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TRANSCRIPT
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9E 燃机极好的学习资料
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Index 目录1.Gas Turbine Principle & General Introduction 燃机原理及概况2. Gas Turbine Structure 燃机本体结构3. Gas Turbine Accessory Systems 燃机附属系统4. Gas Turbine Control System 燃机控制系统5.Gas Turbine Shipment Weight & Dimension 燃机运输重量及尺寸6. Gas Turbine Erection Procedure 燃机安装步骤7. Gas Turbine Commissioning Procedure 燃机调试规程 8. Gas Turbine Performance Procedure 燃机性能试验规程
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Physics Principle of Conservation of Mass:mass in = mass out (Open System)
Principle of Conservation of Energy:energy in = energy outenergy may be transformed from one form to another (Power Plant converts Chemical to Thermal to Mechanical to Electrical Energy)
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First Law of Thermodynamics
Q = 727 MW
W= 281 MW
Example: 9FB Energy Balance
H4-1 = 446 MW
Where: H = total enthalpy change fluid
entering system Q = net thermal energy flowing into
system during process
W = net work done by the system
General Energy Equationenergy in = energy out, or Q = W + H
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Second Law of Thermodynamics
- Amount of energy which is unavailable to do work- A measure of disorder
Entropy:100 x
TTT
H
CHeCarnotCycl
Basic Principle: Heat moves from hot to cold
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Note: s denotes entropy1
4
3
4
3
1
1
2
1
2
TT
PP
TT
PP
Ideal Brayton Cycle Gas Turbine Application
)T(T
)T(T)T(T
Heat Content (Fuel)Work Output (MW)
23
1243Cycle -
---==
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Real Brayton Cycle Compression and Turbine Expansion Inefficiencies
Typical Values for GE TurbinesCompressor Efficiency 0.86-0.89Turbine Efficiency 0.90-0.93
Compressor
Turbine
Actual
Idealcompressor TT
TT)()(
12
12
Actual
Idealcompressor Work
Work
Entropy
Tem
pera
ture
Peak Cycle Pressure
Minimum Cycle
Pressure
Com
pres
sion
Turbine Expansion
Constant Pressure
Heat Addition
Constant Pressure
Heat Rejection
Ideal CycleWith c & t
LEGEND
1
2
3
4
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Real Brayton Cycle Pressure Losses - Inlet, Combustor, Exhaust
Entropy
Tem
pera
ture
Combustor P
Exhaust P
Inlet P
Ideal CycleWith c & tWith P’s
LEGEND
Entropy
Tem
pera
ture
Combustor P
Exhaust P
Inlet P
Ideal CycleWith c & tWith P’s
LEGENDIdeal CycleWith c & tWith P’s
LEGEND
Typical Values for TurbineInlet Pressure Loss 3” H2OExhaust Back Pressure (SC) 5.5” H2OExhaust Back Pressure (CC) 15” H2ODLN Combustor 6-7% P/P
Inlet ExhaustCombustor
2
3
1
4
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Real Brayton Cycle Parasitic Flows for Turbine Cooling
Entropy
Tem
pera
ture
Compressor
Discharge
Pressure
Ambient
PressureCom
pres
sion
Expansion
Heat Addition
Heat Rejection
Combustor P
Exhaust P
Inlet P
Stg 1 Cooling
Stg 2 Cooling
Stg 3 Cooling
Ideal CycleWith c & t
With P’sWith Cooling Flows
LEGEND
E x i t C o n d i t i o n s :T e x h ~ 1 1 5 0 FP e x h < 1 4 . 7 p s i
E x i t C o n d i t i o n s :T e x h ~ 1 1 5 0 FP e x h < 1 4 . 7 p s i
C D
C o m p r e s s o r B l e e d
B e a r i n g
B l o w e r a i r
( 7 F A + e s h o w n )
1 3 t h s t g . C o m p . b l e e d
