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India:1'st Full Prototype Tokamak Fusion Reactor Successfully Commissioned

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India:1'st Full Prototype Experimental Tokamak Fusion Reactor Successfully Commissioned on 20'th June 2013 at Institute of Plamsa Research .

Announcement of Successful Commissioning of SST-1 during speech at IAEA meeting on September 18. 2013 by chairman of Atomic Energy Commission .

See page 6 following press release...

http://www.barc.gov.in/presentations/57gc_chairman_speech_170913.pdf

India:1'st Full Prototype Experimental Tokamak Fusion Reactor Successfully Commissioned on 20'th June 2013 at Institute of Plamsa Research .


http://www.barc.gov.in/presentations/57gc_chairman_speech_170913.pdf





http://dae.nic.in/?q=node/255



Steady State Super-conducting Tokamak SST-1


Y.C.Saxena and D.Bora
Institute for Plasma Research, Gandhinagar, Gujarat In India, scientific research in tokamak plasmas has been continuing for more than a decade now. In tokamaks, the plasma is formed by an electrical breakdown in an ultra high vacuum toroidal vessel and a current is inductively driven in the plasma. As the plasma temperature rises the efficiency to heat the plasma drops. To further raise the temperature of the plasma to fusion grade, one has to use auxiliary heating schemes. During experimentation at high temperatures, it is also required to diagnose the plasma with various sophisticated diagnostic tools. Inherent drawback for future uses is the pulsed nature of tokamaks. One of the areas of research, therefore, has been steady state operation of tokamaks.



A steady state superconducting tokamak, SST-1, is in advanced stage of fabrication at the Institute for Plasma Research, Gandhinagar. The objectives of SST-1 include :



To study physics of plasma Processes in tokamak under steady-state conditions & contribute to the tokamak physics database for very long pulse operations.
Learning new technologies relevant to steady state tokamak operation.
Superconducting magnets and associated power supplies and protection system.
Large scale cryogenic system (Liquid helium and liquid nitrogen).
High Power Radio Frequency Systems.
Energetic Neutral Particle Beams.
High heat flux handling.


The machine has a major radius of 1.1 m, minor radius of 0.20 m, a toroidal field of 3.0 Tesla at plasma centre and a plasma current of 220 kA.



Controlled thermonuclear fusion is one of the attractive futuristic sources of energy. All over the world, the research in this field of energy has been continuing for the last fifty years.
Research efforts in this area are broadly divided into inertial confinement and magnetically confined plasmas. Among the magnetically confined systems, Tokamaks have been the most successful machines to achieve the technological goals .
In India, the scientific research in tokamak plasmas has been continuing for more than a decade now.
The tokamak Aditya developed at the Institute for Plasma Research, Gandhinagar, Gujarat, is one of the milestones of this endeavour. A steady state super-conducting tokamak, SST-1 is in advnced stage of fabrication at the Institute. Present here is the status of this venture.


Superconducting coils for both toroidal field and poloidal field are to be deployed in the SST-1 tokamak. NbTi superconductor at 4.5K is used for the superconducting magnets and maximum field at the conductor is restricted to 5.1 Tesla. An ultra high vacuum compatible vacuum vessel, placed in the bore of the toroidal field coils, houses the plasma facing components. A high vacuum cryostat encloses all the superconducting coils and the vacuum vessel. Liquid nitrogen cooled thermal shield between the vacuum vessel and superconducting coils as well as between cryostat and the superconducting coils reduce the radiation heat load on the superconducting coils.





The sketch showing relative positions of various components.



Normal conductor ohmic transformer system is provided to initiate the plasma and sustain the current for initial period. A pair of vertical field coils is provided for circular plasma equilibrium at the startup stage of the plasma. A set of saddle coils placed inside the vacuum vessel provide fast vertical control of the plasma while poloidal field coils are to be used for shape control. Other subsystems include radiofrequency systems for pre-ionization, current drive and heating, neutral beam injection system for supplementary heating, cryogenic systems at liquid helium and liquid nitrogen temperatures, chilled water system for heat removal from various subsystems. A large number of diagnostics for plasma and machine monitoring will be deployed along with a distributed data acquisition and control system.



The above three dimensional sketch shows the relative positions of various components.



All superconducting coils have been successfully fabricated using a cable-in-conduit conductor (CICC) based on niobium-titanium (NbTi) and copper. The CICC has been fabricated by a Japanese firm under specification and supervision of IPR. In order to test the performance of this CICC under SST-1 operating scenarios, a Model Coil was designed, fabricated and tested at Kurchatov Institute(KI), Russia using the SST-1 CICC. The results obtained from these model coil tests have validated the CICC design parameters as well as its appropriateness as the base conductor for the SST-1 superconducting magnet systems.



