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70 upto mva ( Smart solutions. Strong relationships.
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Leading The World For Generations Crompton Greaves is a pioneer
in the modern technology in electrical field which offers complete
solutions for generation, transmission and distribution of energy
by supplying globally recognized high-tech products delivering
elevated efficiency and robustness.
Since its inception, Crompton Greaves has been synonymous with
electricity. In 1875, a Crompton 'dynamo' powered the world's very
first electricity-lit house in Colchester, Essex, U.K. CG's India
operations were established in 1937, and since then the company has
retained its leadership position in the management and application
of electrical energy.
CG generators meet the vital needs of diverse applications - be
it in continuous power supply, parallel operation in power plants,
industrial plants , hospitals and high-rise buildings; mobile
applications such as railway vehicles, cranes, marine or wind power
demanding the utmost level of electrical performance.
The Synchronous Generator designs are created using latest
technology and optimized using FEM/Flux plotting techniques to
deliver the highest level of performance.
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Solution For Your Industry CG makes generators in both type of
construction i.e.- salient pole and cylindrical pole type. In
addition to this 2 pole turbo alternators are also manufactured.
All the generators are custom built type. It finds application in
various industries like steel, cement, fertilizer, chemical, sugar,
textile, float glass etc. And also in captive power plants using
diesel engines, steam turbines, gas turbines, hydro turbines
etc.
The generators offered are self-excited and self-regulating.
Brushless or static type excitation power is provided by a
stationary-field exciter whose rotor is mounted on the generator
shaft. The excitation unit with the automatic voltage regulation
system is accommodated either in the generator itself or in a
separate panel.
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Hall marks That Make Us A Brand Output and Speed Generator
output and speed are matched to the requirements of the prime
movers. The generators are designed for a power factor of 0.8
lagging as standard, which are mechanically adequate for the
activepower component of their KVA rating. The operational safety
and strength of the generators is verified at works by a two-minute
over speed test at 1.2 times the rated speed.
Voltage and Frequency The generators are available for 50Hz or
60Hz and for rated voltages between 400V and 15000V. Using a
reference value setter, the generator voltage can be adjusted
within a range of + / - 5% of the rated voltage. This set value is
maintained by the AVR. Other frequencies & voltage adjustment
ranges are available on request.
Voltage Waveform An almost sinusoidal voltage waveform is
achieved with a special design of pole profile and suitably
designing the stator winding. Adequate short pitching of the coils
are also done to eliminate the dominating harmonics.
Output Chart 80
70
60
:g; 50 :::i1: .!: 40 .... Q) :s: 0
c... 30
20
10
0 2 4 6 8 10 12 14 16 18
Pole 20 22 24
Q) "0 c... ..... c: . Ri CI'J
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Efficiency
Capability for Unbalanced-Load Due to the fully connected damper
circuit in the pole shoe of the generator , a continuous unbalanced
load current of 8% is permissible as long as the rated current is
not exceeded in any of the phase windings. Designs for higher
continuous unbalanced load currents are available on request.
Overload Capacity The generators can be overloaded at 1.5 times
the rated current for 30s as per lEe 60034-1 as standard. Moreover
for diesel engines they can be overloaded at 110% rated output for
one hour within any 12-hour period. Other customized overloads can
be offered on request.
Elevated efficiencies are offered due to the use of low-loss
stamping materials, optimum windage and friction losses and
effective cooling circuit. To attain these values, different
computer aided analysis are carried out.
Sustained Short - Circuit Current The generators and its
excitation systems are designed to supply a sustained short-circuit
current of at least three times the rated current for a maximum
period of three seconds enabling protection systems to reliably
detect faults and to operate as well as to selectively disconnect
the affected unit.
Shaft Heavy Duty shafts are manufactured from high carbon steel
forging and are 100% ultrasonically tested to detect any
Flaws/Defects, thus ensuring long life. Spider shaft construction
with large diameter ensures very low rotor deflection, low
vibration and smooth operation.