9 t h s t g . C o m p . b l e e d
E x i t C o n d i t i o n s :T e x h ~ 1 1 5 0 FP e x h < 1 4 . 7 p s i
E x i t C o n d i t i o n s :T e x h ~ 1 1 5 0 FP e x h < 1 4 . 7 p s i
C D
C o m p r e s s o r B l e e d
B e a r i n g
B l o w e r a i r
( 7 F A + e s h o w n )
1 3 t h s t g . C o m p . b l e e d
9 t h s t g . C o m p . b l e e dStg 1 Nozzle
Cooling
4
1
2
3
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COMPRESSOR
QADDED
Exchanger
Heat
Burn
P H=Constant
Qin
3
3
Entropy
Suck
Squeeze
Com
pres
sion
1
2
1 2Te
mpe
ratu
re
Expansio
n
COMPRESSOR
Shaft WorkTURBI
NE
QREJECTED
BlowTurn
P L=Constant
Qout
4
4
TURBINEThe
TURBINE transforms
thermal energy into mechanical
energy (3 – 4) used for driving
the Compressor & Generator
Brayton Cycle – Gas Turbine
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World wide heavy-duty Gas Turbine manufacturers
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3.2
Output
Year2000198019701960 1990
100MW
200MW
9 3000 RPM
7 3600 RPM
5-65100-5230 RPM
5P
7A 7E
9B
6A
7F
9F9FB
7FB
6FA
9E
6B
7EA
5L
3-66900-7100 RPM
6CAero (CF6)
Evolution of GE Gas Turbines
7FA+e
9FA+e
6FA+e
9FA
7FA
7B
First air cooled bucketFiring T° > 1000°C
Firing T° > 1250°C
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Evolution of MHI Gas Turbines
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Line-Up of MHI Gas Turbine
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The Efficiency and Power Output of MHI Gas Turbine
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MHI 701F / 701G Gas Turbine features
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Siemens Gas Turbines
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Siemens SGT5-4000F (V94.3A)
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Alstom GT26 Gas Turbine Features
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Alstom Gas Turbine Combined Cycle (50 Hz&60 Hz)
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典型 F 级机组和 E 级机组的性能及参数表 1 : F 级简单循环燃气轮机的参考性能( ISO 标准参考条件)
生产厂商 GE SIEMENS MHI型号 PG9351FA V94.3A M701F功率( MW ) 255.6 267 270热效率(%) 37 38.7 38.2空气流量( kg/s ) 632.7 645 651排气流量( kg/s ) 659
压缩比 15.4 16.9 17.0压气机级数 18 15 17透 平 转 子 进 口 温 度( TRIT ℃)( )
1327 1310 1400*
透平级数 3 4 4透平排气温度(℃) 609 576 586NOx 排放量(天然气燃料) (ppm)
25 25 25
机组重量( ~t ) 240 330 340机组近似尺寸 22.6×5.0×5.4 12.5×6.1×7.5 17.3×5.8×5.8
注 *:这是透平参考进口温度,即透平第一级喷嘴前的温度。
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表 2 :由 F 级燃气轮机组成的联合循环机组的参考性能( ISO 标准参考条件)生产厂商 GE SIEMENS MHI
型号 S109FA S209FA 1S.V94.3A
2S.V94.3A
MPCP1(M701F)
MPCP2(M701F)
CC 功率 (MW) 390.8 786.9 392 784 397.7 799.6
GT 功率 PGT (MW) 254.1 508.2 513.0 266.1 532.2
ST 功率 PST (MW) 141.8 289.2 281.5 131.6 267.4
PGT/PST 1.792 1.757 1.822 2.022 1.990
热效率(%) 56.7 57.1 57.4 57.3 57.0 57.3
燃机、汽机配置 1+1 单轴 2+1 1+1 单轴 2+1 1+1 单轴 2+1
余热锅炉配置 三压再热 三压再热 三压再热 三压再热 三压再热 三压再热
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表 3 : E 级简单循环燃气轮机的参考性能( ISO 标准参考条件)生产厂商 GE SIEMENS MHI
型号 PG9171E V94.2/V94.2A M701D
功率( MW ) 123.4 157/192 144
热效率(%) 33.79 34.4/35.8 34.8
空气流量( kg/s ) 403.7 510/522 441
排气流量( kg/s ) 519/532
压缩比 12.3 11.1/14.0 14.0
压气机级数 17 17 19
透 平 转 子 进 口 温 度( TRIT ℃)( )
1124 1105/1290 1250*
透平级数 3 4 4
透平排气温度(℃) 538 540/572 542
NOx 排放量(天然气燃料) (ppm)25 25/25 25
机组重量( ~t ) 190 295/320 200
机组近似尺寸 (m) 20×4.6×4.8 14×12.5×8.412.01×6.0×7.