The toroidal field coils are encased in a stainless steel casings to take care of forces acting on the coils. The coils and the casings have been manufactured by the Bharat Heavy Electicals Ltd., Bhopal with specifications and supervision from IPR. Such large size superconducting coils have been manufactured for the first time in the country. An insulation system, compatible with low temperature (4.5K) operation of these coils, and the winding technologies have been indigenously developed for these superconducting coils.



The superconducting magnet system, consisting of toroidal field and poloidal field coils, in SST-1 has to be maintained at 4.5 K in presence of steady state heat loads. In addition, the pulsed heat loads during the plasma operation have to be taken care of by the cooling system so as to maintain the magnets in superconducting state.



The magnets will be cooled using forced flow of supercritical helium through the void space in the CICC. Further the magnets have to be energized from power supplies at room temperature. A closed cycle 1 kW class He refrigerator/liquefier, has been deployed for this purpose The system is at present under commissioning tests at IPR. He gas management system, including high pressure and medium pressure storage vessels and recovery system, required for the He refrigerator/liquefier, has been commissioned. This is the biggest liquid helium system in the country at present.



In order to minimize the heat loads on magnets and support system at 4.5 K, liquid nitrogen shields are provided between the cold mass at 4.5 K and warmer surfaces. A liquid nitrogen management system, including liquid nitrogen storage and distribution system, has been commissioned for this purpose. An integrated flow distribution system for distribution of cryogens to magnets and radiation shield has been installed and is in final stages of testing.



SST-1 has two vacuum chambers, (i) Vacuum vessel for plasma production and confinement, and (ii) Cryostat for enclosing all superconducting magnets. Vacuum vessel is a toroidally continuous single wall metallic structure made of SS 304L material. The poloidal cross-section of the vessel is close to ‘D’ shape. Vacuum vessel is designed and fabricated for ultra high vacuum operation. Cryostat is toroidally continuous sixteen sided polygonal vacuum chamber which encloses vacuum vessel and all superconducting magnets. Cryostat is designed and fabricated for high vacuum operation.





Full scale prototype of SST-1 cryostat and Vacuum vessel



Commissioning and operational requirements of vacuum vessel and cryostat demand for high dimensional accuracy, special in-situ welding procedures, very high surface finish etc. It was essential to establish all fabrication techniques, manufacturing of appropriate tools and fixtures, detail inspection/testing stages and procedures etc.; before commencing the fabrication of main vacuum vessel and cryostat. For this 45º toroidally continuous full scale Prototype Vacuum vessel and Cryostat has been successfully fabricated and tested for its functional parameters. All the components of SST-1 vacuum vessel and cryostat are at the final stage of completion at M/s BHEL,Tiruchirappali. The SST-1 Vacuum vessel is the largets ultra high vacuum vessel being fabricated in the country.



During normal pumping and baking/wall conditioning, vacuum vessel will be pumped with 10,000 l/s net pumping speed using two turbromolecular pumps and 10,000 l/s net pumping speed for water vapor and condensable vapors using two cryopumps. During plasma discharge vacuum vessel will be pumped with 62,000 l/s net hydrogen pumping speed using 16 nos. of turbomolecular pumps (8 nos. each for top and bottom divertors).



Cryostat will be pumped with 10,000 l/s net pumping speed using two turbomolecular pumps. However, all surfaces at cryogenic temperature (less than 80 K) will provide large pumping speed for all gases except hydrogen and helium.



The Plasma Facing Components of SST-1, comprising divertors & baffles, poloidal limiters and passive stabilizers, are designed to ensure steady state heat removal capability. Particle removal in steady state is also a major concern. Plasma facing components are made of graphite tiles backed by copper alloy plates with cooling channels. One of the important aspects of the fabrication of the plasma facing components is identifying a suitable process to braze the SS tube in the grooves of the copper alloy heat sinks and regaining the mechanical strength after the brazing. This has been done for Cu-Cr-Zr and Cu-Zr alloys. The graphite material has been tested for heat removal capability in a prototype experiment by irrdiating it by CO2 laser at CAT, Indore. Suitability of mechanical joining of the graphite tiles to the heat sink also has been tested using the same high power laser. Fabrication of the plasma facing components is underway.



High Power Radio Frequency Systems



SST-1 will have three different high power radio frequency systems to additionally heat and non-inductively drive plasma current to sustain the plasma in steady state for a duration of up to 1000 sec. Ion Cyclotron Resonance Frequency system would operate in a range between 22 to 91MHz to accommodate various heating schemes at 1.5 Tesla and at 3.0 Tesla operation of SST-1. The same system would also be used for initial breakdown and wall conditioning experiments. Fast wave current drive in the centre of the plasma is also planned at a later stage. A multi-stage 1.5 MW continuous wave radio frequency system is being built to meet these goals. All the system components require active cooling. Lower hybrid current drive system is being prepared at 3.7 GHz. The system is based on two 500 kW, continuous wave Klystrons with four outputs. Power at these arms are further divided successively to sixty four channels which then finally delivers the power to a grill type window positioned at the equatorial plane on a radial port at the low field side of SST-1. Electron Cyclotron Resonance Heating system is based on a 200 kW, continuous wave gyrotron at 82.6 GHz. Beam launching systems have been designed, fabricated and tested for microwave compatibility for radial and top launch. The system would be used for initial break down and heating of the plasma. Localized current drive would also form a part of experimentation.



