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Created by: Malik for UI Nov 7 2013
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Pokok Bahasan Sumber Daya Angin Metoda Pengukuran Parameter Potensi Energi Angin
dan Pengolahan Data Secara Statistik (Status dan Data Pengukuran di Indonesia) Metoda Analisis Potensi Energi Angin Teknologi Turbin Angin (Penelitian dan Pengembangan Teknologi Turbin Angin di Dunia dan di Indonesia) Potensi Energi Angin di Indonesia Wind Hybrid Power Generation (WHyPGen) Created by: Malik for UI Nov 7 2013
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Sumber Daya Angin •Angin terjadi disebabkan adanya perbedaan tekanan udara dimana perbedaan tekanan udara tersebut dipengaruhi oleh perbedaan suhu. Ketika terjadi perbedaan tekanan, udara mengalir dari tekanan yang tinggi ke tekanan yang rendah. •Pada permukaan bumi, gesekan dapat menyebabkan kecepatan alir angin menjadi lambat. Pada permukaan tanah yang kompleks, arah angin dapat menjadi berubah arah.
Created by: Malik for UI Nov 7 2013
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Sumber Daya Angin
sea
beach grass
trees
hills
woods
buildings
cities
valleys & mountains
Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik Parameter yang di ukur:
Tujuan Pengukuran: Kecepatan dan arah angin, suhu, kelembaban, tekanan udara Pengolahan Untuk mendapatkan data yang akan digunakan Data Secara Statistik: estimasi mengenai ketersediaan sebagai Kecepatanbahan angin rata-rata tiap jam ( diurnal), harian, bulanan dan energi tahunan angin. Dilakukan pada lokasi dimana dibangun turbin angin. direncanakan Kecepatan anginakan minimum, maksimum, dan lull Perhitungan energi Distribusi kecepatan angin angin yang terjadi pada anemometer. ketinggian Distribusi arah angin (Arah angin dominan) Pola angin harian, bulanan, dan tahunan Proses statistik sebagai persyaratan dalam hal keakuratan Daya angin spesifik (WPD) untuk jangka panjang (long perkiraan term). Wind Shear
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Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik Instrumentasi yang digunakan merupakan instrumen standar pengukuran meteorologi. Menggunakan sensor yang akurat dan teliti (anemometer, wind direction with data logger and computer access). Instrumentasi yang digunakan dirancang khusus untuk mengukur dan mengkarakterisasi potensi angin. Selain itu, instrumentasi tersebut dirancang untuk rasio sampling data yang tinggi untuk menentukan jenis angin (angin puting beliung, turbulensi dan sebagainya) yang akan digunakan untuk menganalisa responrespon turbin angin. Tinggi pengukuran 30 m sampai 50 m atau lebih Minimum 1 tahun lamanya observasi Metode estimasi energi : Weibull dan bin Menggunakan software standar untuk pengolaahan dan evaluasi data. "J.F. Manwell, J.G. McGowan and A.L. Rogers" , Wind Energy Explained: “Theory, Design & Application Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik Anemometers= Sensor Pengukuran Kecepatan Angin Spinning cups or propeller. Mechanical counters registering number of rotations * Electrical or electronic voltage changes (AC/DC) A photoelectric switch (Akurasi ± 2%) Ultrasonic reflection (Doppler) Sodar (Sound detection and ranging with a large horn) Radar Drift balloons (Radio Sonde) Lidar Etc.
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Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik Wind vane Wind vanes measure the direction of the wind as a function of time, usually produce signals by contact closures or by potentiometers. Wind vanes usually produce signals by contact closures or by potentiometers.
