KR100831427B1 - Current feeder system of tokamak - Google Patents

Abstract

A current feeding system of a tokamak is provided to stably supply a large current to the tokamak by automatically controlling a plurality of current leads to supply helium. A current feeding system of a tokamak(100) includes a helium buffer tank(220), a plurality of current leads(230,240), and a helium coolant control system(210). The helium buffer tank stores a helium liquid to supply helium. The current leads are connected to the helium buffer tank to receive the helium in link with the helium liquid and a pressure. The current leads allow a current to be transmitted to the tokamak. The helium coolant control system controls to supply the helium liquid in the helium buffer tank and discharge a pressure according to a level value of the helium liquid of the helium buffer tank and the pressure of the helium buffer tank.

Description

Current feeder system of tokamak device

1 is a view for explaining a current transmission system of a general tokamak device;

Figure 2 is a schematic diagram for explaining a current transmission system of the tokamak device according to an embodiment of the present invention,

3 is a detailed block diagram of the system of FIG. 2;

* Explanation of symbols for main parts of the drawings

100: Tokamak 200: TF CLB

300: TF MPS 400: PF CLB

500: PF MPS 210: helium refrigerant control system

220: helium buffer tank 230, 240: CL (current lead)

211: helium refrigerant control unit 212: level sensor

213: level control valve 214: pressure control valve

215: helium transfer port 216: pressure gauge

The present invention relates to a tokamak device, and more particularly to a current transmission system of the tokamak device.

       Tokamak is a container for the fuel gas for fusion power generation that changes to the plasma state of the fourth state of the material during fusion. Tokamak is to trap the high-temperature plasma without touching the common wall, the central solenoid (CS) coil, TF (Toroidal Field) and PF (Poloidal Field) coil is responsible for the generation, confinement, control of the plasma.

       Since the tokamak needs to supply current to the TF coil and the PF coil in order to generate plasma, a normal bus-bar and a current feed system from an external power supply (MPS) are used. Tokamak is supplied with power. At this time, the CFS and the tokamak are connected by a superconducting busline.

       For convenience of explanation, the tokamak, the MPS, the phase conducting bus bar, the superconducting bus line, and the CFS will be described as tokamak devices.

       Hereinafter, the tokamak apparatus will be described in more detail with reference to FIG. 1.

1 is a view for explaining a current transmission system of a general tokamak device.

Referring to FIG. 1, the tokamak 10 is formed of 16 TF coils, 8 CS coils, 6 PF coils, and a connecting structure (not shown) connecting each structure.

       Here, TF coil operates with DC current of about 35kA, CS coil and PF coil perform pulse operation with maximum 8kA / sec current change, and current is charged and discharged up to about ± 20kA, and electromotive force due to mutual magnetic field change It is generated inside the vacuum chamber to generate plasma and constrains the plasma together with the plasma current and the TF magnetic field.

In order to make the Tokamak superconducting magnet into a superconducting state, a current must be supplied. In order to supply current to the superconducting magnets, superconducting bus lines and the like are connected by electrical joints.

The CFS 20 is configured between the tokamak 10 and the MPS 30 to supply current to the tokamak 10. The MPS 30 includes a PF MPS 31 and a TF MPS 32 for supplying power to each coil, and the CFS 20 is a PF current lead box for a PF coil (hereinafter referred to as CLB). 21) and the TF CLB 22 for the TF coil, and each of the CLBs 21 and 22 includes current leads 21a and 22a. In addition, the CFS 20 is connected to the tokamak 10 through a superconducting bus line, and is electrically connected to the MPS 30 through a phase conducting bus bar made of copper. Each CL 21a, 22a electrically connects a phase-conducting busbar operated at room temperature (300K) and a superconducting busline operated at a low temperature (4.5K) and simultaneously blocks heat transferred to the superconducting busline using helium refrigerant. It plays a role. A vapor-cooled current lead (VCL) using a helium gas vaporized in a liquid helium container as a refrigerant is used, and is divided into a CL 21a for a PF coil and a CL 22a for a TF coil.

In FIG. 1, only one CL is shown inside each CLB for ease of explanation. However, seven pairs of CL for PF coils and two pairs of TF coils CL are installed in each CLB for initial plasma generation. In order to control the amount of helium supplied to the multiple CLs in the CLB, the amount of helium to be supplied is controlled by controlling each CL separately.

