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India’s first fast breeder reactor to generate power 2015-16

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India’s first fast breeder reactor to generate power 2015-16
Published May 8, 2015 | By admin
SOURCE : PTI

images


India`s 500 MW prototype fast breeder reactor (PFBR) is targeted to generate power this fiscal, parliament was told on Thursday.

The PFBR is presently under advanced stage of commissioning and is targeted to produce power in fiscal 2015-16, Minister of State in the Prime Minister`s Office Jitendra Singh told the Rajya Sabha in a written reply.

The government-owned Bharatiya Nabhikiya Vidyut Nigam Ltd (BHAVINI) is setting up the country`s first indigenously designed 500 MW PFBR at Kalpakkam, around 80 km from Chennai.

A breeder reactor is one that breeds more material for a nuclear fission reaction than it consumes. The PFBR will be fuelled by a blend of plutonium and uranium oxide, called MOX fuel.

BHAVINI will be constructing two more fast breeder reactors (FBR 1&2) of 600 MW capacity each at Kalpakkam, Singh said.

In addition to projects already under construction, financial sanction has been accorded for construction of two indigenous reactors, he added.

The two projects are: Gorakhpur Haryana Anu Vidyut Pariyojana Units 1&2 (GHAVP 1&2) (2X700 MW) by Nuclear Power Corporation of India Limited (NPCIL) at Gorakhpur, Haryana.

Two more reactors at Kudankulam (Kudankulam Nuclear Power Project 3&4) in Tamil Nadu would be built with Russian help, he said.

During the last three fiscals, a total sum of Rs.1,459 crore has been allotted for the KNPP 3&4 projects and Rs.787 crore for the GHAVP`s two units, he said.

A sum of Rs.27.60 crore was allotted during 2013-14 for the two FBR projects at Kalpakkam.

To another question, Singh said the second unit of KNPP is under commissioning and expected to start power generation in 2015-16.

He said the two new units at Kakrapar Atomic Power Project each with a capacity of 700 MW under construction is anticipated to be completed in 2017-18.

The two new units (700 MW each) under construction at Rajasthan Atomic Power Project (RAPP) is anticipated to be completed in 2018-19.

India’s first fast breeder reactor to generate power 2015-16 | idrw.org
 
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so that s about 1500mw production in TN to start this fiscal,
hopefully there wont be even a hour of power cuts anymore ..:-)
 
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India’s first fast breeder reactor to generate power 2015-16
Published May 8, 2015 | By admin
SOURCE : PTI

images


India`s 500 MW prototype fast breeder reactor (PFBR) is targeted to generate power this fiscal, parliament was told on Thursday.

The PFBR is presently under advanced stage of commissioning and is targeted to produce power in fiscal 2015-16, Minister of State in the Prime Minister`s Office Jitendra Singh told the Rajya Sabha in a written reply.

The government-owned Bharatiya Nabhikiya Vidyut Nigam Ltd (BHAVINI) is setting up the country`s first indigenously designed 500 MW PFBR at Kalpakkam, around 80 km from Chennai.

A breeder reactor is one that breeds more material for a nuclear fission reaction than it consumes. The PFBR will be fuelled by a blend of plutonium and uranium oxide, called MOX fuel.

BHAVINI will be constructing two more fast breeder reactors (FBR 1&2) of 600 MW capacity each at Kalpakkam, Singh said.

In addition to projects already under construction, financial sanction has been accorded for construction of two indigenous reactors, he added.

The two projects are: Gorakhpur Haryana Anu Vidyut Pariyojana Units 1&2 (GHAVP 1&2) (2X700 MW) by Nuclear Power Corporation of India Limited (NPCIL) at Gorakhpur, Haryana.

Two more reactors at Kudankulam (Kudankulam Nuclear Power Project 3&4) in Tamil Nadu would be built with Russian help, he said.

During the last three fiscals, a total sum of Rs.1,459 crore has been allotted for the KNPP 3&4 projects and Rs.787 crore for the GHAVP`s two units, he said.

A sum of Rs.27.60 crore was allotted during 2013-14 for the two FBR projects at Kalpakkam.

To another question, Singh said the second unit of KNPP is under commissioning and expected to start power generation in 2015-16.

He said the two new units at Kakrapar Atomic Power Project each with a capacity of 700 MW under construction is anticipated to be completed in 2017-18.

The two new units (700 MW each) under construction at Rajasthan Atomic Power Project (RAPP) is anticipated to be completed in 2018-19.

India’s first fast breeder reactor to generate power 2015-16 | idrw.org

Congrats
 
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We need to generate more electricity such that we have surplus and can export it to earn revenue.
 