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Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik
Kecepatan Angin
• • • •
Rata-rata / 10 Menit Maksimum/ 10 Menit Minimum/ 10 Menit Std Deviasi/ 10 Menit
1 Hz Arah Angin
• Rata-rata / 10 Menit • Std Deviasi/ 10 Menit
•IEC 61400
Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik DIAGRAM ALIR PENGUKURAN POTENSI ANGIN
Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik •
Tinggi menara
: 50 m
•
Tinggi anemometer : 20 , 35 dan 50 m
•
Sensor arah angin
•
Tinggi Logger
•
Transfer data : by download / internet
•
Tipe menara : tree angle dia 16 mm, hot
: 35 m dan 51,5m :3m
dip galvanis steel •
Jarak pancang : Radius 10m dan 20 m , di 3 sisi
•
Lama Pengukuran : > 1 tahun
Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik WIND SHEAR Height
Wind Speed, m/s
m 50
12.6
40 30
12.2 11.7 11
20 10 5 0
10 8.8 SURFACE
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik Daily Wind Speed Wind Speed (m/s)
8.0 6.0 4.0
Pola Kecepatan Angin Harian
2.0 0.0 1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time
Wind rose Kecepatan Angin Harian
Arah Angin
Energi Rose Created by: Malik for UI Nov 7 2013
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Pengukuran Parameter Potensi Energi Angin dan Pengolahan Data Secara Statistik STATISTIK DATA IKLIM ANGIN
Created by: Malik for UI Nov 7 2013
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STATUS DAN DATA PENGUKURAN DI INDONESIA Kelas
Kec. Angin ( m/s)
WPD (W/m2)
Jumlah Lokasi
Daerah / Wilayah
•
Survei dan< pengukuran langsung di lokasi ; 3,0 < 45 66 Sumbar, Bengkulu, Jambi,Jateng, NTB, Kalsel, NTT,Sultra, Sulut, LAPAN, ESDM : >130 lokasi di berbagai Maluku,wilayah Potensi rendah (Skala 3,0 – 4,0 < 75 34 Lampung,DIY, Bali,Jatim,Jateng, NTB, Indonesia Kecil) Kalsel, NTT,Sultra, Sulut, Sulteng, Sumut, Sulbar Wind Guard : 12 lokasi (NTT) Potensi Menengah/ 4,1 – 5,0 75 - 150 34 Bengkulu, Banten, DKI,Jateng, Jatim, Skala Menengah NTB, NTT, Sultra, Sulteng, Gorontalo, Windrock Int : 20 lokasi (NTT) Sulsel Potensi Bagus /Tinggi, > 5,0 > 150 19 DIY, Jateng, Sulsel, NTB, NTT, Sulut Soluziona : 3 lokasi (Sulsel dan Jateng) Skala Besar Nipsa : 2WPD lokasi Jumlah (Sumut) Daerah / Wilayah Kelas Kec. Angin (W/m ) ( m/s) Lokasi • Data dari skunder : BMG , WMO , NCDC dan 3 TIER Kurang Potensi al < 3,0 < 45 55 Maluku, Papua, Sumba, mentawai, • Peta potensi energi angin NTT : bengkulu, SumbaJambi, danNTT, Timor NTB, Sultra, Sulut, Sumut (NREL) 3,0 – 4,0 Potensi rendah (Skala < 75 29 Jateng, Maluku, DIY, Lampung, Kalsel, Kecil) NTT, NTB, Sultra, Sulteng, Sulut, • Berbagai instansi di beberapa lokasi Sumut Kurang Potensial
30 m
2
Potensi Menengah/ Skala Menengah Potensi Bagus /Tinggi, Skala Besar
4,0 – 5,0
75 - 150
34
Jateng, DIY, Jatim, Bali, Bengkulu, NTT, NTB, Sulsel, Sulteng
> 5,0
> 150
35
Banten, DKI, Jateng, DIY, NTT, NTB, Sultra, Sulut, Sulsel
Created by: Malik for UI Nov 7 2013
50 m
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STATUS DAN DATA PENGUKURAN DI INDONESIA
Klasifikasi Potensi Energi Angin vs. Klasifikasi Turbin Angin
Created by: Malik for UI Nov 7 2013
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Metoda Analisis Potensi Energi Angin Ite m M o de l typ e
N a ti o n a l
R e g io n a l
L o c a l p la n n in g,
W F la yo u t &
p lan n in g
p la n n i n g
w in d f a rm sit ing
m ic r o -sit ing
M e so sc a l e
M e so sc a l e
M e so a n d
M e so - a n d
m i c ro s ca l e
m ic r o sc a le
D om a i n siz e
5 0 0- 1 00 0 k m
1 00 - 50 0 k m
20 - 10 0 k m
1 0 -2 0 k m
M ap
5 -1 0 k m
1 -5 k m
10 - 10 0 m
1 -1 0 m
N C E P /N C A R
N C E P /N C A R
N C E P /N C A R +
D e di c a te d
re a n a l y sis d a t a
re a n a l y si s d a t a
M e t. s ta t io ns
M e t. st a ti o n s
re s olu t ion W i nd d a t a