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Insulation The stator winding copper strips are covered with
mica tape to form the inter turn insulation. The ground insulation
consists of required number of resin poor mica tape layers
depending upon required insulation level. The resin poor mica tapes
are applied all over the stretched coil. All insulated coils are
inserted in core slots, wedged & laced. The wound core is put
in VPI tank & vacuum is applied to remove the moisture. Two
component VPI resin is drawn in the VPI tank to submerge the wound
core. Pressure is applied so that resin penetrates deep in all the
coils, slots & voids. The resin is drained & the wound core
is transferred to oven for curing.
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Beyond Your Expectations
1. Custom built generators of optimum design for various
applications.
2. Compact design and light weight construction.
3. Heavy damper circuit for swift electrical response against
fluctuations in grid.
4. Sturdy mechanical construction.
5. High efficiency, maximizing power generation.
6. Skewed stator for minimizing harmonics for better voltage
wave form.
7. Minimum vibrations, noise and longer bearing life through
precisely balancing the machine to grade better than 1 of ISO
1940.
8. High overload capacity
9. Built in auxiliary winding to act as an independent power
source to AVR.
10. Rotating rectifier with fused diodes to protect diodes &
exciter armature winding during short circuit faults
11. High energy surge suppressor across main field winding to
protect it during fault condition.
12. Large size of bearing for longer life and trouble free
operations.
13. Air gap, slot profiles and slot combinations are selected to
reduce pole surface losses due to flux pulsations.
14. Low loss, insulated, non-aging, silicon steel stator
stampings are selected to reduce iron losses.
15. The conductor sizes are optimized to reduce skin effect and
eddy current losses.
16. Pole stampings are designed to reduce pole leakage.
17. Large lubricant reservoir provides sufficient clean
lubricant supply to bearings for smooth operation, protection and
longer life.
18. Stator core-plates are selected to make sure a tight and
rigid core assembly, to minimize core distortion and magnetic
noise.
19. Windings are processed through modern vacuum pressure
impregnation to ensure high level of Quality and reliability.
20. Cooling fans are aerodynamically designed to reduce noise
and windage losses
21. Abrasion-resistant coating is applied for protection against
dust and moisture.
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Stator Frame The stator frame is a rigid structure of fabricated
steel construction and designed to ensure correct distribution of
airflow over the stator core and windings.
End Frame The end frames are of fabricated steel construction.
They are spigoted to the stator frame and secured by accessible
short bolts.
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Terminals The terminals box is of ample proportions and permits
easy access to the terminals. Cable boxes are provided to house the
main terminals on one side and neutral terminals with provision for
mouting current transformer on the other. The standard main
terminals box is air insulated, designed for simplicity,
reliability and ease of connection. Alternatively phase insulated
or phase segregated main terminal box can be provided.
Rotor The rotor shaft is made from a steel forging. In case of
salient pole construction, the hub may be forged integral with
shaft or made of a separate forging (or fabrication) in which case
it may be keyed and shrunk on to the shaft. As an alternative the
hub is frequently built up from a stack of flame cut steel plates.
Bolted on poles or dovetailed poles are employed. In case of
cylindrical rotor constructions, the rotor core consists of sheet
steel stampings, hydraulically pressed, keyed and shrunk on the
shaft.
Automatic Voltage Regulator The Electronic Automatic Voltage
Regulator is a static, compact panel-mounting unit to control the
excitation of an exciter which in turn provides the field current
of an AC Generator.
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Field Coil The winding is done directly on insulated pole brick
using enameled and fibre glass covered copper conductor. During
winding procedure, resin is applied on the pole body as well as
between conductor layers. The wound coil is subsequently cured
under heat and pressure. For salient pole generators in higher
frame size insulation between turns of field coil consists of
impregnated nomex paper. Each coil is heated and subjected to
hydraulic pressure to consolidate the coil. This process ensures
that the coil is solid and that no further shrinkage will occur
under running condition. Major insulation consists of resin bonded
glass tape on the pole body and thick
washers at top and bottom made from synthetic and resin bonded
board. The coil is solidly bonded to the pole brick with a
specially formulated resin. In case of cylindrical rotor
construction, the field winding consists of field coil mounted in
slots of the rotor core. The coils are made of insulated copper
conductors. The coils are firmly held in the slots by glass epoxy
slot wedges. The coil mounted core is impregnated in epoxy resin.
Resiglass banding is provided on both the overhangs to withstand
centrifugal forces during running and over speeds also.
