Multistage electromagnetic accelerator

A multistage electromagnetic accelerator in which energy is serially induced in stages of parallel rail having serially segmented segments or stages utilizing a high DC current source, circuit breakers, and induction coils with both primary and secondary windings to produce ultra high exit velocity in an armature and projectile which are slidably disposed between the parallel rails.

BACKGROUND OF THE INVENTION 
This invention relates to electromagnetic accelerators for accelerating a 
projectile and more particularly to such an accelerator having 
multistages. Electromagnetic accelerator devices such as described 
hereinafter utilize very high currents to provide high acceleration of a 
projectile armature during the entire period the projectile armature is in 
contact with parallel conductive rails. Circuitry is shown which, 
accomplishes staged current injection into the rails, provides high 
average current keeping the acceleration force relatively constant and 
increases the efficiency by reducing the energy which must be wasted when 
the projectile armature is expelled from the last stage. 
SUMMARY OF THE INVENTION 
In general an electromagnetic accelerator, when made in accordance with 
this invention, comprises a pair of generally parallel conductive rails, a 
device or devices for supplying high DC current to the rails at a 
plurality of locations along the rails, an armature slidably engaging the 
rails, and current interrupting means cooperating with the current 
supplying means to supply current to successive portions of the rails as 
the armature is accelerated and as it travels from one end of the rails to 
the other.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring now to the drawings in detail and in particular to FIG. 1, there 
is shown a schematic diagram of a multistage electromagnetic accelerator 
comprising a pair of generally parallel conductors or conductive rails 3 
and 5. Each conductor or conductive rail is segmented, that is, it is made 
up of conductive segments 3a, 3b and 3c and 5a, 5b and 5c separated by 
insulation 7. Slidably disposed between the rails 3 and 5 is a projectile 
armature 9 or other means for carrying or conducting current between the 
rails as establishing an arc by utilizing initially a shooting wire or 
other means and a projectile 11, which may be propelled by the armature or 
arc. The projectile armature 9 is made up of a stack of conductive sheets 
13, which have margins that contact the rail and are bent toward the 
trailing end of the armature 9. 
A homopolar generator, DC generator or AC generator with rectifying means 
or any other means for producing a high DC current 15 is connected in 
series with a make switch 17, and a plurality of mutual induction coils 
19, 21 and 23 having a primary coil 19p, 21p, and 23p, respectively, and 
secondary coils 19s, 21s, and 23s, respectively. Preferably, the primary 
and secondary coils are so wound that they both substantially link all 
their magnetic flux. The primary coils 19p, 21p, and 23p each have a 
circuit breaker or other means for interrupting a circuit 25, 27, and 29, 
respectively, connected in series therewith. The primary coils 19p, 21p, 
and 23p and their respective circuit breaker means 25, 27, and 29 are 
connected in parallel across the generating means 15 and make switch 17. 
Current shorting or crowbarring means 31 and 33 are respectively connected 
across the primary coils 21p and 23p and circuit breaker means 27 and 29. 
It being understood that the make switch 17, circuit breaking means 25, 
27, and 29, and current crowbarring means 31 and 33 may be any type of 
switching device capable of closing and/or opening circuits in which large 
DC currents flow and that the different names are utilized to make it 
easier to describe the circuit and its operation. 
The secondary coils 19s, 21s, and 23s have one end thereof, respectively, 
connected to the rail segments 3a, 3b, and 3c and the other end thereof, 
respectively, connected to the rail segments 5a, 5b, and 5c so that the 
rail 3 is arbitrarily positive and rail 5 is negative. Rectifying means 41 
is connected across the insulator 7 so that the current generally flows in 
one direction in rail 3 and generally in the opposite direction in rail 5. 
Rectifying means 42 are disposed in the leads connecting the secondary 
coils 21s and 23s to the conductive rails 3b and 3c, respectively. 