41
12.5×5.2×5.28
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表 4: 由 E 级燃气轮机组成的联合循环机组的参考性能( ISO 标准参考条件) 生产厂商 GE SIEMENS MHI
型号 S109E S209E 1.V94.2
2.V94.2
1.V94.2A
2.V94.2A
MPCP1(M701
D)
MPCP2(M701
D)CC 功 率(MW)
189.2 383.7 233 467.5 293.5 588 212.5 426.6
GT 功 率 PGT (MW)
121.6 243.2 152.0 304.0 367.0 142.1 284.2
ST 功 率 PST (MW)
70.4 146.1 85.5 173.0 230.0 70.4 142.4
PGT/PST 1.727 1.665 1.778 1.757 1.596 2.018 1.996
热 效 率 ( %) 52.0 52.7 51.7 51.8 55.1 55.0 51.4 51.6
燃 机 、 汽 机配置 1+1 2+1 1+1 2+1 1+1 2+1 1+1 2+1
余 热 锅 炉 配置 双压无再热 双压无再热 双压无再热 双压无再热 双压无再热 双压无再热 双压无再热 双压无再热
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GE Gas Turbines
9FA at Horizontal Assembly
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Compressor
Combustion
Turbine
KEY:= Static= Rotating
Major Gas Turbine Components
Air Inlet Gas Exhaust
Cold End Hot End
Fuel
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GE Gas Turbines Family:Evolutions and Performances
Page 28
Shorter Launch Cycles Shorter Launch Cycles Technology matures Technology matures fasterfaster
19867F
1260 Tfire
19919F
1260 Tfire
19927FA1288 Tfire
19946FA
1288 Tfire
ScaleFactor = 0.69
19967FA+
1316 Tfire
19977FA+e1327 Tfire
19979FA+e1327 Tfire
20016FA+e1327 Tfire
ScaleFactor = 1.2
20007FB
1370+ Tfire
88 89 1990 91 92 93 94 95 96 97 98 99 2000 20011986 2002 200387
20029FB
1396 Tfire
SIZE (Scaling Factor )
(Technology, Materials)Firing Temperature,
Evolution of Class F Gas Turbines
5230 RPMGeared Machines for 50 or
60Hz
19929FA
1288 Tfire
3000 RPM 50Hz Machines
3600 RPM 60Hz Machines
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Compressor
Multi-stages, Axial compressorThrough Bolted Disc AssyCast Compressor CasingsIGV for flow control
(1 stage IGV for E/F class)Air discharged to Combustors
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Combustion System
Can Annular Reverse Flow Chambers Dual Fuel Capability (Gas - Liquid)"Dry Low NOx" , Standard , or Low BTU Combustion Systems,Water /Steam injection for emission
abatement
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• 3 Stage Turbine
Air cooled Blades and Nozzles
Tip shrouded Blades
Turbine ( Air cooled GT )
Rotor Assembly = Bolted Discs & Spacers
Page 32
Page 33
Siemens SGT6-5000F
Page 34
Firing Temperature GE Defined at N1 Trailing Edge
N1
N2
N3
B1
B2
B3
TurbineExit Flow
Nozzle/Wheelspace Cooling Air(Chargeable)
Firing Plane
Combustor
Combustor & N1 Cooling Air
(Non-Chargeable)