Crucial transmission line components of all the three systems have been tested for high power long duration operation on respective dummy loads. Notable are the high power components that have been developed for continuous wave operation. Some of these are water cooled transmission line components for MHz range operation, direction couplers, water dummy loads, transformers at 3.7 GHz and other passive high power continuous wave components. The systems are being erected and some of the subsystems have been successfully commissioned. Radio frequency systems will be integrated to the machine after the machine shell has been tested for ultra high vacuum compatibility.



Auxiliary Heating System



A Neutral Beam Injection with peak power of 0.8 MW with variable beam energy in range of 10-80 keV will be used as additional auxiliary heating system. The engineering designs have been completed and a number of proto-types for various critical components are under development to establish the fabrication methodology. Quantified results have been obtained in many of the prototyping activities. Notable among them is the successful performance demonstration of the country’s first indigenously designed, engineered and fabricated cryocondensation pump for a pumping efficiency of 105 l/s for deuterium at 4.2 K liquid helium temperature yielding a specific pumping speed of ~ 7 l/s/cm2. Results from other prototypes have been equally encouraging. These include successful testing of electroforming of OFHC copper on a similar base; development, manufacture and tests of 80kV compact post insulator dissimilar material jointing between the heat Cu-Cr-Zr and SS 316 l by explosive bonding and vacuum brazing for the fabrication of heat transfer elements.



Similar achievements have been registered in the larger systems that include the design, fabrication and installation of the country’s largest rectangular (~ 20 m3) vacuum vessel; design, development and testing of 26 units of 160 V / 100 A discharge power supplies with fast turn On and turn Off AC-DC converters; development of VXI based data acquisition system; development of 16 channel multiplexer cards for the 700 channels of data acquisition; fabrication and testing of a computer controlled movement system for the neutral beam power dump.



Plasma Diagnostics



A large number of plasma diagnostics will be deployed on SST-1. These are at various stages of design, fabrication and testing.



Main Machine Support



The main machine support comprises 16 columns, supporting the base frame of the cryostat and the cold mass, which are firmly grouted to ground. The cryostat support frames interface with the central columns which additionally provide support for central solenoid of Ohmic transformer. The cold mass support is provided on eight columns with liquid nitrogen cooled intercept, kept in vacuum and supported on the main columns at the base. A ring with cantilever beams rests on the cold mass support columns. The toroidal field coils freely rest on these beams. The toroidal field casings are nosed in the inner leg and form a rigid vault. Outer inter coil structures between the toroidal field coils provide the rigidity against the turning moments on outer side. The poloidal field coils are supported on the toroidal field coil assembly.



Power Supplies



The power for the different subsystems of SST-1 will be derived from a 132kV line. The 132 kV to 11 kV sub-station has been upgraded to cater to the entire needs of SST-1. The DC power supplies and protection systems for magnets have been designed and are under procurement.



Component Assembly



SST-1 tokamak has a large number of components to be assembled at site to build various systems like machine support structure, plasma chamber, cryostat, magnet system, first wall (plasma facing components) and other auxiliary systems. In this device the required assembly tolerances are in the order of several tenth of a millimeter. The tight installation tolerances, definite assembly sequences and process restrictions govern the efficacy of the assembly procedures. SST-1 assembly demands definite sequence to be followed to ensure sequential testing of each system, accurate positioning of the components in the radial, toroidal, poloidal and vertical direction to meet the tolerances and magnetic axis determination and alignment of the plasma facing components.



To assure compliance with assembly requirement and to minimize the subsequent corrective operations, the assembly plan has been defined. Comprehensive survey of the Tokamak hall and fixation of reference target plates using electronic coordinate determination system (ECDS) has been completed. A machined template, defining the position of the foundation bolts precisely, has been fabricated and used for the preparation of foundation & grouting of the bolts. The support structure has been erected and further assembly of the machine is in progress.



Conclusion



In conclusion, most of the components of SST-1,namely, the cryostat and the vacuum vessel have been successfully prototyped and tested. Various other subsystems such as different magnetic field coils, plasma facing components have been, fabricated and are in the process of erection and commissioning at site. Different components of the auxiliary heating and current drive systems have also been fabricated and tested. The systems would be integrated to the machine after the machine shell commissioning is over.
 
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Tokamak - Wikipedia, the free encyclopedia



Tokamak


From Wikipedia, the free encyclopedia


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A tokamak is a device using a magnetic field to confine a plasma in the shape of a torus. Achieving a stable plasma equilibrium requires magnetic field lines that move around the torus in a helical shape. Such a helical field can be generated by adding a toroidal field (traveling around the torus in circles) and a poloidal field (traveling in circles orthogonal to the toroidal field). In a tokamak, the toroidal field is produced by electromagnets that surround the torus, and the poloidal field is the result of a toroidal electric current that flows inside the plasma. This current is induced inside the plasma with a second set of electromagnets.