Armature or arc sensors 43 are suitably disposed in the vicinity of the 
trailing end of the rails 5a and 5b to sense the armature 9 or the arc as 
it approaches the trailing end of these rail segments and send signals to 
the circuit breaking means 27 and 29 as the armature 9 approaches the 
trailing end of the respective rail segments 5a and 5b. The sensor 43 may 
be optical or electrical or mechanical or a combination thereof. Its 
function is to synchronize the opening of the circuit breaking means 27 
and 29 as the armature 9 progresses to the next rail segment. A spark gap 
or other energy dissipating means 45 is disposed on the trailing end of 
the rail segments 3c and 5c to dissipate the energy remaining in the rails 
after the projectile 11 has been ejected therefrom. 
While both rails 3 and 5 are shown to be segmented and have insulators 7 
disposed between the segments, the operation would not be impaired if only 
one rail was segmented with insulator 7 disposed between the segments or, 
to produce a more modular or symmetrical configuration, the insulating gap 
in each rail could be staggered so that each rail is insulated at every 
second stage thus reducing the number of gaps and the number of bridging 
circuits which generally include the rectifying means 41. The insulating 
gap in the rails are generally shorter than the armature 9 so that current 
can start to flow through the armature 9 between the next successive rail 
segments before current flow is interrupted across the trailing portions 
of the previous rail segments so as to reduce arcing as the armature 9 
moves across the insulating gap. If an arc is utilized to drive the 
projectile rather than an armature, short insulating gaps would assist the 
establishment or transposition of the arc to successive rail segments. 
The operation of the multistage electromagnetic accelerator shown in FIG. 1 
is as follows: a prime mover (not shown) brings the rotor of the 
generating means 15 to the desired velocity thus initially storing kinetic 
energy therein, the switch 17 is then closed with the circuit breaking 
means 25, 27, and 29 already closed and the circuit crowbarring means 31 
and 33 open. This allows current to flow into the primary coils 19p, 21p, 
and 23p. The current is allowed to build up to predetermined levels, which 
substantially transfers the kinetic energy of the generating means 15 to 
electromagnetic energy temporarily stored in the primary coils 19p, 21p, 
and 23p. The current crowbarring means 31 and 33 are next closed 
temporarily storing the energy in the coils 19p, 21p, and 23p. While 
crowbarring means are not shown across the coil 19p and current breaker 
25, if resistance through the generating means or current conducting buses 
is high, crowbarring means should be utilized. During the period energy is 
being transferred to the primary coils 19p, 21p and 23p, relatively low 
voltage will be produced across the terminals of the secondary coils 19s, 
21s and 23s. To prevent undesirable energy dissipation and the possibility 
of premature launching during this period, an insulating strip 46 is 
disposed between the conductive rail 3a and the armature 9. A pneumatic, 
hydraulic, mechanical, explosive, electromagnetic or other initiating 
device 47 may be utilized to move the armature 9 beyond the insulating 
strip 46 and initiate acceleration. Alternatively the insulation 46 could 
be a material which would break down when the voltage reached 
predetermined level or the armature and projectile would be inserted at 
first the desired time between conductive portions of the rails to 
initiate acceleration. The circuit breaker 25 is opened transferring 
current from the primary coil 19p to the secondary coil 19s. Since the 
number of turns in the secondary coil 19s is generally substantially less 
than the number of turns in the primary coil 19p, the electromagnetic 
energy transferred to the secondary coil 19s produces a higher current in 
the secondary coil 19s and this current is directed to the rails 3a and 5a 
and armature 9 applying an electromagnetic force to accelerate the 
armature 9 and projectile 11 along the rails 3a and 5a. When the armature 
9 approaches the insulator 7 between the rail 5a and 5b the sensor 43 
initiates opening of the circuit breaker 27 transferring current from the 
primary coil 21p to the secondary coil 21s and to the rails 3b and 5b thus 
injecting current into the rails to accelerate the armature 9 and 
projectile 11 as it travels along the rails 3b and 5b. As the armature 9 
approaches the insulator between the rail 5b and 5c the sensor 43 adjacent 
thereto sends a signal to open the circuit breaker 29 transferring current 
from the primary coil 23p to the secondary coil 23s and to the rails 3c 
and 5c injecting energy into these rails to continue to accelerate the 
armature 9 and projectile 11. The rectifying means 41 allows the forward 
flow of current from one set of rails to the next successive set of rails, 
but prevents any flow of current back from newly energized rails. As the 
projectile 11 and armature 9 are ejected from the rails the energy 
dissipating means 45 drains the remaining energy from the rails 3 and 5 
preventing arcing between the rails, as the energy remaining in the rails 
is still sufficiently high to produce arcing, if not drained in some 
manner. 