 However, such a conventional CLB has a problem that it is difficult to uniformly control the amount of helium by controlling a plurality of CLs at once.

Accordingly, an object of the present invention is to provide a current transmission system of the Tokamak apparatus capable of supplying a large current stably to the Tokamak can be automatically controlled to supply helium by controlling a plurality of CL at the same time to solve the above problems. .

In the current transmission system of the Tokamak apparatus according to the present invention for achieving the above object, in the current transmission system for supplying current to the Tokamak, helium buffer tank for storing helium liquid to supply helium, helium buffer tank It is connected to the helium liquid and the pressure in order to receive the helium and a plurality of current lead wire (CL) for transmitting current to the tokamak, helium of the helium buffer tank according to the level value and pressure of the helium liquid of the helium buffer tank It characterized in that it comprises a helium refrigerant control system for controlling to supply liquid or discharge pressure.

In addition, the helium refrigerant control system is a level sensor for sensing the level of the helium liquid in the helium buffer tank, a pressure gauge for detecting the pressure value of the helium buffer tank, and the helium according to the level sensing result and pressure value of the level sensor A helium refrigerant control unit for supplying or controlling the pressure of the helium liquid in the buffer tank, a level control valve for controlling the level of the helium liquid under the control of the helium refrigerant control unit, and adjusting the pressure according to the control of the helium refrigerant control unit It characterized in that it comprises a pressure control valve for, and a helium transmission port for supplying helium liquid.

The helium refrigerant control unit may control the level control valve to supply the helium liquid from the helium transfer port to the helium buffer tank when the level sensing value of the level sensor is lower than the preset value.

The helium refrigerant control unit may control the pressure control valve to discharge the pressure in the helium buffer tank when the pressure value of the pressure gauge is higher than the preset value.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 2 and 3.

2 is a view for explaining a current transmission system of the tokamak device of the present invention.

Referring to FIG. 2, a PF MPS 500 for supplying current to the PF coil and a PF MPS 300 for supplying current to the TF coil are provided in the toka film 100. Then, the PF CLB 400 for transmitting current between the PF coil and the PF MPS 500 of the tokamak 100 and the TF CLB 200 for transmitting current between the TF coil and the TF MPS 300 of the Tokamak 100. ). The PF CLB 400 includes seven pairs of CLs (not shown), the TF CLB 200 includes two pairs of CLs 230 and 240, and the TF CLB 200 of FIG. To supply helium refrigerant to the CL 230, 240 according to the control of the helium refrigerant control system 210 and the helium refrigerant control system 210 for cooling the CL 230, 240 by supplying helium to the 240. Configure the helium buffer tank 220 to store. Here, the helium refrigerant control system 210 is to control the helium buffer tank 220 to supply a helium refrigerant by controlling a plurality of CL at the same time.

In the following description, for the sake of convenience, two pairs of CLs 230 and 240 in the TF CLB 200 will be described. However, anyone skilled in the art will apply the same to the seven pairs of CLs (not shown) of the PF CLB 500. It is obvious that the present invention can be implemented.

In FIG. 2, TF CLB 200 is connected with two pairs of CLs 230 and 240 and a helium buffer tank 220 for supplying and storing helium to cool the two pairs of CLs 230 and 240. . The helium buffer tank 220 is supplied with helium from the helium refrigerant control system 210 to fill the helium liquid, and the portion marked in the helium buffer tank 220 is the portion where the helium liquid is discharged and the other portion is pressurized. to be. Here, the helium buffer tank 220 is connected to supply helium (hatched portion) to the CL (230, 240) under the control of the helium refrigerant control system 210, helium supplied to each CL (230, 240) The pressure of the pressurized state is connected to the space other than the helium buffer tank 220. Therefore, since the helium supply amount and pressure of the helium buffer tank 220 and the CL (230, 240) are connected in the same way, when the pressure of the CL (230, 240) drops, the pressure of the helium buffer tank 220 also drops, so helium The helium liquid is supplied to the buffer tank 220. On the contrary, if the helium of the CL 230, 240 is excessively supplied, the helium liquid amount of the helium buffer tank 220 which is linked to the same is also in an excessive storage state, thereby controlling the helium buffer tank 220 in a pressurized state. The pressure between the helium buffer tank 220 and the CLs 230 and 240 and the control according to helium are performed by the helium refrigerant control system 210.