The tokamak is one of several types of magnetic confinement devices, and is one of the most-researched candidates for producing controlled thermonuclear fusion power. Magnetic fields are used for confinement since no solid material could withstand the extremely high temperature of the plasma. An alternative to the tokamak is the stellarator.

Tokamaks were invented in the 1950s by Soviet physicists Igor Tamm and Andrei Sakharov, inspired by an original idea of Oleg Lavrentiev.[1]

The word tokamak is a transliteration of the Russian word токамак, an acronym of either "тороидальная камера с магнитными катушками" (toroidal'naya kamera s magnitnymi katushkami)—toroidal chamber with magnetic coils, or "тороидальная камера с аксиальным магнитным полем" (toroidal'naya kamera s aksial'nym magnitnym polem)—toroidal chamber with axial magnetic field.[2]



Contents
[hide] 1 History
2 Toroidal design
3 Plasma heating 3.1 Ohmic heating
3.2 Neutral-beam injection
3.3 Magnetic compression
3.4 Radio-frequency heating

4 Tokamak cooling
5 Experimental tokamaks 5.1 Currently in operation
5.2 Previously operated
5.3 Planned

6 See also
7 Notes
8 References
9 External links

History[edit]

Although nuclear fusion research began soon after World War II, the programs in various countries were each initially classified as secret. It was not until after the 1955 United Nations International Conference on the Peaceful Uses of Atomic Energy in Geneva that programs were declassified and international scientific collaboration could take place.

Experimental research of tokamak systems started in 1956 in Kurchatov Institute, Moscow by a group of Soviet scientists led by Lev Artsimovich. The group constructed the first tokamaks, the most successful being T-3 and its larger version T-4. T-69 was tested in 1968 in Novosibirsk, conducting the first ever quasistationary thermonuclear fusion reaction.[3]

In 1968, at the third IAEA International Conference on Plasma Physics and Controlled Nuclear Fusion Research at Novosibirsk, Soviet scientists announced that they had achieved electron temperatures of over 1000 eV in a tokamak device. British and American scientists met this news with skepticism, since they were far from reaching that benchmark; they remained suspicious until laser scattering tests confirmed the findings next year.

Toroidal design[edit]





Tokamak magnetic field and current. Shown is the toroidal field and the coils (blue) that produce it, the plasma current (red) and the poloidal field produced by it, and the resulting twisted field when these are overlaid.
Positively and negatively charged ions and negatively charged electrons in a fusion plasma are at very high temperatures, and have correspondingly large velocities. In order to maintain the fusion process, particles from the hot plasma must be confined in the central region, or the plasma will rapidly cool. Magnetic confinement fusion devices exploit the fact that charged particles in a magnetic field experience a Lorentz force and follow helical paths along the field lines.

Early fusion research devices were variants on the Z-pinch and used electrical current to generate a poloidal magnetic field to contain the plasma along a linear axis between two points. Researchers discovered that a simple toroidal field, in which the magnetic field lines run in circles around an axis of symmetry, confines a plasma hardly better than no field at all. This can be understood by looking at the orbits of individual particles. The particles not only spiral around the field lines, they also drift across the field. Since a toroidal field is curved and decreases in strength moving away from the axis of rotation, the ions and the electrons move parallel to the axis, but in opposite directions. The charge separation leads to an electric field and an additional drift, in this case outward (away from the axis of rotation) for both ions and electrons. Alternatively, the plasma can be viewed as a torus of fluid with a magnetic field frozen in. The plasma pressure results in a force that tends to expand the torus. The magnetic field outside the plasma cannot prevent this expansion. The plasma simply slips between the field lines.

For a toroidal plasma to be effectively confined by a magnetic field, there must be a twist to the field lines. There are then no longer flux tubes that simply encircle the axis, but, if there is sufficient symmetry in the twist, flux surfaces. Some of the plasma in a flux surface will be on the outside (larger major radius, or "low-field side") of the torus and will drift to other flux surfaces farther from the circular axis of the torus. Other portions of the plasma in the flux surface will be on the inside (smaller major radius, or "high-field side"). Since some of the outward drift is compensated by an inward drift on the same flux surface, there is a macroscopic equilibrium with much improved confinement. Another way to look at the effect of twisting the field lines is that the electric field between the top and the bottom of the torus, which tends to cause the outward drift, is shorted out because there are now field lines connecting the top to the bottom.

When the problem is considered even more closely, the need for a vertical (parallel to the axis of rotation) component of the magnetic field arises. The Lorentz force of the toroidal plasma current in the vertical field provides the inward force that holds the plasma torus in equilibrium.

