JPH07111466B2 - Pre-pro data generator for neutral particle injector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Industrial field of application) The present invention pre-programs the incident energy itself in a neutral particle injector (NBI) used as a heating device of a nuclear fusion experimental device and the like. The present invention relates to a pre-pro data creation device that creates pre-pro data for controlling the total incident power by changing the values to different values.

(Prior Art) In a fusion experimental device, it is necessary to raise the temperature of plasma as one condition for achieving the critical condition,
Neutral particle injection device has been attracting attention as a powerful means.

The neutral particle injector is a device for injecting electrically neutral particles having high energy into the plasma and applying the energy (incident energy) to the plasma to raise the temperature of the plasma. Generally, in the neutral particle injector, the total incident energy to the plasma is controlled by repeating the incidence / interruption of a beam having a constant incident energy.

(Problems to be Solved by the Invention) However, since the conditions of plasma behavior and the operation of the neutral particle injector are limited, the energy control is limited. Therefore, the incident energy itself is
Pre-pro control is being attempted to change the programmed value to control the total incident power.

In this pre-pro control, it is necessary to know various characteristics of the neutral particle injector and the fusion experimental device and create pre-pro data for realizing the incident energy required for the fusion experiment. However, the characteristics of this type of neutral particle injector are not clear, and the characteristics change depending on the ambient conditions.Therefore, it is necessary to be proficient to create pre-pro data for realizing the incident energy required for the experiment. Even a person had to spend a lot of labor and time, and the accuracy was insufficient.

Therefore, an object of the present invention is to improve the convergence efficiency when creating pre-pro data that defines the deflection magnet current and the acceleration voltage applied to the deflection magnet device and the acceleration power supply provided in the neutral particle injection device, and to obtain high-precision pre-pro data. An object of the present invention is to provide a pre-pro data creation device that can be created efficiently and easily.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, the present invention controls a deflection magnet current and an acceleration voltage applied to a deflection magnet device and an acceleration power supply provided in a neutral particle injection device. By doing so, in the pre-pro data creation device for creating pre-pro data for controlling the total incident power by changing the incident energy itself from the neutral particle injection device to the energy incident target to a pre-programmed value, the deflection A control target value input unit for inputting the magnet current and the control target value of the acceleration voltage from the outside, and a control system including the neutral particle injection device based on the control target value are operated in simulation to obtain the deflection magnet current. A first pre-pro data output section for creating corresponding first pre-pro data and giving it to the neutral particle injector, A first pre-pro data monitor unit for monitoring the response of the neutral particle injection device based on the pre-pro data, and a control system including the neutral particle injection device based on the response monitor information by the first pre-pro data monitor unit A second pre-pro data creation unit that creates a second pre-pro data corresponding to the acceleration voltage by performing a simulation operation is compared with the first and second pre-pro data and the control target value. When it is determined that the second pre-pro data is within the predetermined allowable range with respect to the control target value,
A test result determination unit that outputs the first and second pre-pro data as normal pre-pro data, and the test result determination unit causes the first and second pre-pro data to fall outside a predetermined allowable range with respect to the control target value. If it is determined that the first pre-pro data is corrected, the first pre-pro data is corrected, and the corrected first pre-pro data is supplied to the first pre-pro data output section so as to be supplied to the neutral particle injection device. And a data correction unit.

(Operation) According to such a configuration, only the control target values of the deflection magnet current and the acceleration voltage applied to the deflection magnet device and the acceleration power source of the neutral particle injection device are given respectively, and the deflection magnet current and the acceleration voltage are respectively given. The first and second pre-pro data corresponding to the above are obtained, and the first and second pre-pro data within the predetermined allowable range can be obtained by judging the suitability of the simulation result based on them. The first and second pre-pro data for defining the deflection magnet current and the acceleration voltage for operating the deflection magnet device of the neutral particle injector and the acceleration power supply are obtained without the need for data preparation by an expert. Will be able to. Therefore, many complicated pre-pro data can be created efficiently and accurately, and thus it becomes possible to rapidly perform the experiment using the required set target value, and the use efficiency of the neutral particle injection device is significantly increased. It can be improved.