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Damper Winding For satisfactory parallel running, some form of
damping is necessary on the field system to prevent hunting and
periodic power swing. Damper windings are provided in laminated
poles of rotor stamping according to the construction of the
generator. This consists of copper bars brazed to form short
circuiting ring on both the sides. The damper bars are located in
slots on the pole faces.
Bearings For smaller generators antifriction bearings are used.
Sleeve bearings are used as standard for larger generators. These
are conventional circular profile white metal lined, hydrodynamic
cylindrical bearings designed to be used with light grade turbine
oil. The steel bearing bushes are split on the horizontal center
line for ease of insertion and removal. The two halves are bolted
and dowelled together. In case of higher thrust values thrust pad
bearing is offered.
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Brushless Exciter The brush less excitation system comprises a
rotating armature threephase ac generator, with six-element diode
bridge mounted on the main generator shaft usually outboard of the
non-drive end bearing. The diodes are mounted on aluminum heat
sinks and each is fused to protect the exciter armature in the
event of the failure of a diode due to a short circuit. Non linear
resistance (surge suppressor) are connected across the rotor field
winding to provide a path for negative current which can be induced
in the field under certain fault conditions to protect the rotating
diodes and field winding.
Cooling For bigger frames, radial type fans are fitted to the
rotor and are designed to direct a stream of cooling air both over
the rotor coils and the stator over hangs. The air from the rotor
passes outwards through radial ducts in the stator core into the
space at the back of the core and is then exhausted through outlets
in the stator frame.
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Earthing The stator frame is provided with two earthing
terminals.
Anti-Condensation Heaters These are mounted in the stator frame
on the underside of end windings to protect the windings while the
generator is not in operation to act against condensation.
Temperature Sensors The embedded type sensors (normally Pt 100
type Resistance Temperature Detectors) are provided for main stator
winding to monitor the winding temperature during operation.
For monitoring the temperature of bearings, Pt 1 00 type RTD or
dial type thermometers are provided.
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1 2 3 4 5 6 7 8 9
10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25
RATING IN MVA VOLTAGE FREQUENCY POLARITY RATED PF OVER / RUN
AWAY SPEED SCR AMBIENT ALTITUDE MOUNTING APPLICATION / PRIME MOVER
TYPE OF AVR VOLTAGE REGULATION BRAKES DEGREE OF PROT ECTION TYPE OF
COOLING OVERLOAD & DURATION FRAME SIZE EFFICIENCY AT RATED PF
INSULATION CLASS TYPE OF INSULATION TYPE OF COUPLING TYPE OF
BEARING & LUBRICATION TYPE OF EXCITATION TYPE OF CT
Pick Your Need Base Load
Stand by / Emergency Load
Diesel Engine Steam Turbine
Gas Turbine
Hydro Turbine MG Set
Diesel Engine Test Plant Transformer Test Plant
Rotating Electrical Machine Test Plant
1 MVA to 70 MVA 400 to 15000 Volts. 50 Hz to 200 Hz 2 to 30 Pole
0.8 to 1 1.2 to 3.2 times. 0.45 to 1.2 - 20 to 50 upto 4000 meter
Horizontal/Vertical Diesel, Steam, Hydro, Gas, MG set Analogue /
Digital +/- 0.25% Hydraulic IP 23, IP 55 IC OA1, IC6A1A1, IC8A1W7
150 % for 30 secs 500 to 2000 up to 98 % Class F VPI / Resin Rich
Rigid / Flexible Single / Double (Antifriction / Sleeve / Thrust)
Brushless / Static Metering / Protection / PS / Differential
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Marching With New Technology Turbo Generators Turbo Generators
are designed using state-of-the-art computation technology and
extensive experience of large generator units. Software implemented
on CAE/FEM systems enables CG ELECTRIC SYSTEM HUNGARY to use
advanced, fully integrated electromagnetic and mechanical design
functions linked with operating manufacturing, design and quality
control data. Stator design is based on a horizontally split
two-piece frame, which supports the stator core by means of a
bar-cage system. This facilitates stator maintenance operations.
The stator core is formed of magnetic sheet segments made of high
quality silicon steel coated on both sides with class F insulating
varnish. The rotor is supported by two sleeve pocket bearings with
white metal bushes, designed to accept a maximum axial displacement
of 30mm.