SA S S a t e l li te D a ta
M T Sat
N OA A , M OD IS
L a n ds a t, S P O T ,
A LO S
A LOS V e ri fi c a ti o n
U nc e r t a in ty
R e p re se n ta t ive
R e p re se n t a t iv e
Ded icated
D e di c a te d
m et . sta t ion s
m e t. st a t ion s
M e t. s ta t io ns
M e t. st a ti o n s
1 0 -3 0 %
1 0- 2 0%
5- 1 5%
1 -1 0 %
o n m ean sp e e d U Created by: Malik for UI Nov 7 2013
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Metoda Analisis Potensi Energi Angin
PETA POTENSI ENERGI ANGIN SKALA MIKRO
PARAMETER PENILAIAN POTENSI ENERGI ANGIN
INPUT 1: DATA ANGIN
INPUT 2: DATA TOPOGRAFI
PENGAMBILAN DATA ANGIN
PEMBUATAN PETA VEKTOR
STATISTIK DATA ANGIN
IDENTIFIKASI ROUGHNESS
KARAKTERISTIK IKLIM ANGIN
DIJITASI
WIND RESOURCES ASSESSMENT SOFTWARE Created by: Malik for UI Nov 7 2013
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Metoda Analisis Potensi Energi Angin KECEPATAN
ANGIN RATARATA PADA KETINGGIAN TERTENTU (m/s)
DISTRIBUSI ARAH
ANGIN RATARATA PADA KETINGGIAN TERTENTU (°)
RAPAT DAYA
ANGIN (W/m2) Created by: Malik for UI Nov 7 2013
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EKSTRAPOLASI
KOEFISIEN WIND SHEAR: ROUGHNESS:
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DATA ANGIN PETA VEKTOR PENENTUAN JENIS ROUGHNESS
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B
A
Garis Roughness
Gambar Peta Vektor + Roughness Created by: Malik for UI Nov 7 2013
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WIND POWER POTENTIAL Wind Speed Histograms are used to determine Wind Class Wind Class 3 4 5 6 7
W/m2 at 50 m 300 - 399 400 - 499 500 - 599 600 - 800 > 800
Created by: Malik for UI Nov 7 2013
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Metoda Analisis Potensi Energi Angin
Created by: Malik for UI Nov 7 2013
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Contoh Titik Penempatan Turbin Angin Pada Suatu Windfarm dan Turbulensi
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Teknologi Turbin Angin
LIFT
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Teknologi Turbin Angin HAWT
VAWT
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Teknologi Turbin Angin Perkembangan Turbin Angin
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Teknologi Turbin Angin 10 Besar Produsen Turbin Angin
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Teknologi Turbin Angin WIND TURBINE ANATOMY
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Kontribusi Biaya Per-komponen Turbin Angin dan Persentase Penggunaan Material
Raw Materials Requirements for Wind Turbines (Based on a 1.5 MW Wind Turbine by % of Weight, including blades and towers) Source: U.S. DOE, 20% Wind Energy by 2030, p. 63, July 2008
Contribution of main parts as a percentage of overall costs based on a REpower MM92 Wind Turbine (Source: Wind Direction, 'Supply Chain: The Race to Meet Demand', January/February 2007)
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Menara Table 5.1 Dimensi Menara Turbin Angin 1,5 MW
Tower Overview: Support wind turbine Rolled steel - welded Attaches a concrete base and foundation Maximizes height for good wind 66% of total wind turbine weight Internal components: Steel plate, flanges, yaw gear, coating/ paint, bracket, door assembly, hatches, hoist, climb assist, ladder, platform, lighting and cable. Supplier implications: 100-200 ton of steel 50-120 meters in height Shipped in 3 section or more Internal assembly at tower manufacturer Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Sudu
Blade Overview: Creates lifting forces and rotational torque to generate power 70% to 75% fiberglass by weight with epoxy or polyester resin 7% of total wind turbine weight Internal components: Internal Core/Spar, Fiberglass, Skin Composite Laminates, Carbon Fiber, Epoxy or Polyester Resin, Root Insert, Fasteners, Barrel Nut, Protective Painting/Coating, Lightning Protection, De-Icing System. Supplier implications:
