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Development of Tungsten Injection System for High Z Impurity Transport Study in KSTAR Hyun Yong Lee 1,2 *, Suk-Ho Hong 3, Joohwan Hong 1,2, Seung Hun Lee.

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Presentation on theme: "Development of Tungsten Injection System for High Z Impurity Transport Study in KSTAR Hyun Yong Lee 1,2 *, Suk-Ho Hong 3, Joohwan Hong 1,2, Seung Hun Lee."— Presentation transcript:

1 Development of Tungsten Injection System for High Z Impurity Transport Study in KSTAR Hyun Yong Lee 1,2 *, Suk-Ho Hong 3, Joohwan Hong 1,2, Seung Hun Lee 1,2, Siwon Jang 1,2, Juhyeok Jang 1,2 Taemin Jeon 1,2, Jae Sun Park 1,2, and Wonho Choe 1,2 ** 1 Korea Advanced Institute of Science and Technology (KAIST) 2 Fusion Plasma Transport Research Center (FPTRC) 3 National Fusion Research Institute (NFRI) *leehy0816@kaist.ac.kr, joohwanhong@kaist.ac.kr **Corresponding author: wchoe@kaist.ac.kr

2 Candidates for the W particle injector  Laser blow-off system (C-Mod) - Well controlled temporal form of the source function - Adjustable injecting amount of particles - Difficulties : high cost (laser system), short preparation time  Pellet injection (LHD) - Can deposit impurities deep inside the confined plasma - Difficulties : designing of pellet, short preparation time  Particle dropper (NSTX) - Simple design, easy to inject W dusts into plasmas - Difficulties : A lack of install locations (need to modify passive stabilizer and upper port of KSTAR) It is required to try a simple injector system under the current condition for first W injection experiments on KSTAR.

3 Design of Tungsten Injection System  Design goals 1) Flight-distance of particles > 10 cm Injection system will be mounted on the manipulator The manipulator is inserted into the vacuum vessel around 10 cm away from the LCFS. 2) Compact size Gun: diameter ~ 8 mm, length ~ 50 mm Piezo-electric motor (R40NM, Piezo technology©) 3) Tolerance for strong B-field & high vacuum environments STS316 Piezo-electric motor (R40NM, Piezo technology©) 4) Reloadable system 5) Capability to inject a small amount of metal particles 10 cm

4 Performance Test Performance test with Cu & W particles @ 1 atm Source: 1) Cu Φ=0.2 mm, length~1 mm - Cu: Z=29, Density ~ 8.94 g/cm 3 (~20 ℃ ) 2) W Φ=0.2, 0.1 & 0.06 mm, length~1 mm - W: Z=74, Density ~ 19.25 g/cm 3 (~20 ℃ ) Test menu 1) Particle amount (Cu Φ=0.2 mm, 5,10,15, 20 mg) 2) Particle size (W Φ=0.2, 0.1 & 0.06 mm, 10 mg) 3) Vacuum & B-field test Cu 0.2 mm

5 Experimental Set-up Target plate position: l =100 mm Central axis (y,z)=(0,0) on the target plate A piezoelectric motor moves the trigger. Pictures of deposited particles on the target plate are taken by a DSLR camera (CANON EOS 500D).

6 Edges 10 mm (y,z)=(0,0): central axis  evaluated from edges of injection gun (Injection gun’s diameter ~ 8 mm) 0.2 mm diameter of Cu, l = 100 mm y z Example of Performance Test To evaluate deposited locations To estimate 2-D distribution Deposited locations Cu particles on the target plate 2-D distribution image Averaged drop

7 Amount of particles (Cu 5,10,15, 20 mg) Target plate: 10 cm away from the injection gun Launched Cu: 5,10,15, and 20 mg of 0.2 mm diameter particles Amount of Cu reached to the target plate 5 mg: 93%, 10 mg: 88%, 15 mg: 84%, and 20 mg: 67% Distribution of Cu particles @ l = 10 cm 1) Averaged vertical drop on the target plate - 5 mg: Δz = -3.2 mm - 10 mg: Δz = -9.1 mm - 15 mg: Δz = -11.7 mm - 20 mg: Δz = -22.2 mm 2) Average initial velocity (v 0 ) - v 0 ~ 1.5~4.0 m/s ・ Amount of particles↑: averaged drop↑, Loss↑ Amount of Cu particles vs. Δz

