Recent results of high-enthalpy extraction experiments with closed-cycle MHD disk generators are described. Power generation experiments were carried out with two types of facility: the shock tube facility with the Disk-IV generator and the FUJI-1 blow-down facility. In the shock tube experiments, the effect of channel shape on generator performance was studied using helium seeded with cesium as working fluid. A more divergent channel shape was effective in sustaining a high Hall field throughout the channel and achieving high generator performance even under the strong MHD interaction. High-enthalpy extraction of 27.3 percent was achieved. Furthermore, these experimental results agree well with the results of one-dimensional calculations. In the FUJI-1 blow-down experiments, the effect of stagnation gas pressure on performance was studied with a working gas of seeded argon. The highest enthalpy extraction ratio of 15.7 percent was achieved with the lower stagnation pressure of 0.46 MPa, whereas the largest output power of 516.7 kW and power density of 70 MW/m3 were extracted with the nominal stagnation pressure of 0.6 MPa. This suggested the possibility of a part-load operation without significant degradation of generator performance by reducing stagnation pressure.

1.
Solbes, A., “Quasilinear Plasma Wave Study of Electrothermal Instabiliies,” Proc. 4th Int. Conf. on MHD, Vol. 1, 1968, pp. 499–518.
2.
Brederlow
G.
, and
Witte
K. J.
, “
Effective Electrical Conductivity and Related Properties of a Nonequilibrium High Pressure MHD Plasma
,”
AIAA J.
, Vol.
12
, No.
1
,
1974
, pp.
83
90
.
3.
Nakamura
T.
, and
Riedmu¨ller
W.
, “
Stability of Nonequilibrium MHD Plasma in the Regime of Fully Ionized Seed
,”
AIAA J.
, Vol.
12
, No.
5
,
1974
, pp.
661
668
.
4.
Yamasaki
H.
, and
Shioda
S.
, “
MHD Power Generation With Fully Ionized Seed
,”
J. of Energy
, Vol.
1
, No.
5
,
1977
, pp.
301
305
.
5.
Klepeis, J., and Hruby, V., “MHD Power Generation Experiments With a Large Disk Channel: Verification of Disk Scaling Laws,” Proc. 15th Symp. on Eng. Aspects of MHD, 1976, pp. VI.3.1–VI.3.6.
6.
Loubsky, W. J., Hruby, V., and Louis, J. F., “Detailed Studies in a Disk Generator With Inlet Swirl Driven by Argon,” Proc. 15th Symp. on Eng. Aspects of MHD, 1976, pp. VI.4.1–VI.4.5.
7.
Veefkind, A., “High Enthalpy Extraction From a Shock Tunnel Driven Noble Gas MHD Disk Generator,” Informal paper presented at the I.L.G. Closed Cycle Specialist Meeting, 1985.
8.
Harada
N.
, et al., “
High Enthalpy Extraction From a Helium Driven Disk MHD Generator
,”
J. of Propulsion and Power
, Vol.
5
, No.
3
,
1989
, pp.
353
357
.
9.
Harada, N., et al., “High Performance of a Nonequilibrium Disk MHD Generator,” Proc. 10th Int. Conf. on MHD, Vol. 111, 1989, pp. XII.7–XII.14.
10.
Yamasaki, H., et al., “High Interaction Disk Experiments in the FUJI-1 Facility,” Proc. 26th Symp. on Eng. Aspects of MHD, 1988, pp. 7.1.1–7.1.7.
11.
Yamasaki, H., et al., “High Enthalpy Extraction in the FUJI-1 Disk Generator Experiments,” Proc. of 10th Int. Conf. on MHD, Vol. III, 1989, pp. XII.30–XII.37.
12.
Yamasaki, H., et al., “High Enthalpy Extraction Experiments With the FUJI-1 Disk Generator,” Proc. of 27th Symp. on Eng. Aspects of MHD, 1989, pp. 6.1.1–6.1.7.
13.
Biswas
D.
, et al., “
Boundary Layer Effects in He and Ar Driven Disk MHD Generators
,”
Energy Convs. and Mgmt.
, Vol.
28
, No.
1
,
1988
, pp.
105
115
.
14.
Harada, N., et al., “Performance of an Inert Gas Driven Disk MHD Generator,” Proc. 27th Symp. on Eng. Aspects of MHD, 1989, pp. 8.13.1–8.13.8.
15.
Yamasaki, H., et al., “Closed Cycle MHD Disk Experiments at T.I.T.,” Proc. of 23rd Symp. on Eng. Aspects of MHD, 1985, pp. 430–438.
16.
Harada, N., et al., “Results of High Interaction Experiments in Closed Cycle MHD Facilities at Tokyo Institute of Technology,” Proc. of 24th Symp. on Eng. Aspects of MHD, 1986, pp. 42–53.
17.
Harada, N., et al., “High Enthalpy Experiments With a Closed Cycle Disk MHD Generator,” Proc. of 9th Int. Conf. on MHD, Vol. 11, 1986, pp. 374–383.
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