6-10 tons each 30 - 55 meters in length Vacuum resin infusion and pre-preg molding (most are two pieces, some are one piece) Core parts integrated into final blade assembly Hull with core materials Spar caps Spars with sandwich Root section Bolt holes
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Rotor
Rotor Hub Overview: Extract the power of the wind and convert it to rotary Supplier Implications: One of the largest components at 7 - 20 tons motion Material is typically cast ductile iron Hub connects the blades to the main shaft Tight casting and machining specifications Internal Components: Hub ,Nose Cone, Pitch Brake (Disc, Calipers, Pads, Created by: Malik for UI Nov 7 2013 Hoses, Seals, Housing), Bearings, Lubrication System
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Teknologi Turbin Angin Drivetrain
Drivetrain Overview: Consists of all the rotating components: rotor, main shaft, couplings, gearbox, brakes, and generator 10 -20 rpm low speed side to 1200 – 2000 rpm high speed side Internal Components: Main Shaft, Rotor Lockout , Bearing, Seal, Lubrication, Compression Coupling, Rotor Lock, Connector Plate, Slip Ring Assembly, Transmission Shaft, High Speed Shaft,
High Speed Coupling Brake System (Disc, Calipers, Pads, Hoses, Seals, Housings) Supplier Implications: Main shaft is forged steel, machined and ground at 15- 25 tons weight Machined steel couplings, bolted, keyed, some with rubber Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Gearbox
Gearbox Overview: sun gear, planet gear, carrier gear), 10 - 20 rpm to 1500-1800 rpm on high Hollow Shafts Bearings (planet bearing, speed shaft carrier bearing, shaft bearing), Hoses, One of the heaviest and most expensive Torque Arm Systems, Lubrication components of a wind turbine System, Cooling System, Hoses, Normally planetary or parallel-shaft Sensors (temperature, particulate) gearboxes Not used on direct-drive wind turbines Internal Components: Housing, Planetary Gears (ring gear, Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin
Generator
Radial Flux Axial Flux
Generator Overview: Converts mechanical energy into electric power 3 types are synchronous, asynchronous, • double fed induction generator Most common is DFIG (Double Fed • Induction Generator) PMG (Permanent Magnet Generator) most commonly used on direct-drive turbines and are growing in popularity Created by: Malik for UI Nov 7 2013
Internal Components: Housing, Windings (stator & rotor), Lamination, Rotor Magnets, Commutator and Brushes, Bearings (rotor front bearing, rotor rear bearing, autolube system), Encoder, Shaft, Slip Rings (slip ring and brush), Exciter, Couplings, Generator Temperature Sensor, Coils, Cooling System (Radiator, Hoses, Filters, Cooling Fan, Pump, Pump Motor, Reservoir, Heat Exchanger)
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Teknologi Turbin Angin Kelistrikan dan Sistem Kontrol
Electrical Overview: Sensors Power converters change electric power from one form to another; Internal Components: Control System Overview: Controllers Power Converter , Converter with IGBT Module (on the rotor side), DC to AC or AC to DC, or one voltage to another Balances and optimizes machine operation and power production Mechanical Mechanisms, Electrical Circuits, Computers Inverters convert DC to AC DC Intermediate Circuit, Power Inverter, (on grid side), Power Maximizes fatigue life Power Amplifiers Switchgearenergy connects or disconnects wind power plants from the grid Switches, Factor Correction System (capacitors, harmonics, filter contractor), Maximize production Electric Amplifiers, Hydraulic Pumps and Valves