Bucket/Wheelspace Cooling Air(Chargeable)
Page 35
Combined Cycle T-S Diagram
5 /
Combined Brayton and Rankin CycleT
S
Heat Source
Heat Sink
COM
PRES
SIO
NEXPAN
SION
HRSG
GAS TURBINETOPPING CYCLE
BOTTOMING CYCLESTACK
TEM
PERA
TURE
ENTROPY
COMBUSTION
CONDENSER
EXPANSIO
N
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Gas Turbine Cycle ConfigurationsSingle-Shaft Combined Cycle
• Single Unit Control System • Single Generator & Electricals• Lower Initial Cost vs. Separate STG• Smaller Footprint than multi-shaft
GT-ST-Gen
• Short Cycle Installation
• Small Footprint• Peak Power
Applications• Fast Start Capabilities
GT-GenSimple Cycle Multi-Shaft Combined Cycle
Multi-GT-Gen & ST-Gen
• Lower Centerline Height / Building
• Shorter Construction Time• Higher Base Load Efficiency• 2x1, 3x1, 4x1 …
Page 37
Power Train – Center Line Equipment Variations
GenAcce Inle
t
Stac
k• Generator on the hot (Turbine) side of
GT• Used prior to 1990’s• Shaft driven accessories• Complex packaging
• Generator on the cold (Compressor) side of GT
• Modern F-class arrangement• Electric motor driven accessory skids• Modular packaging
Hot End Drive (prior to 1990’s)Applied to Frames 51P, 6B,7EA,9E
Cold End DriveApplied to Frames 6FA, 7FA/FB, 9FA/FB,7H,9H
Gen Stac
k
Skid Skid
Inle
t
Complex Single-Shaft Power Train
IPHP LPLP
Makeup Tank
GENHPSH
HPEC RHIPSH
LPSH
HP/IP
EC
LPEC
LPEV
IPEV
HPEV
Condensate Pump
BFW
P
Cooling Tower
HP L
CV
IP PCVMSV
MCV
HP BYP
Fuel Delivery
IP BYP
LP
BY
P
LP LCV IP LCV
H
H
H
H
LSV
LCV
ICV
ISV
H
H
CONDENSATE TANK
Air
Gas Turbine
CompTurb
S t e a m T u r b i n eHRSG GT Exhaust
Steam
IPHP LPLP
Makeup Tank
GENHPSH
HPEC RHIPSH
LPSH
HP/IP
EC
LPEC
LPEV
IPEV
HPEV
Condensate Pump
BFW
P
Cooling Tower
HP L
CV
IP PCVMSV
MCV
HP BYP
Fuel Delivery
IP BYP
LP
BY
P
LP LCV IP LCV
H
H
H
H
LSV
LCV
ICV
ISV
H
H
CONDENSATE TANK
Air
Gas Turbine
CompTurb
S t e a m T u r b i n eHRSG GT Exhaust
Steam
Page 38
Examples of Combine Cycle Plant Arrangements
Multi-shaft CC2 gas turbines + 1 steam
turbine
Single-shaft CC
Page 39
Energy Utilization/Loss in Combined Cycle Power Plant
ST POWER (20.9%)
CONDENSER (32.9%)
ST LOSSES
(1%)
STACK LOSSES (7.1%)
HRSG LOSSES (0.5%)
STEAM (54.8%)
GT LOSSES (1.8%)
EXHAUST HEAT
(62.4%) to HRSG
GT POWER (35.8%)
FUEL (100%) to Gas
Turbine
Page 40
9FA Gas Turbine Power Plant General Layout
Power Island HRSG
Cooling Tower
Electrical & Controls
Gas Fuel & Water Treatment Yard
Liquid Fuel Yard AdministrationDemin.
