FR2739441A1 - TRACK LAUNCHER - Google Patents

Abstract

A rail launcher (1) has, on the inner surface of these, spaced extra thicknesses or contact pads (4), between which slides an electrically conductive, sub-calibrated projectile (3). The studs can be made up of filamentary strands. Between the studs, the launcher receives a jacket of insulating material (5).

Description

1 2739441

TRACK LAUNCHER

  The present invention relates to a rail launcher, comprising at least two electrically conductive rails, intended for the electromagnetic acceleration of a projectile

sliding between said rails.

  Rail launchers are known in the state of the art and Figure 1 shows the schematic diagram thereof: This launcher comprises two conductive rails 1 and 2, parallel to each other, between which can be moved by sliding a projectile 3 which comprises at least some

electrically conductive.

  When a current source (not shown) sends a current I through the two rails i and 2, brought into contact by the projectile 3, the magnetic field B, induced around the rails, gives rise to a force F, called force Laplace or Lorentz force, which is expressed by the equation F = IBd (1)

  where d is the distance between the rails.

  The force F can also be expressed by the equation

F = 1/2 L '. I2 (2)

  o L 'is the variation of the inductance of the rails as a function of the length in the direction of the axis. The value of L 'is relatively independent of the distance d and

  generally of the order of 0.35 to 0.45 gH / m.

  The force F accelerates the projectile 3 according to the classical relation F = Mg (3)

  o M is the mass and g the acceleration of the projectile.

  It was possible to obtain high speeds at the launcher outlet, of the order of 2 to 5 km / s with projectiles of mass varying between 0.1 kg and several kilograms; this requires the use of electrical currents of several mega-amps. While the efficiency of powder propellants decreases sharply at high speeds, the efficiency of an electric rail launcher increases at high speeds. One of the main purpose of this technology is therefore research

  very large projectile accelerations and speeds.

  Attempts have generally been made to increase the acceleration force by increasing the intensity of the current, but the intensity of the current which can flow in the rails is

  limited due to the heating it produces.

  We also know that the maximum current Im is proportional to the distance d between the rails. It has therefore been proposed to increase the spacing between the rails in order to be able to increase I and consequently F. However, a projectile filling the space d in order to make the electrical contact between the rails has a mass which increases with d, that it it is a hollow projectile or a full projectile, which compensates for the increase in F and therefore does not make it possible to increase the acceleration in the same proportions. To increase the acceleration of such a rail launcher, proposals have already been made (CG HOMANN et al., IEEE Transactions on Magnetics, MAG-22, Ne6, 1527 (1986)) to increase the magnetic field B, and consequently the resulting force in accordance with equation (1), using additional turns supplied by an additional current source. Such a construction is complex and expensive to carry out, and the ohmic losses of the system are significant. To reduce ohmic losses, we have also proposed

  (CH Haigt, M.M. Tower, IEEE Transactions on Magnetics, MAG-

  22, N 6, 1499, (1986)) to bring the current into the acceleration system in several places. This device is also expensive and difficult to make. The quality of the electrical contact between the surface of the rails and the surface of the projectile, during the sliding, also poses a problem: in particular in the case of two large surfaces, this contact is reduced to point areas which become what is commonly called of

"hot spots".

  For certain applications, the payload to be accelerated has a caliber, that is to say of small transverse dimensions. This is particularly the case with elongated projectiles such as barrel projectiles. To launch

  such projectiles, it has been proposed to provide a projectile-

  low caliber bar with a fixed peripheral reinforcement or a removable conductive launching shoe, of a significantly greater caliber, equal to the caliber of the rail launcher. During the acceleration of such a structure, it has been found that the current I is concentrated on the side of the intense magnetic field B, that is to say at the rear of the projectile. Such an inhomogeneous distribution is not desirable, in particular to obtain reliable guidance of the rod projectile. The correction of the current distribution can be obtained using relatively complicated launcher construction measures (FR 2 658 281). In addition, these structures also pose the problem of "hot spots", cited more

high.

  The object of the present invention is to provide a rail launcher of the type defined above which does not have the drawbacks of the prior art. The object of the invention is in particular to obtain significant accelerations without using complex additional peripheral structures of the accelerated object. Another specific object of the invention is to improve the electrical contact between the projectile and the rails of the launcher without calling on specific complex structures of the accelerated object.