Hereinafter, the present invention will be described in more detail with reference to the helium refrigerant control system 210, which is a detailed block diagram of FIG.

Referring to FIG. 3, the helium refrigerant control system 210 includes a sensing result of the level sensor 212 and the level sensor 212 and a pressure gauge 216 for sensing the level of the helium liquid of the helium buffer tank 220. Helium refrigerant control unit 211 for adjusting the helium liquid and the pressure of the helium buffer tank 220 and the level control valve 213 for controlling the level of the helium liquid under the control of the helium refrigerant control unit 211 according to the detection result And a pressure control valve 214 for regulating pressure, and a helium transfer port 215 for supplying helium.

In FIG. 3, the CL 20 and 240 which are simultaneously linked with the helium liquid amount and the pressure of the helium buffer tank 220 are connected, and the helium buffer tank 220 when the helium liquid amount and the pressure of the CL 230 and 240 are changed. The amount of helium liquid and the pressure of) fluctuate by the same amount. Accordingly, the level sensor 212 senses the level of the helium liquid in the helium buffer tank 220 and transmits it to the helium refrigerant control unit 211, and the pressure gauge 216 measures the pressure inside the helium buffer tank 220. It transmits to the helium refrigerant control unit 211.

At this time, when the amount of helium of the CL (230, 240) is insufficient, the amount of helium liquid in the helium buffer tank 220 to be linked at the same time is also insufficient, the level value of the level sensor 212 is lowered. When the helium refrigerant control unit 211 receives a sensing value from the level sensor 212 indicating that the level of the helium liquid is lower than the preset value, the helium refrigerant control unit 211 turns on the level control valve 213 and the helium liquid from the helium transfer port 215 is helium. Supply to the buffer tank 220. Then, the level of the helium buffer tank 220 is increased and the helium supply amount of the teeth 230 and 240 to be linked at the same time is also increased.

In addition, when the pressure of the CL (230, 240) is high, the pressure of the helium buffer tank 220 to be linked at the same time is also high, the pressure value of the pressure gauge 216 is increased. The helium refrigerant control unit 211 turns on the pressure control valve 214 when the pressure value is higher than the preset value from the pressure gauge 216 to discharge the pressure to the helium buffer tank 220. Then, the pressure of the helium buffer tank 220 is lowered and the pressure of the CL (230, 240) to be linked at the same time is also lowered.

In this way, helium liquid volume and pressure of the helium buffer tank 220 may be adjusted to simultaneously control helium and pressure supplied to the plurality of CLs 230 and 240.

Therefore, the device of the present invention provides the effect of stably supplying a large current to the tokamak device.

Claims (4)

In the current transmission system for supplying current to the tokamak, A helium buffer tank for storing helium liquid to supply helium; A plurality of current inlet wires (CL) connected to the helium buffer tank and connected to receive the helium in connection with pressure to transmit current to the tokamak; And a helium refrigerant control system for controlling to supply or discharge the helium liquid of the helium buffer tank according to the level value and the pressure of the helium liquid of the helium buffer tank. The method of claim 1, The helium refrigerant control system A level sensor for sensing a level of helium liquid in the helium buffer tank; A pressure gauge for detecting a pressure value of the helium buffer tank; A helium refrigerant control unit for supplying helium liquid or controlling pressure of the helium buffer tank according to a level sensing result and a pressure value of the level sensor; A level control valve for controlling the level of the helium liquid under the control of the helium refrigerant control unit; A pressure control valve for adjusting the pressure according to the control of the helium refrigerant control unit; And And a helium transport port for supplying helium liquid. The method of claim 2, The helium refrigerant control unit And if the level sensing value of the level sensor is lower than a predetermined value, controlling a level control valve to supply helium liquid from the helium transfer port to the helium buffer tank. The method of claim 2, The helium refrigerant control unit And if the pressure value of the pressure gauge is higher than a predetermined value, controlling the pressure control valve to discharge the pressure in the helium buffer tank.

Images