Transformer adjusts the voltage Soft Starter, Motor Contactor, Wiring and Connections (main Provide means to monitor Actuators Higher Frequency Replacement Parts On Operating Turbines contactor), Main Disconnect, Fuse Main Circuit Breaker, Relay, Internal Components: Motors, Pistons, Magnets, Solenoids Electrical System parts Cabinet Heater, Power Supply, Grounding System, Main Sensors Intelligence Electronic Control parts Transformer (pad mounted or nacelle mounted) Speed, Position, Flow, Temperature, Current, Voltage Computers, Microprocessors Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Nasel
Nacelle Housing Overview: Is the housing for all major components of a wind turbine Provides weather protection Normally made from lightweight materials such as fiberglass around a steel frame
Internal Components: Fiberglass Shell with Structural Steel Frame, Brackets, Exit Hatch and Latches, Wiring, Lightening Rod, Landing Pad, Ducting
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Sistem Yawing
Yaw System Overview: Orients the wind turbine in line with the wind direction 3 or 4 motors used to rotate Includes a parking brake system
Internal Components: Brake, Calipers, Housing, Pads, Seals, Hoses, Electric or Hydraulic Drive, Reducer Gearbox, Lubrication System, Fan, Pinion gear, Polymer Slide Pads/Discs, Encoder
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Sistem Pitch
Pitch System Overview: Feathers the blades to best capture the energy from the wind Used to stall the rotor to help slow down the turbine Geared slew ring with electric or hydraulic driver Each blade controlled separately Internal Components: Electric Pitch System Motor, Cooling Fan, Motor Brake, Pitch Gear, Gear Reducer, Limit Switch , Battery, Battery Charger, Seals, Auto-Lube System, Rotary Electric Drive (pinion, power electronics/drive,
cabling, contactor/circuit breaker fuse, encoder, power supply, heater, misc. electrical) Hydraulic Pitch System Linear Hydraulic Drive, Accumulator, Pump & Pump Motor, Proportional Valve, Position Sensor, Hoses/Fittings, Spherical Bushing, Cylinder, Linkage, Position Controller, Limit Switch Mechanical Pitch System Bearings and Lubricants, Motors, Gears, Pitch Cylinder Linkage
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Wind Turbine Concepts
By-pass SCIG wind
Active stall/ Pasive stall wind turbine Fixed Speed Squirrel-Cage Induction Generator
G drive train Capacitor
AC AC Soft-starter
transformer
grid
Bank
Soft-starter, Capacitor Bank
SCIG transformer wind
Pitch control wind turbine Variable Speed Squirrel-Cage Induction Generator
G drive train
AC AC Power Converter
grid/stand alone
Back-to-Back Power Converter Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Wind Turbine Concepts
DFIG
Pitch control wind turbine Variable Speed Double-Fed Induction Generator
wind
transformer
G drive train
AC AC
Back-to-Back Power Converter
SG Pitch control wind turbine Variable Speed Multi-Pole Synchronous Generator
wind
– direct driven Rectifier + Inverter
G
grid
transformer AC AC Power Converter
grid/stand alone
Created by: Malik for UI Nov 7 2013
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Teknologi Turbin Angin Contoh Kurva Daya Turbin Angin
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TECHNOLOGY TREND
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KONFIGURASI PEMANFAATAN
Sistem Stand Alone
Sistem Hibrida
Sistem Interkoneksi
Created by: Malik for UI Nov 7 2013
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Turbin Angin Di Indonesia LAPAN: Turbin angin sudu majemuk untuk pompa mekanik. 80
Watt hingga 50 kW untuk pembangkit listrik, jenis poros horisontal, vertikal, radial flux dan axial flux. LAGG-BPPT: Turbin angin poros horisontal dengan kapasitas 300
W hingga 20 kW.