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India's FAST BREEDER TEST REACTOR (FBTR)


Reactor core

The core consists of 745 closely packed locations, with fuel at the centre, surrounded by nickel reflectors, thoria blankets and steel reflectors. The core is vertical and freestanding, with the subassemblies supported at the bottom by the Grid Plate and held on to the latter by collapsible hold-down springs. The subassemblies are hexagonally shaped.
image003.jpg
As per the initial design, the core was rated for 40 MW t and had 65 fuel subassemblies, three test steel subassemblies, six control rods, 143 nickel reflectors, 342 thoria blankets and 163 steel reflector subassemblies. In addition, there are 23 storage locations in the outermost steel reflector row.
The core consists of 745 closely packed locations, with fuel at the centre, surrounded by nickel reflectors, thoria blankets and steel reflectors.

The core is vertical and freestanding, with the subassemblies supported at the bottom by the Grid Plate and held on to the latter by collapsible hold-down springs. The subassemblies are hexagonally shaped. As per the initial design, the core was rated for 40 MW t and had 65 fuel subassemblies, three test steel subassemblies, six control rods, 143 nickel reflectors, 342 thoria blankets and 163 steel reflector subassemblies. In addition, there are 23 storage locations in the outermost steel reflector row.


Reactor Assembly
The Reactor Vessel houses the core and serves as a conduit for the primary sodium coolant flow through the core. Charging and discharging of subassemblies are done from the reactor top with the reactor in shutdown state. The reactor assembly consists of a cylindrical stainless steel vessel enclosed by its stainless steel double envelope. The interspace between main vessel and its double envelope is filled with inert gas nitrogen.

The sodium inlet pipe joins the
image009.jpg
Reactor Vessel at the bottom and two sodium outlet pipes radially branch out of the vessel above the core. The reactor is closed at the top by Large and Small Rotatable Plugs, which serve as top shields and also enable access to the core locations for fuel handling. The Rotatable Plugs are cooled by nitrogen. Liquid Metal Seals of Tin�Bismuth alloy, backed with Inflatable Seals, isolate the reactor cover gas from the Reactor Containment Building atmosphere. The Liquid Metal Seals are frozen during reactor operation and melted during rotation of the plugs. The space between the Liquid Metal Seals and the Inflatable Seals, called the Interseal Space, is maintained in argon at a pressure higher than the reactor cover gas to prevent the leakage of active cover gas into the reactor building.


The Small Rotatable Plug houses the Control Plug which carries six Control Rod Drive Mechanisms and Core Cover Plate with thermocouples for monitoring the outlet temperatures of the fuel subassemblies. Ten neutron shields, each 25 mm thick, surround the core and minimize the incident flux on the Reactor Vessel. Thermal shields are provided inside the Reactor Vessel to minimize the thermal stresses due to cold and hot shocks. The radial and axial shifts of the Grid Plate are monitored by two displacement measuring devices. A steel vessel with thermal insulation surrounds the Reactor Vessel. Radial shielding is provided by borated concrete and structural concrete. The borated concrete is cooled by water pipes embedded close to its inner periphery. The entire Reactor Assembly is suspended from the top, with the load taken by structural concrete. The reactor is closed at the top by the Anti-Explosion Floor, which is bolted to tie-rods anchored on the structural concrete the reactor building.


Sodium systems
FBTR uses liquid sodium as coolant, which is reactive with air or water. Maintenance of nuclear grade purity of the coolant is very important to minimize corrosion of structural materials and also avoid plugging of narrow flow passages in the reactor core and coolant circuits. This is achieved by controlling the routes for impurity ingress mainly through the inert argon cover gas and sodium pump seals and also by on-line purification and monitoring system to limit oxygen (<10 ppm), hydrogen (<2 ppm) and carbon (<30 ppm) impurities in sodium.

Primary sodium is pumped into the reactor by primary sodium pumps and flows by gravity to the intermediate heat exchangers and then back to the pump suction. The intermediate heat exchangers are vertical, counter-flow heat exchangers and transfer heat from the active primary sodium to the inactive secondary sodium. Primary sodium flows on the shell side and secondary sodium on the tube side. The shell is fixed and the tube bundles are removable.
Secondary sodium is pumped into the intermediate heat exchangers by secondary sodium pumps. After removing heat from primary sodium, the secondary sodium enters the steam generators. A surge tank is interposed between the intermediate heat exchangers and steam generators as a buffer against pressure wave transmission to intermediate heat exchangers during sodium�water reaction in steam generators due to any water leaks. The four sodium pumps are vertical, single stage centrifugal pumps with axial suction and radial discharge. Each pump has a fixed shell and a removable assembly comprising the impeller, diffuser and shaft. The shaft is supported by taper roller bearings at the top and guided by hydrostatic bearings at the bottom. The four sodium pumps have logged cumulative operation of 5,50,000 h without any major intervention.