FIG. 2 shows a schematic diagram similar to FIG. 1 except there is no 
rectifying means between adjacent rail segments and there is energy 
dissipating means 45 at the end of each rail segment to dissipate the 
energy in each segment as the armature passes beyond that segment. In this 
embodiment the insulators 7 are preferably longer than the armature 9. 
FIG. 3 shows a schematic diagram in which the segmented rails 3a, b, and c 
and 5a, b, and c, the insulator 7, the armature 9, and the projectile 11 
are similar to those shown in FIGS. 1 and 2, however the circuitry of the 
power supply is different. A similar generating means 15 and make switch 
17 is utilized, however the primary portions of the mutual inductance 
coils 19p, 21p, and 23p are connected in series with the generating means 
15 and make switch 17 and a current interrupting means 50. Circuit 
breakers 51p and 53p are connected respectively across the primary coils 
21p and 23p. The secondary coils 19s, 21s, and 23s are respectively 
connected to the leading ends of the rails 3a, b, and c and 5a, b, and c. 
Rectifying means 41 are disposed across the insulator 7, rectifying means 
42 are disposed in the leads connecting the secondary coils 21s and 23s to 
the conductive rails 5b and 5c, respectively, and energy dissipating means 
45 are disposed adjacent the trailing end or muzzle of the rails segments 
3 and 5c. 
The operation of the multistage electromagnetic accelerator as shown in 
FIG. 3 is as follows: the rotor of the generation means 15 is brought to 
the desired speed by a prime mover (not shown) or by motoring up and when 
the desired rotor kinetic energy magnitude is attained, the make switch 17 
and interrupter means 50 are closed thus commencing current flow in the 
series circuit including the primary coils 19p, 21p, and 23p. When the 
current reaches a predetermined level the circuit breakers 51p and 53p 
connected respectively across the primary coils 21p and 23p are closed 
temporarily storing energy in these coils and the armature 9 is 
concurrently moved beyond the insulating strip 46 by the initiating device 
47. The interrupter means 50 is opened, transferring the electromagnetic 
energy stored in the primary coil 19p to the secondary coil 19s 
accelerating the armature 9 over the rail segment 3a and 5a. As the 
armature 9 approaches the second rail segment 3b and 5b the circuit 
breaking means 51p opens, as the sensor 43 associated therewith responds 
to the approach of the armature, transferring energy from the primary coil 
21p to the secondary coil 21s and to the rail segments 3b and 5b 
accelerating the armature 9 along the rail segments 3b and 5b. Similarly, 
as the armature 9 approaches the third rail segments 3 c and 5c, the 
circuit breaker 53p opens, as the sensor 43 associated therewith responds 
to the approach of the armature 9, transferring electromagnetic energy 
from the primary coil 23p to the secondary coil 23s and the rail segments 
3c and 5c to accelerate the armature 9 through the final rail segments 3c 
and 5c. Energy dissipating means 45 prevent arcing as the armature 9 is 
ejected from the rail segments 3c and 5c and rectifying means 41 transfer 
current from one rail segment to the next rail segment and to the armature 
9 or are as the projectile 11 progresses along the rails. 
FIG. 4 shows a schematic diagram of a multistage electromagnetic 
accelerator similar to the one shown in FIG. 3 except the circuit breakers 
51s and 53s are connected across the secondary coils 21s and 23s, 
respectively, and the circuit breakers 51p and 53p are omitted across the 
primary coils 21p and 23p respectively. 