Generator Type Range : upt070 MVA
: 3,000 or 3,600 rpm : cylindrical
Two pole Rotor type V entilation Bearing type
: open or closed circuit with various coolers arrangements. :
pedestal type mounted on the frame extension.
Reference Standards GTG generators are designed and manufactured
in accordance with IEC standards at 50 Hz and 60 Hz. ANSI standards
at 60 Hz can be applied on a case by case basis to meet
electromagnetic requirements.
Rated Voltage The rated voltage is 11.5 kV for 50 Hz and 13.8 kV
for 60 Hz generators. Different voltage requirements can also be
met.
Insulation System Stator and rotor windings are insulated with
class F insulation systems.
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Phase Sequence The phase sequence is UVW in one specific
direction of rotation.
Protection Closed-ventilation generators have IP54 protection.
Open-circuit generators have the same degree of protection with the
exception of the ventilation openings which must be connected to
the air ducts according to specific layout.
Rated Output The rated output range referred to a primary
coolant temperature of 40C at 50 Hz is 20 to 32 MVA for the GTG 70
series and from 40 to 60 MVA for the GTG 81 series/and from 70 up
to 110 MVA for GTG 92 series.
Temperature Rises Class B temperature rises are considered at
rated conditions according to standard customer specifications.
Generators can also be operated at class F temperature rises. The
standard power factor is 0.8 lagging. Generators with other power
factor can also be supplied.
Short Time Capability GTG generators satisfy the short-circuit
and short time thermal requirements of the reference standards.
Unbalance Load Capability The rotors are designed to comply with
IEC and ANSI requirements in terms of b and It capability.
Voltage And Freq uency Range Generators can be operated
successfully at any voltage and frequency within the ranges
specified by the reference standards (5% voltage, 2% frequency).
Different voltage and frequency ranges can also be taken into
consideration and suitable design choices made on the basic of
other specifications including rated output, power factor and
cooling conditions.
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We Are World Wide CG Hungary
Steam Turbine Year Client, Plant QIy MVA Voltage (KV) Pole
1916 Csepel, Hungary 14 3.3 4 1922 Monceau Sur Sambre, Belgium
15.5 6.6 2 1922 Castellanza, Italy 14.3 12 2 1922 Budapest, Hungary
15 10.5 4 1925 Hengello, Netherland 24 11 2 1925 Budapest, Hungary
36 10.6 4 1925 Alest, Belgium 16 6.6 2 1926 Budapest, Hungary 12.5
5.2 2 1929 Budapest, Hungary 44 10.6 2 1935 Csepel, Hungary 19 3.3
4 1937 Tatabanya, Hungary 19.5 6.6 2 1939 Salgotarjan, Hungary 13.5
11 2 1939 Magyarovar, Hungary 10 3.15 2 1940 Tatabanya, Hungary