P3TEK EBTKE: Turbin angin poros horisontal dengan kapasitas
100 kW.
PT. Alpen Steel: Turbin angin poros horisontal dengan kapasitas 1
kW dan 7,5 kW.
PT. Mekanika Elektrika Egra: Turbin angin poros horisontal dengan
kapasitas 4,5 kW dengan merek Egra.
Created by: Malik for UI Nov 7 2013
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Teknologi SKEA
Prototipe SKEA
SKEA 5 kW
SKEA 10 kW
SKEA Pompa Air
SKEA 80 W
SKEA 2,5 kW Created by: Malik for UI Nov 7 2013
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Contoh Prototipe Teknologi SKEA
LPN-10000E Prototipe SKEA Listrik
Spesifikasi : SKEA 10 Kw Daya output : 10000 W Posisi rotor : angin hulu ( upwind ) Diameter rotor : 7,2 m Jumlah Sudu : 3 buah Bahan Sudu rotor : glassfibre reinforce Polyester Putaran rotor : 350 rpm Kecepatan Operasional Kec. Awal ( cut-in ) : 3,0 m/detik Kec. Nominal ( rated ) : 10 m/detik Kec. Batas ( cut-out ) : 18 m/detik Generator : tipe angular, magnet permanen Tegangan output : 24 V – 240 V DC Sistem pengaman : “ ecliptic safety by turning tail vane 90o and electric brake “ Menara : tipe latis / threangle (10 – 30m) Tubular (6 – 24 m) Pondasi : blok setempat diperkuat r angka besi Created by: Malik for UI Nov 7 2013
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Spesifikasi : SKEA 50 kW Daya output Posisi rotor Diameter rotor Jumlah Sudu Pitch setting Bahan Sudu rotor Putaran rotor Kecepatan Operasional • Kec. Awal ( cut-in ) • Kec. Nominal ( rated ) • Kec. Batas ( cut-out ) Generator Tegangan output Sistem pengaman Menara Pondasi
: 50.000 W ( 50 kW) : angin hulu ( upwind ) : 18.00 m : 3 buah : fix blades : glassfibre reinforce Polyester/ Epoksi : 100 rpm : 2,5 m/detik : 10 m/detik : 18 m/detik : tipe angular, magnet permanen : 24 V – 240 V DC : “ aktif yaw system “ : tipe latis / threangle with guy wires : blok setempat diperkuat r angka besi
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CONTOH PEMANFAATAN TURBIN ANGIN
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CONTOH PEMANFAATAN TURBIN ANGIN
OFF GRID SYSTEM
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Wind Power to Grid Interconnection Issues Discussion Bagaimana energi angin yang merupakan sumber yang bersifat variabel dimana hal •Intermittent (tidak selalu tersedia) tersebut dapat meningkatkan kekhawatiran akan dampaknya tersebut terhadap •Tiba-tiba hilang, tiba-tiba jaringan (aturan jaringan, pembebanan, penjadwalan, parameter kelistrikan dan Alami muncul Kualitas Daya cadangan?) dan berapa biaya interkoneksinya serta dibebankan ke siapa?. •Kecepatan yang bervariasi •Efek bayangan menara Peralatan
Power Converter
Kehandalan Pasokan
Kualitas Tegangan Gangguan Beban
Interupsi yang lama
Interupsi Sesaat: •Voltage Dips •Over Voltage •Frequency Deviation
•Rapid Changes •Flicker •Unbalance •Harmonics •Interharmonics •Transient •DC-Component
Created by: Malik for UI Nov 7 2013
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Wind Power to Grid Interconnection Issues, Solution Aturan Jaringan Khusus Untuk Turbin Angin (Sistem Jaringan Lemah & Sistem Jaringan Kuat)
Teknis •Monitoring and Logic system •Switching operation dan soft starting •Active Power Control •Frequency Control •Voltage Control •Modeling Information and Verification •Communication and External Control •Low voltage ride through
Administratif
Biaya Interkoneksi
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Wind Power to Grid Interconnection Issues, Solution
Pemilihan Jenis Teknologi dan Kapasitas Turbin Angin yang Sesuai dengan:
1.