This device where a large toroidal current is established (15 Mega-amps in ITER) suffers from a fundamental problem of stability. The nonlinear evolution of magnetohydrodynamical instabilities leads to a dramatic quench of the plasma current on a very short time scale, of the order of the millisecond. Very energetic electrons are created (runaway electrons) and a global loss of confinement is finally obtained. A very high energy is deposited on small areas. This phenomenon is called a major disruption.[4] The occurrence of major disruptions in running tokamaks has always been rather high, of the order of a few percent of the total numbers of the shots. In currently operated tokamaks, the damage is often large but rarely dramatic. In the ITER tokamak, it is expected that the occurrence of a limited number of major disruptions will definitively damage the chamber with no possibility to restore the device.[5][6][7]

Plasma heating[edit]

In an operating fusion reactor, part of the energy generated will serve to maintain the plasma temperature as fresh deuterium and tritium are introduced. However, in the startup of a reactor, either initially or after a temporary shutdown, the plasma will have to be heated to its operating temperature of greater than 10 keV (over 100 million degrees Celsius). In current tokamak (and other) magnetic fusion experiments, insufficient fusion energy is produced to maintain the plasma temperature.

Ohmic heating[edit]

Since the plasma is an electrical conductor, it is possible to heat the plasma by inducing a current through it; in fact, the induced current that heats the plasma usually provides most of the poloidal field. The current is induced by slowly increasing the current through an electromagnetic winding linked with the plasma torus: the plasma can be viewed as the secondary winding of a transformer. This is inherently a pulsed process because there is a limit to the current through the primary (there are also other limitations on long pulses). Tokamaks must therefore either operate for short periods or rely on other means of heating and current drive. The heating caused by the induced current is called ohmic (or resistive) heating; it is the same kind of heating that occurs in an electric light bulb or in an electric heater. The heat generated depends on the resistance of the plasma and the amount of electric current running through it. But as the temperature of heated plasma rises, the resistance decreases and ohmic heating becomes less effective. It appears that the maximum plasma temperature attainable by ohmic heating in a tokamak is 20-30 million degrees Celsius. To obtain still higher temperatures, additional heating methods must be used.

Neutral-beam injection[edit]

Neutral-beam injection involves the introduction of high-energy (rapidly moving) atoms into the ohmically heated, magnetically confined plasma. The atoms are ionized as they pass through the plasma and are trapped by the magnetic field. The high-energy ions then transfer part of their energy to the plasma particles in repeated collisions, increasing the plasma temperature.

Magnetic compression[edit]

A gas can be heated by sudden compression. In the same way, the temperature of a plasma is increased if it is compressed rapidly by increasing the confining magnetic field. In a tokamak system this compression is achieved simply by moving the plasma into a region of higher magnetic field (i.e., radially inward). Since plasma compression brings the ions closer together, the process has the additional benefit of facilitating attainment of the required density for a fusion reactor.





Set of hyperfrequency tubes (84 GHz and 118 GHz) for plasma heating by electron cyclotron waves on the Tokamak à Configuration Variable (TCV). Courtesy of CRPP-EPFL, Association Suisse-Euratom.
Radio-frequency heating[edit]

See also: Radio frequency heating and Dielectric heating

High-frequency electromagnetic waves are generated by oscillators (often by gyrotrons or klystrons) outside the torus. If the waves have the correct frequency (or wavelength) and polarization, their energy can be transferred to the charged particles in the plasma, which in turn collide with other plasma particles, thus increasing the temperature of the bulk plasma. Various techniques exist including electron cyclotron resonance heating (ECRH) and ion cyclotron resonance heating. This energy is usually transferred by microwaves.

Tokamak cooling[edit]

The fusion reactions in the plasma spiraling around a tokamak reactor produce large amounts of high energy neutrons. These neutrons, being electrically neutral, are no longer held in the stream of plasma by the toroidal magnets and continue until stopped by the inside wall of the tokamak. This is a large advantage of tokamak reactors since these freed neutrons provide a simple way to extract heat from the plasma stream; this is how the fusion reactor generates usable energy. The inside wall of the tokamak must be cooled because these neutrons yield enough energy to melt the walls of the reactor. A cryogenic system is used to prevent heat loss from the superconducting magnets. Mostly liquid helium and liquid nitrogen are used as refrigerants.[8] Ceramic plates specifically designed to withstand high temperatures are also placed on the inside reactor wall to protect the magnets and reactor.