19.5 6.6 2 1940 Csepel, Hungary 18 10.5 2 1940 Dorog, Hungary 19.5
5.75 2 1940 Lorinczi, Hungary 3 44 10.5 2 1941 Budapest, Hungary 16
5.7 2 1942 Ajka, Hungary 2 22 10.5 2 1942 Banhida, Hungary 1 26.3
10.5 2 1948 Lorinczi, Hungary 3 44 10.5 2 1949 Csepel, Hungary 27
10.5 2 1949 Sofia, Bulgaria 17 5.75 2 1949 Moscow, U.S.S.R 15 6.6 2
1950 Lorinczi, Hungary 44 10.5 2 1950 Tatabanya, Hungary 22 6.6 2
1950 Dunaujvaros, Hungary 2 26.55 10.5 2 1950 Moscow, U.S.S.R 22
5.75 2 1950 Moscow, U.S.S.R 15 6.3 2 1950 Warszava, Poland 26.25
10.5 2 1950 Dunaujvaros, Hungary 1 26.5 10.5 2 1950 Warszava,
Poland 2 31.25 10.5 2 1951 Dunaujvaros, Hungary 17 10.5 2 1952
Budapest, Hungary 18 5.25 2 1952 Prague, Czehoslovakia 18 5.25 2
1952 Csepel, Hungary 2 18 10.5 2 1952 Budapest, Hungary 2 18 10.5 2
1952 Ujpest, Hungary 1 16 10.5 2 1952 Moscow, U.S.S.R 3 15 6.3 2
1952 Kispest, Hungary 1 18 10.5 2 1953 Moscow, U.S.S.R 3 31.25 10.5
2 1953 Moscow, U.S.S.R 2 31.25 6.3 2 1953 Hungary 3 44 10.5 2 1956
Szezeczin, Poland 3 31.25 6.3 2 1957 Bendzin, Poland 31.25 6.3 2
1957 EI Tabbin, Egypt 20 10.5 2 1958 Csepel, Hungary 22 10.5 2 1959
Beyrouth, Libanon 2 40 11 2 1959 Tiszapalkonya, Hungary 1 62.5 10.5
2 1960 Ti-Ti, China 44 10.5 2 1961 Oroszlany, Hungary 1 61 10.5 2
1961 Ti-Ti, China 3 44 10.5 2 1961 Wang-TIng, China 2 31.5 10.5 2
1961 Budapest, Hungary 23 10.5 2 1961 Desu, India 18.75 11 2 1961
AJka, Hungary 16 10.5 2 1961 Ajka, Hungary 3 44 10.5 2 1962
Oroszlany, Hungary 61 10.5 2 1962 Budapest, Hungary 2 18.5 10.5 2
1963 Lorinczi, Hungary 1 44 10.5 2 1963 Tarnow-Azoty, Poland 2 31.5
6.3 2 1963 Skolwln, Poland 20 6.3 2
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We Are World Wide CG Hungary
Steam Turbine Year Client, Plant QIy MVA Voltage (KV) Pole
1964 Ostrolenka, Poland 44 10.5 2 1964 Launa- Werke, G.D.R 1
34.5 10.5 2 1964 Tiszapalkonya, Hungary 2 17 6.3 2 1964 Poland 20
6.3 2 1964 Szolnok, Hungary 16 10.5 2 1964 Jasi, Romania 31.5 6.3 2
1964 Poland 20 6.3 2 1965 Oradea, Romania 34.5 6.3 2 1965 Budapest,
Hungary 22 10.5 2 1965 Swlecia, Poland 2 44 10.5 2 1965 Poland 13.7
6.3 2 1966 Janikova, Poland 20 6.3 2 1966 Suceava, Romania 25 6.3 2
1966 Berenta, Hungary 16 10.5 2 1967 Budapest, Hungary 31.7 10.5 2
1967 Ajka, Hungary 25 10.5 2 1968 Hungary 32.3 10.5 2 1969 Polico
II, Poland 16.1 6.3 2 1970 Ajka, Hungary 1 19.5 10.5 2 1971 Dewnja,
Bulgaria 2 27 6.3 2 1971 Ismir, Turkey 3 18 10.5 2 1972 Budapest,
Hungary 40 10.5 2 1973 Turkey 3 18 10.5 2 1974 Glogow III, Poland
31.2 6.3 2 1974 Obrovec, Yugoslavia 23.4 6.3 2 1974 Lappaenranta,
Finland 44.5 10.5 2 1974 Aliaga, Turkey 4 42.4 10.5 2 1975 Dubai
Electric Co. Dubai 2 44.5 11 2 1975 Jalkowa, Poland 25 6.3 2 1975
Lappaenranta, Finland 2 44.5 10.5 2 1975 Poland 1 16.8 6.3 2 1975
