solar system.The high efficiency PV controller is feasible and functional as required. Additionally, the efficiency of the wind generator system is varied from 42% to 82% based on the load, however, this controller is not stable enough to satisfy daily power demand.
Future works With the completion of preliminary testing of all components, the controller testing and validating of the battery. Assembly components into a cabinet, monitoring and energy management need to be further conducted.