8 20 mg15 mg Distribution of Cu on the target plate I Deposited locations of launched Cu particle on the target plate (a) 5 mg, (b) 10 mg (c) 15 mg, and (d) 20 mg 5 mg10 mg (a) (b) (c) (d)

9 5 mg 10 mg 20 mg 15 mg Distribution of launched Cu particle on the target plate (a) 5 mg, (b) 10 mg (c) 15 mg, and (d) 20 mg (a) (b) (c) (d) Distribution of Cu on the target plate II

10 Target plate: 10 cm away from the injection gun Launched W particles  0.2, 0.1 & 0.06 mm, (10 mg x 5 times = 50 mg) Amount of particles reached to the target plate  Less than 2 mg (< 5%) Distribution of particles @ l = 10 cm 1) Averaged vertical drop at the target plate - 0.2 mm: Δz = - 9.7 mm - 0.1 mm: Δz = - 9.8 mm - 0.06 mm: Δz = - 9.9 mm 2) Average initial velocity (v 0 ): ignoring air resistance - v 0 ~ 2.3 m/s ・ In the case of W, particle size does not affect change of averaged drop Particle size (W 0.2, 0.1 & 0.06 mm)

11 0.06 Deposited locations of launched W particle on the target plate (a) 0.2 mm, (b) 0.1 mm, and (c) 0.06 mm 0.2 0.1 (a) (b) (c) Distribution of W on the target plate I

12 Distribution of launched W particle on the target plate (a) 0.2 mm, (b) 0.1 mm, and (c) 0.06 mm (a) (b) (c) 0.06 0.2 0.1 Distribution of W on the target plate II

13 Discussion (Cu vs. W) Distribution - Cu is much broaden than W - The case of heavy particle has a narrow distribution (see error-bars) Amount 1) Cu: amount ↑ averaged drop ↑ 2) W: amount ↑ averaged drop → W: Particle size does not affect increase of averaged drop ϕ vs. averaged drop

14 Vacuum test Injection gun was operated by ~ 6x10 -6 Torr (Torr) ◯/☓◯/☓ 3.0x10 -2 ◯ 6.0x10 -3 ◯ 5.0x10 -5 ◯ 1.5x10 -5 ◯ 5.6x10 -6 ◯ Injection gun

15 B-field test B-field test of piezo-electric motor was performed with a Nuclear Magnetic Resonance (NMR) device A piezo-electric motor was operated under 7 Tesla of magnetic field → It is enough to use in KSTAR environ ment NMR device 7 T @ Center NMR device Piezo-electric motor Schematic view

16 Summary  A tungsten injection system for KSTAR plasma is under developmen t and a performance test was carried out. - Source: Cu (0.2mm diameter) & W (0.2, 0.1 & 0.06 mm diameter) - Distance to the target plate: 100 mm @ 1 atm. 1) Flight-distance of particles > 10 cm ✔ (v 0 ~ 1.5-4.0 m/s) - Distribution: narrow (heavy particle), broaden (light particle) - Effect of amount & size of particles: small (heavy particle), large (light particle) 2) Compact size ✔ 3) Tolerance for strong B-field (< 7 T) ✔ high vacuum (~ 6x10 -6 Torr) environments ✔ 4) Reloadable system Δ 5) Capability to inject a small amount of metal particles Δ

17 Future work & Discussion  Future work 1) Performance test in vacuum environment (W Φ = 24 & 12 μm) 2) Optimization of injection amount, position and impurity size (considering pellet type) 3) Finding reloadable injecting condition using tiny W dusts (0.4-0.5 μm)  Discussion 1) Amount of injecting particles 2) Adopting dropper system for future experiments (vertical & horizontal injection at the same time)

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