Experimental tokamaks[edit]

Currently in operation[edit]

(in chronological order of start of operations)





Alcator C-ModTM1-MH (since 1977 Castor, since 2007 Golem[9]) in Prague, Czech Republic; in operation in Kurchatov Institute since early 1960s; 1977 renamed to Castor and moved to IPP CAS,[10] Prague; 2007 moved to FNSPE, Czech Technical University in Prague, and renamed to Golem[11]
H-1NF H-1 National Plasma Fusion Research Facility, h1nF[12] based on the H-1 Heliac device built by Australia National University's plasma physics group and in operation since 1992
T-10, in Kurchatov Institute, Moscow, Russia (formerly Soviet Union); 2 MW; in operation since 1975
TEXTOR, in Jülich, Germany; in operation since 1978
Joint European Torus (JET), in Culham, United Kingdom; 16 MW; in operation since 1983
Novillo Tokamak,[13] at the Instituto Nacional de Investigaciones Nucleares,in Mexico City, Mexico; in operation since 1983
JT-60, in Naka, Ibaraki Prefecture, Japan; in operation since 1985 (Currently undergoing upgrade to Super, Advanced model)
STOR-M, University of Saskatchewan; Canada in operation since 1987; first demonstration of alternating current in a tokamak.
Tore Supra,[14] at the CEA, Cadarache, France; in operation since 1988
Aditya, at Institute for Plasma Research (IPR) in Gujarat, India; in operation since 1989
DIII-D,[15] in San Diego, USA; operated by General Atomics since the late 1980s
COMPASS,[10] in Prague, Czech Republic; in operation since 2008, previously operated from 1989 to 1999 in Culham, United Kingdom
FTU, in Frascati, Italy; in operation since 1990
Tokamak ISTTOK,[16] at the Instituto de Plasmas e Fusão Nuclear, Lisbon, Portugal; in operation since 1991




Outside view of the NSTX reactor
ASDEX Upgrade, in Garching, Germany; in operation since 1991
Alcator C-Mod,[17] MIT, Cambridge, USA; in operation since 1992
Tokamak à configuration variable (TCV), at the EPFL, Switzerland; in operation since 1992
TCABR, at the University of São Paulo, São Paulo, Brazil; this tokamak was transferred from Centre des Recherches en Physique des Plasmas in Switzerland; in operation since 1994.
HT-7, in Hefei, China; in operation since 1995
HL-2A, in Chengdu, China; in operation since 2002
MAST, in Culham, United Kingdom; in operation since 1999
NSTX in Princeton, New Jersey; in operation since 1999
Pegasus Toroidal Experiment[18] at the University of Wisconsin-Madison; in operation since the late 1990s
EAST (HT-7U), in Hefei, China; in operation since 2006
KSTAR, in Daejon, South Korea; in operation since 2008
SST-1, in Institute for Plasma Research Gandhinagar, India; 1000 seconds operation.[19]
IR-T1, Islamic Azad University, Science and Research Branch, Tehran, Iran[20]

Previously operated[edit]





The control room of the Alcator C tokamak at the MIT Plasma Science and Fusion Center, in about 1982–1983.LT-1, Australia National University's plasma physics group built the first tokamak outside of Soviet Union c. 1963
T-3, in Kurchatov Institute, Moscow, Russia (formerly Soviet Union);
T-4, in Kurchatov Institute, Moscow, Russia (formerly Soviet Union); in operation in 1968
Texas Turbulent Tokamak, University of Texas, USA; in operation from 1971 to 1980.
Tokamak de Fontenay aux Roses (TFR), near Paris, France
Alcator A and Alcator C, MIT, USA; in operation from 1973 until 1979 and from 1978 until 1987, respectively.
TFTR, Princeton University, USA; in operation from 1982 until 1997
T-15, in Kurchatov Institute, Moscow, Russia (formerly Soviet Union); 10 MW; in operation from 1988 until 2005
UCLA Electric Tokamak, in Los Angeles, United States; in operation from 1999 to 2005
Tokamak de Varennes; Varennes, Canada; in operation from 1987 until 1999; operated by Hydro-Québec and used by researchers from Institut de recherche en électricité du Québec (IREQ) and the Institut national de la recherche scientifique (INRS)
START in Culham, United Kingdom; in operation from 1991 until 1998
COMPASS in Culham; in operation until 2001
HL-1M Tokamak,Chengdu,China; in operation from 1994 to 2001
MT-1 Tokamak, Budapest, Hungary 1979-1998 (Built at the Kurchatov Institute, Russia, transported to Hungary in 1979, rebuilt in 1991 to MT-1M)

Planned[edit]
ITER, international project in Cadarache, France; 500 MW; construction began in 2010, first plasma expected in 2020.[21]
DEMO; 2000 MW, continuous operation, connected to power grid. Planned successor to ITER; construction to begin in 2024 according to preliminary timetable.
 
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Tokamak Fusion Test Reactor - Wikipedia, the free encyclopedia

The Tokamak Fusion Test Reactor (TFTR) was an experimental tokamak built at Princeton Plasma Physics Laboratory (in Princeton, New Jersey) circa 1980. Following on from the PDX (Poloidal Diverter Experiment) and PLT (Princeton Large Torus) devices, it was hoped that TFTR would finally achieve fusion energy break-even. Unfortunately, the TFTR never achieved this goal. However it did produce major advances in confinement time and energy density, which ultimately contributed to the knowledge base necessary to build ITER. TFTR operated from 1982 to 1997.