(Embodiment) An embodiment of a pre-pro data generation apparatus for a neutral particle injector according to the present invention will be described below with reference to the block diagram of FIG. 1 and the operation flow chart of FIG.

In FIG. 1, 1 is a control target value input unit for inputting a control target value (t) from the outside, and 2 is a neutral particle injector NBI based on the control target value (t) from the control target value input unit 1. This is a first pre-pro data generation unit that simulates the control system that includes it and generates the first pre-pro data.
Is a first pre-pro data output section for giving the first pre-pro data from the first pre-pro data creation section 2 to the neutral particle injector NBI. Reference numeral 4 is a first pre-pro data monitor unit for monitoring the response of the neutral particle injector NBI based on the first pre-pro data, and 5 is the second pre-pro data obtained by simulating the control system again based on this monitor information. It is the second pre-pro data creation section to create,
6 is a pass / fail judgment by comparing the control target value (t) with the pre-pro data group created by the first and second pre-pro data generation and the monitor's multiple operations. Is a test result judging unit that outputs the above-mentioned pre-pro data group as normal pre-pro data in the case of good judgment, and 7 is data when the test result judging unit 6 makes a judgment. It is a pre-pro data correction unit that corrects the pre-pro data group to regular pre-pro data based on the control target value (t) by a method of repeating correction and test operation. As the correction operation in the pre-pro data correction unit 7,
A general method, for example, when the value of the pre-pro data is too large and the test result judging section 6 makes a rejection judgment, the pre-pro data is set to a small value, and the pre-pro data is too small and the test result judging section 6 makes a rejection judgment. In case of, it is possible to use a well-known method such as increasing the pre-pro data.

Next, the second operation of the present embodiment configured as described above will be described.
It will be described with reference to the drawings.

That is, the control target value (t) is input to the control target input unit 1 in the process S1 starting from the process S1.

Next, in process S3, the first pre-pro data for operating the neutral particle injector NBI under ideal conditions is created based on the control target value (t). For example, when the first pre-pro data is the deflection magnet current and the second pre-pro data is the accelerating voltage, the relationship under the ideal condition is expressed by the following equations (1) and (2).

I _rms (t) = y (t) · B _rmobj (t) (2) where Y _acc · _obj is the acceleration voltage target value, I _rms is the deflection magnet current, y (t) is the transfer function, and B _rmobj Is the deflection magnetic field setting and K _acc is a constant.

Here, the deflection magnet device and the acceleration power source are the neutral particle injector NBI.
The deflection magnet device is used to apply the ions that could not be neutralized in the neutralization cell to the beam damper, and the acceleration power supply is to accelerate the ions created in the ion source by the electric field. Is used.

The transfer function y (t) in the above equation (2) should be calculated by a method such as outputting an impulse-shaped deflection magnet current to the deflection magnet device, monitoring the deflection magnetic field response thereof, and performing Fourier transform of this. Is possible.

Next, in step S4, the first pre-pro data generated as described above is output to the neutral particle injector NBI by the first pre-pro data output unit 3, and in step S5 the response is output to the first pre-pro data monitor. Take in part 4.

Next, in step S6, the second pre-pro data creating section 5 is used to create ideal second pre-pro data corresponding to the first pre-pro data by using the response. For example, the relational expression under ideal conditions when the first pre-pro data is the deflection current and the second pre-pro data is the accelerating voltage as in the case of the above-mentioned first pre-pro data creation is expressed by the above formula (1). The modified equation (3) is obtained.

V _acc · _c (t) = K _acc · B _rm · m ² (t) (3) where V _acc · _c is the calculated acceleration voltage, B _rm · _m is the deflection magnetic field monitor value, and K _acc is a constant. Is.

Next, in step S7, the test result judging unit 6 is used to determine whether the first pre-pro data and the second pre-pro data created from the control target value (t) as described above are satisfactory pre-pro data. Determine. As a specific method of this determination, there is a method of comparing the control target value (t) with the corresponding second pre-pro data.