Plant
Page 41
9FA Gas Turbine Power Plant General LayoutCooling Tower
Water Treatment
GT/ST/Gen Building
Electric & Control Building
Admin. Building
Liquid Fuel Yard
HRSG
Waste Water
Exhaust Stack
Warehouse
Aux Boiler
GT Inlet
Gas MeteringMain Transforme
r
Feedwater Pump Building
Fuel Heater
Condensate Storage Tank
Water Pretreatment Chemical Area
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9E Gas Turbine General Layout Adobe Acrobat Document
Mark* VIe Control System - HardwareGE Gas Turbine Controls
Page 44
100MB Ethernet
Unit Data Highway (EGD, NTP…)
Plant Data Highway (TCP/IP, OPC, GSM, Modbus, PI Server, DNP 3.0)
Controller(s)
Operator &Maintenance
Stations(HMI)
Ethernet
Ethernet System 1®
ConditionMonitoring
HistorianOSI PI
TurbineI/O
Driven-LoadI/O
RemoteI/O
Rotating Machinery Control
ProcessI/O
ProcessI/O
RemoteI/O
Process Control
Controller(s)
PTP IEEE1588 100MB EthernetPTP IEEE1588
MK VIe Architecture
TCP Panel
Page 45
Turbine Control1991
7FA Gas Turbine
Industrial Steam
9H Combined Cycle
Turbine / Plant Control1997
Governor / Plant Control2003
Net
wor
ked
I/O, 1
00M
B E
ther
net /
Fib
er
Governors,Hydro, Wind
VM
E B
ackp
lane
, Eth
erne
t, W
Indo
ws
Pro
prie
tary
Des
ign
Mark V Mark VIMark VI e
Evolution of Control System
Page 46
MK VIe Enhancement
Simplex
Processors
Dual
Triple
Simplex
Switches &I/O Net
Dual
Triple
Dual
Triple
I/O Packs
Simplex
1 PackRedundancy• Dual (Process Runs if Controller Fails)• Triple (Process Runs if Controller has Partial or Complete Failure)
Distributed / Remote I/O• Less Installation & Maintenance Cost• More Flexible Application
On-line Repair / I/O Packs• Hot Swap in Redundant Systems• Improved MTTR / Availability
Flexible Redundancy
Page 47
MK VIe TMR Features
TMR configuration
Controller redundancy I/O pack redundancy Terminal board redundancy local transimitters/transducers 2-oo-3 voting for digital inputs Analog inputs voting
Page 48
MK VIe Hardware
Controllers
Power Supplies
IONet Switches
Field Wiring• Vertical Channels• Top & Bottom Cabinet Access• Barrier Blocks• Pluggable• (2) 3.0mm2
(#12AWG) wires/pt
TCP Outline
Page 49
MK VIe Hardware
TCP Controller Rack
Main Processor Board• Compact PCI• QNX Operating System• Unit Data Highway, Ethernet• IONet 100MB EthernetOptional Second ProcessorPower Supply
Processor 650MHz 1.66GHz Cache 256k bytes
1M byte Ram 128M bytes 256M
bytes Flash 128M bytes 128M
bytes Communication Dual 10/100 Full Duplex
Ethernet Power 18 to 32Vdc
Page 50
MK VIe Hardware
• I/O Packs Plug into Mk VI Termination Boards• Barrier & Box Type TBs
Processor 32 Bit RISC CPU 266MHz Cache 32k bytes Ram 32M bytes Flash 16M bytes Communication Dual 10/100 Full Duplex
Ethernet Power 28Vdc
TCP I/O Packs
Page 51
MK VIe Software
TooloboxST is the software tool for I/O definition, EGD configuration, and control strategy programming.
EGD Configuration Control Logic Sheet
ToolboxST—configuration software
Page 52
Cimplicity is the tool used for HMI (human-man interface) display and editor
Operation Menu
Pushbutton
Live Data
Status Feedback
Setpoint
Alarm Window
Cimplicity—HMI Display Editor
MK VIe Software
Page 53
9FA Gas Turbine Weight & Dimension
Item Length
(m)
Width
(m)
Height
(m)
Weight(kg)
Accessory module 9.4 3.5 4.2 36,290
Turbine 10.5 4.7 5.0 288,000
Generator 10.9 5.3 4.2 275,108
9FA Component Weights and Dimensions