Gomlik, Turkey 2 42.4 10.5 2 1975 Neste, Finland 44.5 10.5 2 1977
Kokkola, Finland 75 10.5 2 1978 Hungary 19.3 6.3 2 1979 Aliaga,
Turkey 2 37 10.5 2 1979 Vapo, Finland 1 15.61 6.3 2 1981 Daura,
Iraq 4 46.3 11 2 1981 Dibis, Iraq 46.3 11 2 1983 Barsod, Hungary 44
10.5 2 1986 Barsod, Hungary 44 10.5 2 1986 Hungary 1 18.5 10.5 2
1987 Oroszlany, Hungary 2 68.75 10.5 2 1988 Oroszlany, Hungary 2 75
10.5 2 1990 Hungary 184.65 15.75 2 1990 Csepel, Hungary 22 10.5 2
1990 Budapest, Hungary 18 10.5 2 1991 Pori, Finland 46.6 10.5 2
1994 TAIWAN-Pali 51.25 10.5 2 1994 TAIWAN-Hsinchu 34.5 10.5 2 1995
TAIWAN-Ban yu paper 60 11.4 2 1995 INDIA-Dahej Gujarat 1 44 11 2
1995 ITALY-Tordivalle 3 51.3 11.5 2 1995 U.K.-Cleveland 29.4 11 2
1996 U.K.-Thetford 52 11 2 1997 ITALY-Montemartlnl 3 24 8.4 2 1998
ALGIRE-Boufarik 32 10.5 2 1999 SENEGAL -Cap de biches 43.125 11.5 2
1999 HUNGARY-Ujpest 50.25 10.5 2 1999 SAUD ARABIA-Arar 22.25 13.8 2
1999 U.S.A.-Albany 53 12.47 2
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We Are World Wide CG Hungary
Hydro Turbine Year Client, Plant QIy MVA Voltage (KV) Pole
1889 Austria 2 0.1 2 24 1892 Italy 6 0.33 5 36 1898 Austria 4
1.5 3.6 18 1898 Austria 2 2.5 12 18 1899 Italy 7 3.5 11 28 1902
Yugoslavia 2 3 15.5 20 1902 Austria 3 2.5 15.5 14 1902 Austria 1 4
15.5 14 1906 Italy 2 5.2 30 14 1907 Yugoslavia 4 6.6 30 14 1911
Austria 2 8 18 18 1912 Italy 2 5.2 30 26 1913 Yugoslavia 2 16 4 16
1914 Italy 2 7.5 33 18 1928 Yugoslavia 2 26 3.6 16 1941 Yugoslavia
1 1.6 3.3 6 1942 Hungary 2 3.3 5.45 24 1950 Romania 4 6.2 6.3 12
1950 Romania 2 3 6.3 10 1951 U.S.S.R 3 4.8 6.3 16 1952 Romania 3
1.7 6.3 8 1955 Hungary 3 4.8 5.25 80 1956 Bulgaria 2 5.5 6.3 8 1956
Bulgaria 2 10.5 6.3 12 1957 Turkey 3 7.25 6.3 8 1958 Poland 2 5.2
6.3 24 1958 India, Kashmir 4 5.7 6.3 12 1960 Poland 2 2.5 6.3 48
1960 Hungary 2 3.15 14 1960 Hungary 3.25 14 1961 China 5 5.2 6.3 20
1961 Poland 1 6.25 6.3 72 1966 India 3 5.833 6.6 10 1969 2 5.625 11
32 1976 Shanan, India 1 70 11 16 1977 Peru 2 38.8 13.8 16 1977
India 2 9.375 11 8 1982 India 2 4.5 6.6 12 1982 New Zealand 2 10.1
11 10 1985 India 6.25 11 16 1986 India 6.25 11 16 1993 Finland
18.75 10.5 52 1994 Finland 18.75 10.5 52
Diesel Engine 1973 Andros Power 4 2.4 6.3 12 1973 Syros-Chios
Power 4 75 10.5 14 1974 MAV, Hungary 8 2.85 0.7 4 1977 MAV, Hungary
1 2.85 0.7 4 1978 Vizmuvek, Hungary 1 2.43 0.4 6 1980 Sam as,
Greece 3 6.125 6.3 12 1981 Greece 9.13 6.3 12 1981 PPC Athen,
Greece 9.13 6.3 12 1981 MAV, Hungary 2.85 0.7 4 1982 Greece 9.13
6.3 12 1982 PPC, Greece 6 9.13 6.3 12 1984 PPC Athen, Greece 4
6.125 0.5 12 1984 PPC Athen, Greece 1 9.13 0.5 12 1986 Parks,
Hungary 2 5 6.3 4 1987 Parks, Hungary 7 5 6.3 4 1992 Girne, Cyprus
5 6.3 4 1992 Parks, Hungary 5 6.3 4
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We Are World Wide CG India