image023.jpg
For safety reasons, there are no valves in the primary sodium main loop. Flow control is by controlling the speeds of the pumps. The pumps are driven by dc motors and powered by Ward Leonard drives. Flywheels mounted on the Ward Leonard drives provide sufficient inertia to run the pumps to ensure that fuel clad hot spot temperature is within limits in the event of power failure. The pump drives are provided with emergency power supply from the station diesel generators and battery backup is provided for the primary pump drives to provide adequate flow for safe removal of decay heat.

All the sodium capacities are provided with an inert cover of argon above the free sodium levels. Argon purity is maintained through NaK bubblers. Both primary and secondary sodium systems are provided with cold traps for sodium purification. Plugging indicators monitor sodium purity.

image027.jpg
The steam generator modules are of once-through, counter-flow type, with sodium entering the shell side from top and water entering the tube side from bottom. The modules have a serpentine configuration, with evaporation and superheating occurring in a single pass. Due to the absence of blow-down, feed water chemistry is maintained within very stringent limits. The steam generator modules are housed inside an insulated casing. By opening the trap doors of the casing, it is possible to remove decay heat from the reactor by natural convection.


image034.jpg
The entire primary sodium circuit is provided with a nitrogen-filled envelope called Double Envelope, designed to minimize the sodium level drop in the reactor in the event of any sodium leak. The annular gap between the Reactor Vessel and its Double Envelope is used for emergency cooling of the core during the very-low-probability incident of simultaneous rupture of coolant boundary and its Double Envelope outside the reactor. Nitrogen is also used for sodium fire fighting in the cells housing the primary sodium system in the unlikely event of failure of the main coolant boundary and its Double Envelope


Generating plant
The steam�water circuit consists of all the equipment in a conventional power plant. An on-line condensate polishing
image035.jpg
unit meets the stringent feed water chemistry requirements of the once-through steam generators. A cooling tower cooled by induced draft fans serves as terminal heat sink. The turbine is a single cylinder, 16 stage, non-reheat condensing turbine and is designed to produce 16.4 MWe with 72.5 t/h flow of superheated steam at 120 kg/cm2 and 480 �C. The generator is rated for 19.3 MV A, 6.6 kV, 3φ, 50 Hz, 0.85 pf, 3000 rpm. The rotor is air-cooled with a closed circuit. The generator field is powered by a shaft driven exciter rated for 110 kW and 220 V (DC).


Instrumentation and control
The reactor power control and shutdown are by six control rods. For shutdown, the rods are inserted into the core in two modes, i.e., lowering of rods, wherein all the rods are driven down by the respective drive mechanisms, and scram, wherein all the rods drop down by gravity.

A Central Data Processing System processes the core outlet temperatures of individual fuel subassemblies and generates reactor trip signals to limit fuel and clad hotspot temperatures.
Sodium levels in the capacities are monitored by continuous and discontinuous level probes. Flows are monitored by permanent magnet type electro-magnetic flow meters. Sodium leak is detected by spark plugs, wire type and ionization types of detectors.

Water leak into sodium in the steam generator at the incipient stage is detected by Steam Generator Leak Detection System to measure hydrogen in sodium in ppb levels. Medium leaks are detected by monitoring the expansion tank cover gas pressure. Quick closing valves isolate the steam generators on the sodium and water sides in the event of large leaks and rupture discs provided in the sodium headers relieve pressure build up.

Component handling
Fuel handling is done off-line using Charging and Discharging Flasks. There are special flasks forandling of control rod drives, irradiation devices, pumps and intermediate heat exchangers. For moving the active components between Reactor Containment Building and the adjacent Active Building, there is a Secondary Flask, which moves on rail carriages. Spent fuel is stored in air-cooled cast iron blocks

Auxiliary systems
image037.jpg
Station auxiliaries comprise the Service and Circulating Water System for heat removal from main and dump condensers and other heat exchangers, fire water system, chilled water system, compressed air system to provide service, instrument and mask air, service argon system, service nitrogen system with a Pressure Swing Adsorption nitrogen plant and Horton sphere, Air-conditioning and Ventilation System, make-up Demineralised water plant and auxiliary boiler

Construction, Commissioning and Operation Summary

Components were manufactured by Indian industries, and were installed in 1984. Commissioning was done in phases. Initially, the primary and secondary sodium systems were commissioned, without the steam generators in place. The reactor was made critical on 18th October 1985 and low power physics experiments were conducted. Steam generator modules were then connected to the secondary sodium circuits.

