AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM
Research on energy sources of water with a relatively low head of heads between 2 to 3 meters have been developed. At this time, for resources with a low head, the use of Kaplan turbines to convert water energy into usable energy is the most widely used. But the lack of use of the Kaplan turbine is...
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id-itb.:151832017-09-27T10:40:55ZAXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM STYWARD L. TOBING (NIM : 13105027); Dosen Pembimbing :Dr.Ir Priyono Sutikno;, BORIS Indonesia Final Project INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/15183 Research on energy sources of water with a relatively low head of heads between 2 to 3 meters have been developed. At this time, for resources with a low head, the use of Kaplan turbines to convert water energy into usable energy is the most widely used. But the lack of use of the Kaplan turbine is an expensive installation cost, and turbine rotating <br /> <br /> <br /> at a low rotation so that the gearbox needed to turn generators and generators that are used are also more expensive than the generator to a higher round. One way to reverse these problems is to convert the energy contained in the water into the air first with the axial air turbine with the resources of hydro venturi Sistem. This wind turbine can work at 1000 Rpm. <br /> <br /> <br /> This Final task is to design a wind turbine axial with the resources is got from hydro ventury Sistem so that the mechanical power produced by this wind turbine can <br /> <br /> <br /> work at 1000 Rpm optimally. Results of this final task simulation is obtained that the turbine can work on 1000 Rpm, with power generated by 452,45 Watts with an efficiency of 86.24% by using 19 pieces venturi hydro Sistems that are connected in parallel to get the air flow rate accordance with the initial design parameters of the turbine in the air mass flowrate of 4.84 kg / s. It also provided a turbine characteristic curves were simulated at <br /> <br /> <br /> several mass flow rate variations at 1000 Rpm spin and spin the turbine at varying mass flow rate of 4.84 kg / s. text |
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Research on energy sources of water with a relatively low head of heads between 2 to 3 meters have been developed. At this time, for resources with a low head, the use of Kaplan turbines to convert water energy into usable energy is the most widely used. But the lack of use of the Kaplan turbine is an expensive installation cost, and turbine rotating <br />
<br />
<br />
at a low rotation so that the gearbox needed to turn generators and generators that are used are also more expensive than the generator to a higher round. One way to reverse these problems is to convert the energy contained in the water into the air first with the axial air turbine with the resources of hydro venturi Sistem. This wind turbine can work at 1000 Rpm. <br />
<br />
<br />
This Final task is to design a wind turbine axial with the resources is got from hydro ventury Sistem so that the mechanical power produced by this wind turbine can <br />
<br />
<br />
work at 1000 Rpm optimally. Results of this final task simulation is obtained that the turbine can work on 1000 Rpm, with power generated by 452,45 Watts with an efficiency of 86.24% by using 19 pieces venturi hydro Sistems that are connected in parallel to get the air flow rate accordance with the initial design parameters of the turbine in the air mass flowrate of 4.84 kg / s. It also provided a turbine characteristic curves were simulated at <br />
<br />
<br />
several mass flow rate variations at 1000 Rpm spin and spin the turbine at varying mass flow rate of 4.84 kg / s. |
| format |
Final Project |
| author |
STYWARD L. TOBING (NIM : 13105027); Dosen Pembimbing :Dr.Ir Priyono Sutikno;, BORIS |
| spellingShingle |
STYWARD L. TOBING (NIM : 13105027); Dosen Pembimbing :Dr.Ir Priyono Sutikno;, BORIS AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| author_facet |
STYWARD L. TOBING (NIM : 13105027); Dosen Pembimbing :Dr.Ir Priyono Sutikno;, BORIS |
| author_sort |
STYWARD L. TOBING (NIM : 13105027); Dosen Pembimbing :Dr.Ir Priyono Sutikno;, BORIS |
| title |
AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| title_short |
AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| title_full |
AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| title_fullStr |
AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| title_full_unstemmed |
AXIAL WIND TURBINE DESIGN FOR HYDRO VENTURI SYSTEM |
| title_sort |
axial wind turbine design for hydro venturi system |
| url |
https://digilib.itb.ac.id/gdl/view/15183 |
| _version_ |
1820737412442095616 |