The operation of the multistage electromagnetic accelerator shown in FIG. 4 
is as follows: the prime mover (now shown) brings the rotor of the 
generating means 15 to the speed level at which the kinetic energy 
required for launching is attained. The make switch 17 is closed along 
with the current interrupting means 50. The make switch 17 can be 
eliminated as the circuit interrupter 50 can also serve this function. The 
primary coils 19p, 21p, and 23p are connected in series with the 
generating means 15, the make switch 17 and the current interrupter means 
50. When a predetermined current is reached in the series circuit 
hereinbefore described, the circuit breakers 51s and 53s disposed across 
the secondary coils 21s and 23s, respectively, are closed and the armature 
9 is moved beyond the insulating strip 46 by the initiating device 47. The 
circuit interrupter 50 is opened transferring energy from the primary 
induction coils 19p, 21p, and 23p to the secondary coils 19s, 21s, and 
23s. The energy in the coils 21s and 23s is temporarily stored and the 
current in the secondary coil 19s is conducted to the rails 3a and 5a and 
accelerates armature 9 and projectile 11. As the sensor 43 adjacent the 
trailing end of the rail 5a senses the approach of the armature 9, the 
circuit breaker 51s opens delivering energy to the rails 3b and 5b 
accelerating the armature 9 as it passes therealong. And in a like manner 
as the armature 9 is sensed by the sensor 43 disposed at the trailing end 
of the rail 5b, the circuit breaker 53s is opened transferring energy to 
the rails 3c and 5c accelerating the armature therealong. As the armature 
exists from the rails 3c and 5c the energy dissipating means 45 removes 
the energy from the rails and prevents arcing therebetween. The rectifying 
means 41 and 42 allow the current to flow forward to the newly activated 
rails and help to prevent a backward flow of current as the successive 
secondary coils energize the successive rail segments. 
FIG. 5 shows a schematic diagram of a multistage electromagnetic 
accelerator, which comprises continuous rails 3d and 5d which are utilized 
to accelerate an armature 9 or an arc, and projectile 11 disposed thereon. 
A plurality of generating means 15a, b, and c are connected in series 
respectively with switches 17a, b, and c, circuit breaker means 59, 61, 
and 63 and the primary coils 19p, 21p, and 23p of the mutual inductance 
coils 19, 21, and 23. Secondary coils 19s, 21s, and 23s have rectifying 
means 69, 71, and 73 respectively connected in series therewith and are 
connected to the rails 3d and 5d at various intervals along their length. 
Energy dissipating means 45 are connected to the trailing ends of the 
rails 3d and 5d to prevent arcing therebetween after exit of the 
projectile. 
The operation of the multistage electromagnetic accelerator shown in FIG. 5 
is as follows: after the desired level of kinetic energy has been 
transferred to each of the generating means 15a, 15b and 15c, the switches 
17a, b, and c are closed along with the circuit breakers 59, 61 and 63. 
The generating means 15a, b, and c produce a predetermined current in the 
respective circuits temporarily storing energy in the primary coils 19p, 
21p, and 23p. The armature 9 is next moved beyond the insulating strip 46 
by the initiating device 47. The circuit breaker 59 is opened transferring 
energy from the primary coil 19p to the secondary coil 19s and the rails 
3d and 5d to accelerate the armature 9 or an arc formed between rails. As 
the armature 9 approaches the location on the rails 3d and 5d near where 
the secondary coil 21s is connected thereto, the circuit breaker 61 is 
opened transferring energy from the primary coil 21p to secondary coil 21s 
and the rails 3d and 5d as the sensor 43 picks up the approach of the 
armature 9. The rectifier means 69 and 71 cooperate with the circuit now 
formed with the armature 9 and rails 3d and 5d to assure that current 
flows only in the desired directions and to prevent or reduce parasitic 
current flow. As the armature 9 approaches that portion of the rail 3d and 
5d near where the secondary coil 23s is connected, the sensor 43 
associated with the circuit breaking means 63 sends a signal to the 
circuit breaking means 63 to open the circuit, which transfers the 
electromagnetic energy stored in the primary coil 23p to the secondary 
coil 23s and also to the connected portions of the rails 3d and 5d to 
continue accelerating the armature 9 until the armature exists from the 
rails. Energy dissipating means 45 prevents arcing between the rails and 
dissipates the energy remaining therein. 