Reactor was operated up to a maximum power of 1 MW t till 1992 for intermediate power physics and engineering experiments. The steam�water circuit was commissioned, steam generators were put in water service and power was raised to 8 MW t in January 1993. After completing high power physics and engineering experiments, power was raised to 10.2 MW t, generating superheated steam suitable for admission to the turbine-generator. After completing the commissioning activities of TG and auxiliaries, power was raised to 11.5 MW t and the turbine-generator was synchronised to the grid in July 1997.The reactor has operated upto a power level of 17.4 MWt/2.2MWe

Mixed carbide fuel, being a unique fuel of its kind without any irradiation data, it was decided to use the reactor itself as the test bed for this driver fuel. Hence, the core was redesigned as a small carbide core. As against the original design of 65 MOX fuel subassemblies rated for 40 MW t, the small carbide core had 22 fuel subassemblies with 70% PuC and 30% UC composition (designated as Mark-I fuel) during first criticality. This small carbide core was rated for 10.2 MW t, with the peak linear heat rating limited to 250 W/cm. The core has since been progressively enlarged by adding fuel subassemblies to compensate for reactivity loss due to burn-up.

With a view to raise the reactor power to 40 MW t, it was decided, in 1995, to go in for a full carbide core of 78 fuel subassemblies. The fuel composition chosen was 55% PuC + 45% UC (designated as Mark-II fuel). Fuel subassemblies of Mark-II composition were inducted in 1996. A gradual transition to the full carbide core was envisaged. The Mark-I fuel in the centre was retained to continue the irradiation for assessing its ultimate burn-up capability before phasing it out. Mark-II fuel was added at the periphery. The allowable peak linear heat rating of the Mark-I fuel has also been revised up to 400 W/cm based on the fuel performance. The reactor power for the small carbide core has been progressively increased, reaching the highest power of 17.4 MW t in 2002. Table 2 gives the cumulative performance statistics of the reactor as of 30 th September 2005. Thirteen irradiation campaigns have so far been completed.

Milestones
18th October 1985 First criticality
November 1989 Sodium valved in into SG
January 1993 Water valved in into SG
December 1993 Power raised to 10.5 MWt
1994-1995 Safety related Engineering Experiments
May 1996 Mark-I burn-up of 25 GWd/t
July 1997 TG synchronized to grid
1998 � 1999 Zr-Nb irradiation for PHWR
April 1999 Mark-I burn-up of 50 GWd/t
March 2002 Power raised to 17.4 MWt
September 2002 Mark-I burn-up of 100 GWd/t
July 2003 Start of PFBR Test Fuel Irradiation
October 2005 Mark-I burn-up of 150 GWd/t

Table -2

Summary of performance statistics from 1985 (up to 13th irradiation campaign)

Parameter Cumulative value since first criticality
Maximum power (MW t/MWe) 17.4/2.8
Maximum linear heat rating (W/cm) 400
Bulk sodium temperature (�C) 444
Operating time (h) 37,808
Thermal energy produced (MWh) 2,76,026
Electrical energy generated (Million Units) 5.4
TG synchronisation time (h) 5228
Peak burn-up (GW d/t) 155
Longest operating campaign (d) 54
No. of lowering of rods 238
No. of scrams 157
 
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Once operational it will produce 140 kg weapon grade plutonium every year. And we have 6 such reactors planned in next 10 years or so.

fast breeder reactors are needed for our proposed thorium reactors & also nuclear subs i think, not just weapons
we dont need more than 100 nukes..
 
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These are a part of ( Stage 2 ) of the 3 Stage Electricity Production plan using Thorium as Fuel.
The Grand vision of Bhabha.
 
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we will never have a surplus
plus who are we going to sell to ?
Bangladesh, nepal, Pakistan, Burma etc etc..there are many to get revenue from. More over even if there is no export, we should be self reliable and production should be more than consumption in order to reduce the overall cost of running a power project.
 
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Once operational it will produce 140 kg weapon grade plutonium every year. And we have 6 such reactors planned in next 10 years or so.

And that is sufficient to make 30 Nuclear bomb each reactor or fuel our nuclear sub or Aircraft career. 10 reactor means 300 Nuclear bomb fissile materials per year from Fast breeder reactor per year. This is simply great.
 
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Sad that present day Indians could not salvage the unlimited nuclear fusion energy technology blueprints from their ancient Vedic Hindu ancestors... All burnt in one of the wars of the Mahabharata.
 
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