a. Heaviest piece to be handled during erection: kg: 285,000b. Heaviest piece to be handled during maintenance: kg 77,500 c. Shipping weight of heaviest piece: kg 288,000 Turbine
Page 54
9E Gas Turbine Weight & Dimension
a. Heaviest piece to be handled during erection: kg: 207,000b. Heaviest piece to be handled during maintenance: kg 49,611 GT rotor
c. Shipping weight of heaviest piece: kg 208,000 Turbine
9E Component Weights and Dimensions
Item
Length(m)
Width(m)
Height(m)
Weight(kg)
Gas Turbine
12.65 5.03 4.98 208,000
Page 55
Gas Turbine Erection Procedure安装过程包含了通用电气 MS 9001FA 燃气轮机所有设备、模块、管路、电缆 在现场的运输 吊装、就位、固定和安装的操作。1 基础准备基础准备包括燃气轮机、发电机和辅助模块的基础,迸气系统和排气系统的基础与附属模块的基础三部分。2 燃机主设备的安装
(1) 安装燃气轮机和发电机的理想方法是配 备一台起重机,或者方法就是利用滑动装置,从卡车上滚动到基础上然后就位。
(2) 燃气轮机的就位先在基础上放好燃机底部各类键销的固定架,再将燃气轮机吊装就位并搁置在底板和薄垫片上,调整薄垫片直至正确的中心线高度。
Page 56
Gas Turbine Erection Procedure2 燃机主设备的安装
(3) 安装负荷联轴节 ( 入口端 )建议采用干冰冷套的方法。安装时螺栓的紧固要求是测量螺栓的伸长量。
(4) 发电机的就位安装取下发电机上的锁定装置 , 提高约 25.4mm 的距离 ( 往换向器一端的方向 ) 。在发电机的底板放置球面垫圈和垫片层,调整薄垫片直至正确的中心线高度。
(5) 盘车装置的安装安装人员应该对所有的螺栓进行装配和扭矩加载测试。(6) 燃气轮机排气扩压段安装先布置好排气扩压段两侧的弹簧支架,用吊车将排气扩压段吊装到弹簧支架上,穿入与排 缸连接的垂直面的螺栓,待调整好开口间隙后再紧固此部分螺栓,以减少对燃气轮机本体的附加应力。安装排气扩压段和外壳之间的绝缘材料。
Page 57
Gas Turbine Erection Procedure2 燃机主设备的安装(7) 最终的定位操作首先应该将发电机与燃气轮机、盘车装置与发电机之间的位置确定好,然后根据要求进行设备的找正找中心工作。注意事项:在进行最终的定位操作之前,排气扩压段应该装配在燃气轮机上。
3 安装辅助模块(1) 安装辅助模块在基础底板上安装辅助模块。此模块包含润滑油箱、润滑油过滤器、润滑油泵和马达、润滑油冷却器、液压控制油泵和马达、液压蓄电池、密封油泵、提升油泵、润滑油蒸汽去雾器和过滤器、气体燃料设备。并按照厂商的说明书来定位油泵和马达。注意事项:辅助模块的基础上没有地脚螺栓。此模块被设计安装在底板上,它包括一个定位销和一个导向销,可以向一端滑动,以补偿热膨胀。模块上的中心定位销靠近燃气轮机端。
Page 58
Gas Turbine Erection Procedure3 安装辅助模块
(2) 安装燃料和雾化空气的模块及电气控制室 (PEECC) 。注意事项:液体燃料和雾化空气模块安装在 6 个支撑腿上。 PEECC 模块安装在 8 个支撑腿上。(3) 安装注水模块、消防模块、水冷却模块、液体燃料前置模块、空气处理器模块、水洗模块等六个模块。(4) 安装冷却风扇模块。
(5) 安装 LCI 和励磁机、绝缘/触发变压器、总线辅助室。
(6) 安装和装配封闭母线
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Gas Turbine Erection Procedure4 罩壳和平台的安装(1) 基础划线,并布置与安装罩壳底部和第一层框架。
(2) 安装发电机和燃气轮机罩壳:依次安装上部框架和面板。注意此处有封闭母线出线排的管道与其他的管道,应和罩壳一起安装。 (3) 安装排气风扇和阻尼器,安装通道、平台和楼梯。同时在燃气轮机和发电机的护栏底部安装一个防止老鼠啃咬的装置。5 安装空气进气系统(1) 安装空气进气室的强制通风系统
(2) 安装空气进气风道系统注意事项:安装人员应该确保风道之间的所有接合面都是防水的或者密封的。
(3) 安装空气进气过滤室注意事项 : 安装精细过滤筒一般在机组第一次运行前 30 天进行。
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Gas Turbine Erection Procedure6 排气烟道的安装
(1) 布置好排气烟道的底部钢结构。
(2) 装配和焊接排气烟道的四个部分,上面两部分和下面两部分应该在水平连接处通过螺栓连接法兰盘来进行定位。
(3) 在排气烟道的外表安装保温材料。
(4) 安装排气扩散段和排气烟道之间的膨胀节。膨胀节是由两个拼装而成的不锈钢环搭接组成的。注意事项:排气烟道和锅炉进口烟道之间的膨胀节应该由锅炉制造商提供并安装。
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Gas Turbine Erection Procedure7 基础上的管道安装
在安装燃气轮机发电机时, 一般由通用电气公司提供各种 on-base 部分的管道 ( 包括支撑架、调节装置和各种仪器 ) 。注意事项:如果部分管道在出厂之前已经装配到燃气轮机上了,那么剩下的管道和管件一般是装在集装箱中运抵现场。此部分的部件号码在集装箱内的管件储放柜上有明显标示,每根管道上也有标记牌,便于安装前清点。8 基础外的管道安装
Off-base 的管道一般是指外部设备 ( 非 GE供货 ) 与 GE 模块或燃气轮机、发电机之间的管道,以及部分 GE 模块与主设备之间的管路。管路系统设计由业主委托设计院完成,施工单位进行施工。安装水和二氧化碳管道和液体燃料管道,空气进气加热管道,排放管,水洗管道,消防管道和放空管共七种。
警告:在对任何管道和部件进行焊接之前,应该确保所有的设备都已经正确接地了,这样可避免出现过大的电流。在对设备进行焊接操作时,应尽量使接地点靠近工作位置。
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Gas Turbine Erection Procedure9 装配电气部分
安装各个电气控制元件包括所有导线、管道、仪表、控制装置、接线盒和电气材料的安装,这些材料用在燃气轮机、发电机、电气控制室 (PEECC) 、辅助模块和液体燃料/雾化空气模块上。注意:只有在被允许的前提下才能安装与连接从发电机至主变的封闭母线。10 基础外的模块上的电气安装
根据 GE 的安装图纸来安装所有的控制设备和仪表 ( 压力和温度开关、测仪表、振动开关、液位指示、低位开关/报警器 ) 。
11 安装业主购买的电气设备由业主提供的十种电气设备:天然气测量管 和测量孔,低量程压差计,高量程压差计,压力变送器,天然气测量热电偶,天然气监测系统,进气传感器和排气传感器 , 湿度传感器性能监视器和发电机出线等。
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Gas Turbine Erection Procedure12 其它设备的电气安装和 6.6kV 的 VAC 电源 (BOP)
13 电力供应:安装人员负责提供动力电缆 , 连接 GE公司提供的设备和业主提供的设备.
14 辅助动力装置 (6 . 6kV ~ 4125 VAC) :安装辅助动力电缆和互连导线.15 辅助总线 / LCI室:安装互连导线。
