secondary cells with lithium anodes and immobilized fused_salt
secondary cells with lithium anodes and immobilized fused_salt secondary cells with lithium anodes and immobilized fused_salt
130. The time required for the detonation to travel fran the tetryl through the sample cup, the first "finger" of MDF and to point x1 in the sheet explosive is: ds tl = - + P + % + T I + L vS Vl vw The time required for the detonation to travel from.the tetryl through the "start" branch of the MDF and to x1 through the sheet explosive from the opposite direction is: dw L - xL t,' = 3L +I) + - + b "W vW Equating (A-1) and (A-2) and rearranging terms: Similarly, by equating the times of travel from the tetryl to point in the second finger of sheet explosive: Subtracting (A-3) from (A-4) and noting that 5 = 9 and VI = Va (A-1) (A-2) (A-3) (A-4) (A-5) Vs, ds', and dw' are conditions of the ,experiment; x1 and Q are measured; therefore Vs can be calculated. ,
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- Page 80 and 81: . .- . - ..... . . I ,caving the re
- Page 82 and 83: If it ~ 3 ~ o~t 7 s Y'2t the therm1
- Page 84 and 85: Chlorine Fentafluaride T q D OC 252
- Page 86 and 87: , 86. Zeections of Cl30 and AsF5. M
- Page 88 and 89: aa . - The rrost difficult rctionel
- Page 90 and 91: 90. DENSITY, VISCOSITY AND SURFACE
- Page 92 and 93: 92. If it is assumed that the syste
- Page 94 and 95: 94. After condensation of oxidizer
- Page 96 and 97: Stirring Solenoid LHe 7. Cryostat 9
- Page 98 and 99: Introduction 98. RFACTIONS OF OxYcm
- Page 100 and 101: , Acknowledgement 100. This work wa
- Page 102 and 103: 102. volume and then by pumping to
- Page 104 and 105: 104. The x-ray powder pattern (Tabl
- Page 106 and 107: Irredie tion Time, mi&) 106. Table
- Page 108 and 109: I. Introduction 108. RE7IIEw OF ADV
- Page 110 and 111: 1.40 w F O/) 103-4O 'F 110. /H 0 21
- Page 112 and 113: !P, "c -- -2118.5 -195 -172 -16.1 .
- Page 114 and 115: 114. weaker than those in NF02. The
- Page 116 and 117: Compound C102F ~ 1 , 0 ~ -146 ~ 116
- Page 118 and 119: 118. fom such salts as cS+m8- have
- Page 120 and 121: 120. DETONABILITY TESTING AT NONAMB
- Page 122 and 123: I 122. top) is closed with caps whi
- Page 124 and 125: 124. five pieces of MDF, each 20.00
- Page 126 and 127: 126. auxiliary equipment. For conve
- Page 128 and 129: 128. reliability. Details of most o
- Page 132 and 133: 132. Fig. 2 Typical Witness Plate
- Page 134 and 135: I ll 134. L, ALUMINUM 011+ ‘7 I-
- Page 136: W (3 3 a (3 W m 3 0 v) W E k- / W 3
130.<br />
The time required for the detonation to travel fran the tetryl<br />
through the sample cup, the first "finger" of MDF <strong>and</strong> to point x1 in<br />
the sheet explosive is:<br />
ds<br />
tl = - + P + % + T I + L<br />
vS Vl vw<br />
The time required for the detonation to travel from.the tetryl through<br />
the "start" branch of the MDF <strong>and</strong> to x1 through the sheet explosive<br />
from the opposite direction is:<br />
dw L - xL<br />
t,' = 3L +I) + - +<br />
b "W vW<br />
Equating (A-1) <strong>and</strong> (A-2) <strong>and</strong> rearranging terms:<br />
Similarly, by equating the times of travel from the tetryl to point<br />
in the second finger of sheet explosive:<br />
Subtracting (A-3) from (A-4) <strong>and</strong> noting that 5 = 9 <strong>and</strong> VI = Va<br />
(A-1)<br />
(A-2)<br />
(A-3)<br />
(A-4)<br />
(A-5)<br />
Vs, ds', <strong>and</strong> dw' are conditions of the ,experiment; x1 <strong>and</strong> Q are<br />
measured; therefore Vs can be calculated.<br />
,