FIG. 3 is a characteristic diagram showing the relationship between the control target value (t) and the prepared pre-pro data, and the control target value (t) is provided with a certain allowable upper limit value _Du and allowable adjustment value _Dl . . Here, due to problems such as transfer function, if the created pre-pro data contains many errors, that is, if the created pre-pro data has D _p outside the allowable range, it is necessary to correct the pre-pro data. Judge that there is.

In step S8, the pre-pro data correction unit 7 is used to correct the pre-pro data of a portion having a value outside the allowable range.
As the above-mentioned general method, for example, when the value of the pre-pro data is too large and the test result judging section 6 makes a rejection judgment, the pre-pro data is set to a small value, and the pre-pro data is too small to judge the test result judging section 6 If the result is NO, the well-known method such as increasing the pre-pro data is used, and then the test operation is repeated. When the processing S9 obtains a satisfactory result, the process ends. By the above-described method, the convergence efficiency of pre-pro data creation can be improved and high-precision pre-pro data can be created efficiently and easily.

When correcting the pre-pro data, the influence of the corrected part on the pre-pro data after the correction is calculated by considering the transfer function of the neutral particle injector NBI and using a weighting function etc. The calculation result is used for the subsequent data correction.

[Effects of the Invention] As described above, according to the present invention, only the control target values of the deflection magnet current and the acceleration voltage given to the deflection magnet device and the acceleration power source of the neutral particle injection device are given, respectively. The first and second pre-pro data corresponding to each of the current and the acceleration voltage are obtained, and the first and second pre-pro data within the predetermined allowable range are judged by the suitability judgment of the simulation result based on them
Since the second pre-pro data is obtained, the deflection magnet current and the acceleration for operating the deflection magnet device and the acceleration power source of the neutral particle injection device can be obtained without the need for the data preparation by the expert as in the conventional case. It becomes possible to obtain the first and second pre-pro data defining the voltage.

Therefore, many complicated pre-pro data can be created efficiently and accurately, and thus it becomes possible to rapidly perform the experiment using the required set target value, and the use efficiency of the neutral particle injection device is significantly increased. It is possible to provide a pre-pro data generation device for a neutral particle injection device that can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a pre-pro data generation device for a neutral particle injection device according to the present invention, FIG. 2 is an operation flow chart of the same embodiment, and FIG. 3 is a function of the embodiment. FIG. 1 ... Control target input unit, 2 ... First pre-pro data creation unit, 3 ... First pre-pro data output unit, 4 ... First
Prepro data monitor unit, 5 ... second prepro data creation unit, 6 ... test result determination unit, 7 ... prepro data correction unit.

Claims (1)

[Claims] 1. The incident energy itself from the neutral particle injector to the energy incident target is controlled by controlling the deflecting magnet current and the acceleration voltage provided to the deflecting magnet device and the acceleration power source provided in the neutral particle injector. In a pre-pro data creating device for creating pre-pro data for changing the pre-programmed value to control the total incident power, a control target value input unit for externally inputting the control target values of the deflection magnet current and the acceleration voltage. And a first pre-pro data corresponding to the deflection magnet current is generated by performing a simulation operation of a control system including the neutral particle injection device based on the control target value, and is supplied to the neutral particle injection device. A pre-pro data output section and a first pre-monitor for monitoring the response of the neutral particle injector according to the first pre-pro data. (2) Based on the response monitor information from the data monitor unit and the response monitor information from the first pre-pro data monitor unit, the control system including the neutral particle injection device is simulated again to create the second pre-pro data corresponding to the acceleration voltage. The second pre-pro data generation unit that compares the first and second pre-pro data with the control target value, and the first and second pre-pro data are within a predetermined allowable range with respect to the control target value. When it is judged to be good,
A test result determination unit that outputs the first and second pre-pro data as normal pre-pro data, and the test result determination unit causes the first and second pre-pro data to fall outside a predetermined allowable range with respect to the control target value. If it is determined that the first pre-pro data is corrected, the first pre-pro data is corrected, and the corrected first pre-pro data is supplied to the first pre-pro data output section so as to be supplied to the neutral particle injection device. A pre-pro data generation device for a neutral particle injection device, comprising: a data correction unit.