Diesel Engine Year Client, Plant QIy MVA Voltage (KV) Pole
1990 Wartsila India Khopoli 1 7.5 11 8 1991 Modi erne nt, Raipur
2 7.5 11 8 1991 Telco, Jamshedpur 2 5 11 8 1991 DCM Textiles,
Hissar 1 1.58 0.415 6 1991 Auro Spinning Mills, Baddi 1 1.58 0.415
6 1991 Float Glass India, Taloja 2 1.58 0.415 6 1991 Dandeli
Steels, Dandeli 1 2.35 11 6 1992 Tisco Cements, Sonadih 2 7.5 6.6 8
1994 Oswal Agro Chemicals, Shahajahanpur 1 2.57 0.415 6 1994 Jaypee
Rewa Cement, Rewa 2 7.75 6.6 10 1995 Orient Cement, Devapur 1 2.35
11 6 1996 Jaypee Bela Cement, Bela 4 7.75 6.6 10 1996 Sree Vishnu
Cement, Andhra Pradesh 2 5 6.6 8 1996 Float Glass India, Taloja 1
1.575 0.415 6 1997 Tisco Cements, Sonadih 1 7.5 6.6 8 1998 CPWD
Bank Note Press, Dewas 2 2 11 4 1999 Shah Alloys Ltd., Ahmedabad 2
7.2 11 12 2000 AVIS Marine, Veraval 2 3.125 11 12 2001 Reliance
Petrolium Ltd., Jamnagar 3 1.2 6.6 4 2001 Shah Alloys Ltd.,
Ahmedabad 2 7.2 11 12 2002 Vijaya Steel Ltd., Bangalore 2 3.421 11
12 2002 Powerica, Bangalore 1 1 11 4 2002 Shah Alloys Ltd.,
Ahmedabad 2 7.2 11 12
Hydro Turbine 1988 PSEB, Rohti & Thuhi, Punjab 4 0.5 0.415 8
1992 Govt. of Manipur, Khuga 3 0.625 0.415 8 1995 Surya Canal Drop,
Maharashtra 1 1 0.415 8 1995 Govt. of Arunachal Pradesh, Sirnyuk 3
1.25 3.3 6 1995 Govt. of Arunachal Pradesh, Domkhoreng 2 1.25 3.3 8
1997 TECIL, Ullunkul 2 3.89 6.6 8 1998 Govt. Of Mizoram, TEl REI 3
1.25 3.3 8 1998 Govt. of Arunachal Pradesh, Sirnyuk 1 1.25 3.3 6
2000 UP Jalvidyut Nigam, Soneprayag 2 0.313 0.415 8 2000 AP Power
Projects, Midpennar Dam 2 1.25 11 8 2000 Atria Power Ltd.,
Sivasamudram 2 3.667 11 6 2000 Indushree Power Ltd., Raskat 1 1
0.415 6 2000 NCL Energy Ltd., Hyderabad 3 3.125 6.6 8 2001 NATL
Power Ltd., Hyderabad 3 1.688 6.6 8 2001 RSI Power Ltd., Bangalore
3 1.176 3.3 8 2001 KBL Nugu - I, Mysore 2 0.938 3.3 8 2001 KBL Nugu
- II, Mysore 2 0.938 3.3 10 2001 KBL Badrinath, UP 2 0.695 0.415 6
2002 VATECH, Hanumanganga 2 1.765 3.3 4 2002 VATECH, Sitagala 2 0.5
0.415 10 2002 ALSTOM, Bhoruka Power 2 2.059 3.3 8
MG Set 1990 CGL EHV IT Division, Nashik 0.42 0.7 8 1995 CGL ,
Transformer Division, Mandideep 7.5 11 10 1995 CGL , Transformer
Division, Mandideep 3 11 16 1997 EMCO Transformers Ltd., Thane 7.5
11 10 1997 EMCO Transformers Ltd., Thane 2 11 16 1997 CGL. Motors
Division, Mandideep 2.35 3.6 6 1997 CGL, Large Machines Division ,
Mumbai 7.5 3.3 8 2002 Siemens India Ltd., Kalwa 2 0.69 4
Steam Turbine 1995 Krishna SSK, Karad, Maharashtra 1 0.415 4
1996 Sri Malaprabha Co.Sugar Factory, Hubli 1 0.415 4 2000 Guljag
Industries Ltd., Jodhpur 1.8 0.415 4
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Crompton Greaves Ltd. . .. .
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CG 6th Dr Annie Besant Road, I. I
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