In 1986 it produced the first 'supershots' which produced many more fusion neutrons.[1]

In 1994 it produced a then world-record 10.7 megawatts of fusion power from a plasma composed of equal parts of deuterium and tritium (exceeded at JET in the UK, which generated 16MW for 22MW input in 1997, which is the current record).

It was followed by the NSTX spherical tokamak.
 
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BBC News - 'Critical phase' for Iter fusion dream


'Critical phase' for Iter fusion dreamDavid Shukman
By David Shukman

Science editor, BBC News

7 August 2013

The world's largest bid to harness the power of fusion has entered a "critical" phase in southern France.

The Iter project at Cadarache in Provence is receiving the first of about one million components for its experimental reactor.

Dogged by massive cost rises and long delays, building work is currently nearly two years behind schedule.

The construction of the key building has even been altered to allow for the late delivery of key components.

"We're not hiding anything - it's incredibly frustrating," David Campbell, a deputy director, told BBC News.

"Now we're doing everything we can to recover as much time as possible.

"The project is inspiring enough to give you the energy to carry on - we'd all like to see fusion energy as soon as possible."

One litre of water contains enough deuterium, when fused with tritium, to produce the equivalent energy of 500 litres of petrol
A 1,500MW fusion power station would consume about 600g of tritium and 400g of deuterium a day
The first large-scale use of fusion was by the US military with the detonation of Ivy Mike, a hydrogen bomb, on 1 November 1952.
Iter's design involves a tokamak, the Russian word for a ring-shaped magnetic chamber
The magnetic field is designed to contain 100 million degree plasma, the temperature required for the fusion process
The US, while supporting Iter as a partner, is also funding the National Ignition Facility, which uses lasers to heat and compress hydrogen to the point of fusion
South Korea, another Iter partner, is investing $941m in a fusion technology demonstrator, K-DEMO, which could be the first to generate Grid power
Critics object to further research into nuclear power and question the likely costs of commercial operations

After initial design problems and early difficulties co-ordinating this unique international project, there is now more confidence about the timetable.

Since the 1950s, fusion has offered the dream of almost limitless energy - copying the fireball process that powers the Sun - fuelled by two readily available forms of hydrogen.

The attraction is a combination of cheap fuel, relatively little radioactive waste and no emissions of greenhouse gases.

But the technical challenges of not only handling such an extreme process but also designing ways of extracting energy from it have always been immense.

In fact, fusion has long been described as so difficult to achieve that it's always been touted as being "30 years away".

Now the Iter reactor will put that to the test. Known as a "tokamak", it is based on the design of Jet, a European pilot project at Culham in Oxfordshire.

It will involve creating a plasma of superheated gas reaching temperatures of more than 200 million C - conditions hot enough to force deuterium and tritium atoms to fuse together and release energy.

The whole process will take place inside a giant magnetic field in the shape of a ring - the only way such extreme heat can be contained.

The plant at JET has managed to achieve fusion reactions in very short bursts but required the use of more power than it was able to produce.

The reactor at Iter is on a much larger scale and is designed to generate 10 times more power - 500 MW - than it will consume.

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Iter brings together the scientific and political weight of governments representing more than half the world's population - including the European Union, which is supporting nearly half the cost of the project, together with China, India, Japan, Russia, South Korea and the United States.

Contributions are mainly "in kind" rather than in cash with, for example, the EU providing all the buildings and infrastructure - which is why an exact figure for cost is not available. The rough overall budget is described as £13bn or 15bn euros.

But the novel structure of Iter has itself caused friction and delays, especially in the early days.

Cryostat The cryostat holds the vacuum vessel and acts as a giant fridge maintaining the low temperature needed for the superconducting magnets.
Magnets The magnet system confines and controls the plasma inside the vacuum vessel and will generate a magnetic field 200,000 times higher than the Earth.
Vacuum The vacuum vessel is a doughnut-shaped chamber in which the fusion reaction takes place as the plasma particles spiral continuously without touching the walls.
Blanket The blanket covers the interior surfaces of the vacuum vessel, shielding the vessel and superconducting magnets from the heat and high-energy neutrons produced by the fusion reaction.
Divertor The divertor sits at the bottom of the vacuum vessel and acts like an exhaust system, extracting heat and helium ash and other impurities from the plasma.
Heaters For the gas in the vacuum chamber to become plasma, the temperatures inside the reactor need to reach 150 million degrees celsius—or ten times the temperature of the centre of the Sun.

Each partner first had to set up a domestic "agency" to handle the procurement of components within each member country, and there have been complications with import duties and taxes.

Further delay crept in with disputes over access to manufacturing sites in partner countries. Because each part has to meet extremely high specifications, inspectors from Iter and the French nuclear authorities have had to negotiate visits to companies not used to outside scrutiny.

The result is that although a timeline for the delivery of the key elements has been agreed, there's a recognition that more hold-ups are almost inevitable.

The main building to house the tokamak has been adjusted to leave gaps in its sides so that late components can be added without too much disruption.