  This goal is achieved with a rail launcher of the type below.

  above, the rails of which have a plurality of spaced apart extra thicknesses, forming pads of electrical contact with the projectile, the distance between the contact surface of the pads of the first rail and the surface of the pads of the second rail in contact with said projectile being equal to the caliber of the projectile, and o the spacing between the successive studs of the same rail is sufficiently small so that the projectile, while sliding, is permanently in effective contact with at least one stud of

each rail.

  In the device according to the invention, the spacing of the two rails is greater than the caliber of the projectile, so that the maximum current is greater than that which could be used in a launcher o the spacing of the rails

  would be equal to the caliber of the same projectile.

  Furthermore, the reduction in contact surfaces in the form of studs, between rails and projectiles makes it possible to avoid the numerous "hot spots" which normally appear during contact between two large surfaces. In addition, the movement of the projectile in contact with the studs makes it possible to distribute the current in the body of the projectile while it would tend to concentrate near the part

  rear of the projectile in launchers of the prior art.

  Preferably, the space between the contact surfaces of two successive studs contains an insulating material which is flush with the contact surface of the studs. The presence of this insulating material at the same time improves the guiding of the

  projectile and reinforces the overall structure of the launcher.

  The pieces of insulating material can be designed so as to mechanically join the rails, prevent the tendency to the spacing of the rails, and therefore improve the

electric contact.

  Each of the two rails has opposite the other rail a

  row of discrete teeth constituting the contact pads.

  These studs may have come from a room with a rail which

wears them.

  The studs can consist of rods fixed to the body

of the rail.

  The height of which the studs exceed the rail which carries them

  can be adjusted by means of an instrument.

  The studs mounted on a rail can be made of a material different from that of the rails, homogeneous or heterogeneous, to optimize a mechanical or electrical property. According to a particularly preferred variant of the invention, the studs can be made up of filamentary strands. Contact by filamentary strands provides an extremely low electrical resistance at the contact. The structure of an electrical contact by filament strands is generally known to those skilled in the art. It has for example been described in

  documents FR 79 27526 and FR 77 29716.

  The present invention will be better understood by those skilled in the art.

  profession thanks to the detailed description of a

  embodiment and accompanying figures, among which - Figure 1A shows a block diagram of a prior art rail launcher; - Figure lB shows a cross section of Figure 1A along A -A; - Figure 1C shows in the same section, a variant

  of execution of the launcher of FIG. 1A.

  - Figure 2 is a schematic view, in half-section

  longitudinal, of a rail launcher according to the invention.

  - Figures 3A, 3B and 3C are three schematic views in longitudinal section illustrating the difference between a launcher according to the invention and a launcher of the prior art. - Figure 4 shows a schematic view of another mode of

  realization of the present invention.

  Identical or equivalent objects and sizes are designated by the same symbols and reference numerals

in all of the figures.

  In Figure 2, only the rail 1 is shown. In the preferred embodiment which will now be described, the rail 2 has a structure symmetrical to that of the rail 1 with respect to the axis XX '. The bodies of the conductor rails 1 and 2 have a spacing dl. The rails 1 and 2 have discrete extra thicknesses 4n, 4n + 1, spaced apart by a distance e. These extra thicknesses can be produced by digging the rail 1 in the raw state by any known means, for example by milling. Those skilled in the art will readily understand, with reference for example to FIGS. 1B, 1C, that these extra thicknesses, schematically represented in FIG. 2 in longitudinal section in the form of teeth, can take the form of straight ribs (FIG. 1B) or in an arc of circle (FIG. 1C) extending over the entire internal width of the rail, perpendicular to the axis of the launcher, the crest of which forms a surface matching the transverse profile of the projectile, or alternatively, the shape of small studs section, square, round or other. The height or thickness f of these studs is such that d + 2f = dl (4) o d is the caliber of the projectile, less than the spacing

dl of the rail body.

  The space between and around the studs is filled to a thickness equal to f by an insulating material 5 which constitutes an interior lining of the launcher, of caliber d. The external surface of the studs is flush with the surface of the insulator 5 by any known suitable machining, and the surface of the insulator 5 has an appropriate finish to substantially guide the projectile 3 with

the best possible slip.

  The outer surfaces of the pads 4 ensure permanent electrical contact between the rails 1, 2 and the projectile 3 and therefore the passage of current between the rails 1 and 2 which generates the acceleration force F applied to the projectile

3.