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Gas Turbine Commissioning Procedure – 9FA
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Gas Turbine Commissioning Procedure
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Gas Turbine Commissioning Procedure
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Gas Turbine Commissioning Procedure
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Gas Turbine Commissioning Procedure
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Gas Turbine Commissioning Procedure
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Gas Turbine Commissioning Procedure
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Gas Turbine Performance Test Procedure
1. The Purpose: to measure the performance of the gas turbine-generator units in accordance with the purchase contract.
2. The evaluation procedure: To utilize correction factors to translate the measured performance at the test conditions to the rated conditions
3. The performance test international standard: Simple Cycle: ASME PTC 22 Combined Cycle: ASME PTC 464. The performance specifications: Power Output xxx,xxx kW Heat Rate, LHV xxx,xxx
kJ/kWh Gas Turbine Exhaust Temperature xxx.x °C Gas Turbine Exhaust Available Energy xxx.x GJ/hr
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Gas Turbine Performance Test Procedure
5. Rated ConditionsAmbient air temperature xx oC Ambient air relative humidity xx %Barometric pressure x.xxx bar (xx.xx psi)Gas Turbine Shaft Speed xxxx rpmGenerator power factor x.xx (lagging)Gas turbine conditions New and Clean, ≤ xxx Fired HoursInlet system pressure drop (@ contract rated conditions) xx.x mm H2O
(x inH2O)Exhaust system pressure drop (@contract rated conditions) xxx.x mmFuel Natural GasFuel supply temperature xxx oC (xxx.x oF)Fuel composition % volume• Nitrogen (N2) xx.xx• Methane (CH4) xx.xx• Ethane (C2H6) xx.xx• Propane (C3H8) xx.xxFuel lower heating value xx,xxx
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Gas Turbine Performance Test Procedure
6. Division of Test ResponsibilitiesTest Activity Conducting Party
Witnessing PartyPrepare the thermal performance test procedureProvide special instrumentation as specified hereinProvide suitable containers for the collection of fuel samplesPerform required station instrumentation calibration checksWitness / Assist station instrumentation calibration checksInstall special test instrumentationDirect the installation of special test instrumentationObtain calibration records and/or flow section dimensions for the fuel flow sectionExecute of test programWitness execution of test programProvide copies of pertinent measured data to involved partiesArrange for third party analysis of fuel samplesRemove special test instrumentationCalculate corrected performance results and provide preliminary resultsIssue the final test report
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Gas Turbine Performance Test Procedure
7. Measurement and InstrumentationPerformance test data are of two classes:Primary Data used for performance test calculationsSecondary Data not used for performance test calculations, but required for reference or diagnostic purposes
8. Pre-Test PreparationAn off-line water wash of the gas turbine compressorThe calibration and proper operation of the control systempertinent station instrumentation and measurement devices, and recording systems will be