FIG. 6 shows a schematic diagram of a multistage electromagnetic 
accelerator having continuous rails 3d and 5d, and armature 9, and 
projectile 11. A plurality of generating means 15a, b, and c are, 
respectively, connected in series with the make switches 17a, b, and c; 
induction coils 79, 81, and 83; and the circuit breakers 89, 91, and 93 
forming a close loop. The rail 3d is connected to one side of the circuit 
breaker means 89, 91, and 93 at various locations along its length and the 
rail 5d is connected to the other side of the circuit breaker means 89, 
91, and 93 at corresponding locations along its length. Rectifier means 
69, 71 and 73 arc are, respectively, connected in one of the leads 
connecting the circuit breaker means 89, 91 and 93 to the rail 3d or 5d. 
Energy dissipating means 45 are connected to the discharge end of the 
rails 3d and 5d to prevent arcing between the rails as the armature 9 or 
projectile driving arc exits therefrom. Sensors 43 operate the circuit 
breakers 91 and 93. 
The operation of the electromagnetic accelerator shown in FIG. 6 is as 
follows: the generating means 15a, b, and c produce a DC current which 
flows through the induction coils 79, 81, and 83 when the switches 17a, b, 
and c and the circuit breakers 89, 91, and 93 are closed temporarily 
storing electromagnetic energy in the coils 79, 81, and 83. In order to 
restrain the armature 9 in its initial position leads 95, 97, and 99 
connect one side of the circuit breaking means 89, 91, and 93 respectively 
to the rail 3d and these leads 95, 97 and 99 may have sufficient 
resistance so that any parasitic and premature current flow produced by 
the minor voltages across breakers 89, 91 and 93 during charging of 
inductors 79, 81 and 83 will not cause sufficient current flow through 
armature 9 to cause premature launch or excessive armature heating. 
Premature armature 9 launching may also be prevented by an insulating 
means 46 disposed between the armature and the rail and the armature could 
be initially moved from the insulating means 46 by pneumatic, hydraulic, 
electromagnetic or mechanical initiating means 47. Upon opening the 
circuit breaker 89, energy stored in the induction coil 79 is transferred 
to the rails 3d and 5d initiating acceleration of the armature 9. As the 
armature 9 progresses down the rails 3d and 5d, the sensor 43 initiates 
opening of the circuit breaker 91 transferring energy stored in the 
induction coil 81 to the rails 3d and 5d as the armature passes the 
electrical junction connecting the induction coil to the rails and 
accelerates the armature. When the armature approaches the electrical 
juncture of leads to the induction coil 83 the sensor 43 associated 
therewith opens the circuit breaker 93 injecting energy into the rails 3d 
and 5d to provide additional acceleration. The serial injection of power 
into the rails maintains a more constant acceleration and reduces the 
resistance and inductance losses of the system. The rectifying means 69, 
71, and 73 prevent a parasitic flow of current from one source to the 
other, but they still allow the earlier stages to transfer a greater 
portion of their energy to the armature 9 to help maintain the high 
acceleration. As the armature 9 leaves the rails 3d and 5d the energy 
dissipating means 45 discharges the rails and prevents arcing between the 
rails. 
As shown in the drawings the rectifying means 42 are disposed in the 
secondary or high current portions of the circuits. Present day 
commercially available rectifiers may be utilized in parallel and if 
required, series-parallel connected arrays to handle these high currents. 
Since the duration of the current flow is very short, the individual 
rectifiers can be safely operated at high current levels thus reducing the 
number of rectifiers required for the high accelerating current. The 
rectifying means 42 prevents parasitic current flow in the secondary 
portions of the circuits and the rectifying means 41 prevents reversal of 
current between adjacent rail segments if a subsequent current injection 
circuit is activated prematurely before the armature reaches the 
associated rail segments. Thus, in FIGS. 1, 3 and 4 synchronization of 
current injection into the successive rail segments is not extremely 
critical. Whereas the circuits in FIGS. 5 and 6 must absolutely preclude 
premature current injection to successive rail segments or this would 
result in current flowing in the wrong direction through the armature 9 or 
driving arc which may produce acceleration forces in the wrong direction 
or produce other undesirable results. Late current injection into 
successive rail segments of any of the embodiments would result in less 
efficient utilization of available energy and may produce excessive rail 
currents. 