Potensi Sumber Energi
2.
Kondisi Jaringan
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The Project aims to promote the adoption of Wind Hybrid Power Generation (WHyPGen) Technology through the facilitation, development, application and promotion of the commercialization of on-grid WHyPGen technology. Wind Hybrid Power Generation = WHyPGen
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Funding Source: Global Environment Facility (GEF) Government Implementing Partner: Agency for the Assessment and Application of Technology (BPPT) Implementing Agency: United Nations Development Programme (UNDP)
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Management Structure Project Board Senior Beneficiaries:
Executive:
BAPPENAS, MEMR, PLN, MoI, MoF, Min of Disadvantage Region, METI
National Project Director Agency for the Assessment and Application of Technology (BPPT)
Supplier: UNDP
Project Assurance UNDP
Project Management Unit (PMU) led by National Project Manager Consultants (Experts) Admin and Finance Associate
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Reduction of GHG emission in the power sector
Goal
Objective
Wind Resources Assessmmen t
Facilitation of commercial on-grid WHyPGen systems for environmentally sustainable electricity supply
Wind Farm Feasibility
Activities Comp. #1 Technology Application & Assessment
Comp. #2 Technology Demonstrati on
Comp. #3 Financing Initiatives
Comp. #4 Policy & Institutiona l Support
Comp. #5 WHyPGen Promotion
Comp. #6 Market Developme nt & Industrial Support
Created by: Malik for UI Nov 7 2013
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Target Proyek WHyPGen 16.050 mt
9,4 MW 18,115 GWh
Total penurunan emisi CO₂ per tahun dari pembangkitan listrik melalui aplikasi WHyPGen
Total kapasitas WHyPGen terpasang
Total kapasitas listrik yang dibangkitkan WHyPGen per tahun
Created by: Malik for UI Nov 7 2013
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System Configuration
Wind
Solar
Diesel Power Plant
LV / MV Grid
Public Facilities Residential load
WHyPGen Technology
Hydro
Coal Gas / Diesel Geothermal
Wind Farm MV / HV Grid
Industrial load
Commercial Residential load
Created by: Malik for UI Nov 7 2013
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Skema PLTH. PV-WIND-DIESEL
POMPA TV
LAMPU LAMPU
STEREO
RADIO
KULKAS
Created by: Malik for UI Nov 7 2013
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Beberapa Lokasi Potensial:
POTENSI ENERGI ANGIN DI INDONESIA
Lebak Area
: 100 MW
Sukabumi selatan
: 100 MW
Garut selatan
: 150 MW
Purworejo
: 67.5 MW
Bantul
: 50 MW
Gunung kidul
: 15 MW
Sidrap
: 100 MW
Jeneponto
: 80 MW +100 MW
Baron
: 10 MW
Oelbubuk
: 10 MW
Kupang
: 50 MW (Indikatif)
Palakahembi
: 50 MW (Indikatif)
Selayar
: 10 MW
Takalar
: 100 MW (Indikatif)
Bulukumba
: 50 MW (Indikatif) Created by: Malik for UI Nov 7 2013
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T.E.R.I.M.A.K.A.S.I.H
Created by: Malik for UI Nov 7 2013
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