verified
9. Conducting the TestFor each unit, a minimum of three (3) test runs per rated case listed will be conducted.
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Gas Turbine Performance Test Procedure
In accordance with paragraph 3.3.4 of ASME PTC 22-1997:Each test run will be conducted over a thirty (30) minute time period. Manual data will be recorded at least five (5) minute intervalsElectronic control system and data acquisition data will be recorded at least one (1)
minute intervals As a minimum, a set of two (2) fuel samples will be taken at the beginning and end of
each test run All data files, electronic and/or copies of the manual data hard copy sheets relevant for
performance testing and evaluation purposes will be given to the witnessing party immediately after the
test.Deviations from the procedure in any aspect of the test program should be discussed by
the Conducting Party and the Witnessing Party.
10. Evaluation
Calculation formula check and confirmation
The correction curves will be used to account for the difference between the rated value and the
measured value for each parameter
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Gas Turbine Performance Test Procedure
Performance Correction Curves Examples
Compressor Inlet Temperature vs. Output Compressor Inlet Relative Humidity vs. Output Barometric Pressure vs. OutputShaft Speed vs. OutputGenerator Power Factor vs. Output Total Fired Hours vs. OutputInlet System Pressure Drop vs. Output Exhaust System Back Pressure vs. Output Fuel Composition vs. Output Fuel Supply Temperature vs. Output Compressor Inlet Temperature vs. Heat Rate Compressor Inlet Relative Humidity vs. Heat Rate Barometric Pressure vs. Heat Rate Shaft Speed vs. Heat Rate
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Gas Turbine Performance Test Procedure
Performance Correction Curves Examples
Generator Power Factor vs. Heat RateTotal Fired Hours vs. Heat RateInlet System Pressure Drop vs. Heat RateExhaust System Back Pressure vs. Heat RateFuel Composition vs. Heat Rate Fuel Supply Temperature vs. Heat RateCompressor Inlet Temperature vs. Exhaust
TempCompressor Inlet Relative Humidity vs.
Exhaust Temp Barometric Pressure vs. Exhaust Temp Shaft Speed vs. Exhaust Temp Generator Power Factor vs. Exhaust Temp Total Fired Hours vs. Exhaust TempInlet System Pressure Drop vs. Exhaust
TempExhaust System Back Pressure vs. Exhaust
TempFuel Composition vs. Exhaust Temp
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Gas Turbine Performance Test Procedure
11. Comparison to GuaranteesInstrument Uncertainty Test Tolerance
GEK 107551a - Standard Field Performance Testing Philosophy
For testing per these guidelines, these uncertainties are expected to be:
Power Output +/- 2 % Heat Rate, Gas Fuel +/- 1.7 % Heat Rate, Oil Fuel +/- 1.45 % Exhaust Gas Temperature +/- 11F Exhaust Gas Flow +/- 3.3 % Exhaust Gas Energy, Gas Fuel +/- 3.35 % Exhaust Gas Energy, Oil Fuel +/- 3.1 %The test uncertainties will be considered to be minimum tolerance
bands in the commercial evaluation of the test.
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Gas Turbine Performance Test Procedure
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Thank You