The circuits shown in FIGS. 1 through 4 could be utilized for multiple 
projectile launching by replacing the rail segments with individual pairs 
of rail having a projectile 11 and an arc drive or armature 9 to conduct 
current between the rails in each pair and to accelerate the projectiles. 
Rectifying means and some of the circuit breakers or crowbar switches may 
also be eliminated. FIG. 7 shows how the circuit shown in FIG. 3 could be 
utilized. The secondary coils 19s, 21s and 23s could be connected to the 
rails 3f and g, and 5e, f and g respectively. An additional circuit 
breaker 49p could be electrically connected across the primary coil 19p or 
the circuit breakers 49p, 51p and 53p could be eliminated. Insulating 
strips 46 and means 47 for moving the armature beyond the insulating 
strips are shown, however any device will suffice which will insert the 
armature or be utilized to establish an arc just between the rails when 
the circuit breakers 50, 49p, 51p and 53p are opened to initiate firing. 
If the circuit breakers 49p, 51p and 53p are utilized 3 projectiles can be 
accelerated in rapid succession, without the circuit breakers 49p, 51p and 
53p three projectiles would be accelerated essentially simultaneously. If 
the primary coils 19p, 21p and 23p are connected in parallel across the DC 
source 15 successive or simultaneous firing could be achieved. 
It should be observed that the crowbarring means 31 and 33 in FIGS. 1 and 2 
need not always be required because the current change in storage coils 
21p and 23p will be relatively slow when these coils have attained near 
their maximum current levels and therefore even without crowbarring, 
energy may be stored for a few milliseconds in these coils as long as 
their current flow loops are of sufficiently low resistance to prevent 
excessive energy loss. 
Even though FIGS. 5 and 6, both of which utilize continuous rails, are 
shown with a separate power supply for each of the individual accelerating 
current injection locations, it should be observed that the current supply 
systems shown in FIGS. 1, 3 and 4 may also be used with continuous rails 
but when so used, it would be advantageous to add a rectifier means 42 
into the initial rail firing circuit. 
If the projectile is to be arc driven, it is required to initiate the arc 
which is normally accomplished by having a fuse means bridge across the 
initial or breech rail sections at the time when current flow is first 
injected there. When the fuse means explodes, an arc is initiated which 
pushes against and accelerates an insulating member. This member serves at 
least two functions. It must, first, seal the inner rail bore to prevent 
the arc or hot gases from bypassing the projectile and it must as its 
second function push the projectile unless the insulating member is also 
the projectile. 
The multistage electromagnetic accelerators hereinbefore described: 
advantageously utilize primary and secondary storage coils at each 
inductive energy storage location to allow switching at lower current 
levels, to simplify and reduce the cost of producing adequate switching 
hardware; allows the use of stored energy injection from a number of 
optimally located separate induction energy storage locations with energy 
initially supplied by a single or multiple energy sources to produce an 
ideal injection of energy into parallel rails in order to maintain a 
relatively constant acceleration force along the entire length of the 
rail, allows use of individual stage energy storage for ultra high 
velocity propulsion; allows energy remaining in the inductive stores and 
rails to be usefully utilized in accelerating the projectile even after 
the projectile has passed beyond the rail section initially powered by 
that particular inductive storage coil; allows greater efficiency or 
energy utilization because energy in a preceding stage is usefully 
dissipated in accelerating the projectile rather than being wasted; allows 
reduction in the energy to be dissipated at the muzzle after projectile 
exit and thus increases life and/or reduces complexity of the muzzle 
energy dissipation means; reduces the length of rail, which at any given 
instant experiences maximum current flow and thus reduces rail ohmic 
heating and ohmic heating losses; allows the individual stage, high 
current, inductive energy sources to be located close to the location 
where the high current is required, thus obviating the expense and high 
energy loss associated with transmitting ultra high current over longer 
distances; allows using a single initial energy source, which transmits 
power in the form of relatively low current to a number of separate 
locations where the current level is then increased to the magnitude 
required for electromagnetic launching.