The route from the ports to the construction site has had to be improved to handle huge components weighing up to 600 tonnes, but this work too has been slower than hoped. A trial convoy originally scheduled for last January has slipped to this coming September.

Continue reading the main story Iter Preparation work at the Iter site in Cadarache began in 2007. Some 90 hectares has been cleared and levelled for scientific buildings and facilities, leaving the other half of the site in its original wooded state Tokamak foundations Here, construction teams work on the foundations for Iter's Tokamak complex. Begun in 2011, the works require about 110,000 cubic metres of concrete and some 3,400 tonnes of steel reinforcement PF Coils spreader beam A 12,000 sq m building will be used to assemble the giant poloidal field (PF) coils - part of the magnetic system that helps control plasma inside Iter's vacuum vessel. The 40-tonne circular spreader beam (pictured) can travel the length of the building to move components around Regular radial plate prototype Manufacturing is underway on many components destined for the facility. This picture shows a prototype for stainless steel plates that will hold part of the toroidal field coil system Superconducting cable The field coils use special cable that is "superconducting", meaning it can conduct electricity with zero resistance as well as generating intense magnetic fields. In order to become superconducting, the coils have to be cooled with helium to -269C Continue reading the main story
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Under an initial plan, it had once been hoped to achieve the first plasma by the middle of the last decade.

Then, after a redesign, a new deadline of November 2020 was set but that too is now in doubt. Managers say they are doubling shifts to accelerate the pace of construction. It's thought that even a start date during 2021 may be challenging.

The man in charge of coordinating the assembly of the reactor is Ken Blackler.

"We've now started for real," he told me. "Industrial manufacturing is now under way so the timescale is much more certain - many technical challenges have been solved.

"But Iter is incredibly complicated. The pieces are being made all around the world - they'll be shipped here.

"We'll have to orchestrate their arrival and build them step by step so everything will have to arrive in the right order - it's really a critical point."

Command and control

While one major concern is the arrival sequence of major components, another is that the components themselves are of sufficiently high quality for the system to function.

The 28 magnets that will create the field containing the plasma have to be machined to a very demanding level of accuracy. And each part must be structurally sound and then welded together to ensure a totally tight vacuum - without which the plasma cannot be maintained. A single fault or weakness could jeopardise the entire project.

Assuming Iter does succeed in proving that fusion can produce more power than it consumes, the next step will be for the international partners to follow up with a technology demonstration project - a test-bed for the components and systems needed for a commercial reactor.

Ironically, the greater the progress, the more apparent becomes the scale of the challenge of devising a fusion reactor that will be ready for market.

At a conference in Belgium last September, I asked a panel of experts when the first commercially-available fusion reactor might generate power for the grid.

A few said that could happen within 40 years but most said it would take another 50 or even 60 years. The fusion dream has never been worked on so vigorously. But turning it into reality is much more than 30 years away.
 
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[Bregs];4872385 said:
This seems to be very complex and critical tachnology reactor

Indeed India has joined select club of few nations with such capability ...very reason why India was allowed to partner in ITER project.

This will enable India to harness Thermo-nuclear fusion energy whenever it becomes technologically viable ...It is the cleanest form of energy ...

You have to understand this is only prototype experimental reactor ....nevertheless a grand step !
 
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India has had smaller experimental Toakmak reactor named " Aditya " since 1989 ....

The one commissioned this year is being built since 2003.

This is full scale Prototype TSST1 to study behavious of plasma at exceedingly high temperatures ....as such it is research purpose ...and just like all Tokamak reactors around the world ....not primarily meant to conduct fusion reaction ....


The one at ITER will actually conduct fusion reaction ...

Neverthless India has demonstrated capability in handling and developing such critical technology fully indigenously...


This disclaimer is off course aimed at trollers .....
 
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Indeed India has joined select club of few nations with such capability ...very reason why India was allowed to partner in ITER project.

This will enable India to harness Thermo-nuclear fusion energy whenever it becomes technologically viable ...It is the cleanest form of energy ...

You have to understand this is only prototype experimental reactor ....nevertheless a grand step !

Congrats for this Big achievement.And i think those few nation also Include Pakistan

GLAST (tokamak) - Wikipedia, the free encyclopedia
 
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Congrats for this Big achievement.And i think those few nation also Include Pakistan

GLAST (tokamak) - Wikipedia, the free encyclopedia

Indeed ....but these programmes are in various stages of development ...

Anyway ITER which is actual true prototype fusion reactor is truly global endeavor with 33 nations participating - India , Pakistan included ....

All nations have equal stake in this futuristic technology ....for we all constitute world together !!!

Together we can thrive ....or together we shall fall ( if at all we fail ) ....for our destinies are woven together ....we are joined in birth and death of each other !!!

Are not we ???
 
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A very good news .

Steadily we are making progress in the civilian nuclear sector .

1000MWe and 1500MWe nuclear reactors should be our next priority which will free us from foreign reliance .
 
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