  It can be seen in FIG. 2 that in the longitudinal direction of the launcher, the extra thicknesses 4 forming the contact pads have a width 1 clearly less than the spacing e between two successive pads 4n, 4n + 1. The conductive projectile of caliber d has a diameter or a thickness equal to d over a length L; in other words, L is the length of the projectile without taking into account a possible point or frontal warhead. The projectile must remain in permanent electrical contact with rails 1 and 2. This is achieved if L> 1 + e (5) In this way, during its sliding, the front part of the projectile comes into contact with the stud 4n + 1 before that its rear face leaves the stud 4n. An effective electrical contact, on an area equivalent to at least that of a stud or advantage, is thus permanently maintained, and moreover, the movement of the projectile in contact with the studs makes it possible to distribute the current well on average in the body of the projectile, while it tends to concentrate near the rear face of the projectile in known launchers. The performances which the invention allows in terms of acceleration are illustrated by FIGS. 3A, 3B, 3C which show respectively - a) a launcher a of the prior art with rails having a spacing dl, between which a projectile full of mass M1, under an acceleration ga - b) a launcher b according to the invention having rails of spacing dl, equal to that of the launcher a of FIG. 3A, but provided with studs of height f, in which slides a solid projectile, of mass M, of the same length as the projectile of the launcher a and of caliber d = dl - 2f under an acceleration gb - c) a launcher c according to the prior art having a track gauge equal to d, between which slides a projectile identical to that of the launcher b of figure 3B, under an acceleration gc If the three launchers function under maximum current, then Ia = Ib (6) and Ia / Ic = dl / d (7)

  Example 1: launcher and projectile of cylindrical section.

  At equal length, M = M.d2 / dl2 o gb = dl / d ga (8) and gb = gc'dl / d (9) In other words, the launcher b according to the invention, thanks to the studs of height f, allows - compared to a launcher of the prior art with the same spacing of rails dl and under the same current, to accelerate a sub-calibrated projectile at (dl - 2f) with increased acceleration in the ratio d1 / (dl - 2f) - compared to a launcher of the prior art firing the same projectile under maximum current, to obtain an increase in acceleration in a ratio (d + 2f) / d at the cost of current increase in a ratio (d +

2f) / d.

  The differences in the values of mass and acceleration are important: If a projectile of mass M1 = 0.1 kg is launched by a launcher where the distance dl between the rails is 30 umm, the acceleration obtained is 9a. The simple reduction of the spacing to 15 mm makes it possible to replace the mass M1 of 0.1 kg by a mass M of 0.0316 kg but the acceleration by

against does not change.

  A launcher according to the invention having a track spacing dl = 30 mm, provided with studs with a height of 7.5 mm launches a projectile of the same length and mass 0.0316 kg under an acceleration of 2 ga '

  Example 2: launcher and projectile of rectangular section.

  If the other dimensions of the projectile remain identical, M = M1.d / d1 o gb = ga (10) and gb = gc- (dl / d) (11) In other words, this launcher according to the invention allows, compared to a launcher of the prior art firing the same projectile under maximum current, to obtain an increase in acceleration in a ratio (d + 2f) / d at the price of an increase in current in a ratio (d + 2f) / d. If a projectile with a mass M1 = 6 kg is launched by a launcher where the spacing dl between the rails is 80 mm, the acceleration obtained is ga. The simple reduction of the spacing to 60 mm makes it possible to replace the mass M1 of 6

kg by a mass M of 4.5 kg.

  A launcher according to the invention having a track spacing dl = 80 mm, provided with studs 10 mm high, launches a projectile of the same length and mass 4.5 kg under a

1.3 g acceleration.

  If on the other hand the width of the sub-calibrated projectile is reduced in the same proportion as its thickness, in particular in the case of a projectile of square section, one obtains the same effects on acceleration as in

Example 1.

  The launcher contact pads according to the present invention can be the subject of various embodiments. They can in particular be made up of threaded rods, screwed into threaded bores of the body of the rail and pass right through it. In this way, the height f is adjustable and it is possible, using an instrument, by rotation of the threaded rods, to correct a lack of parallelism of the rails or wear. According to a particularly preferred embodiment of the present invention, the studs consist of bundles of filamentary strands: this embodiment allows

  to obtain a particularly effective electrical contact.

  FIG. 4 shows studs, provided with multifilament contacts, encased in a sheath of insulating material in the form of a tube or a plate depending on the shape of the projectile that the sheath guides. The pads 4 are in contact by filaments on one side with the rail 1, on the other side with the projectile 3. The rail itself does not undergo wear

  mechanical due to multiple shots.

  The conductor rails of the launcher according to the invention no longer having, as in previous launchers, to ensure both electrical contact, current flow and mechanical guidance of the projectile, it is possible to no longer conform the inner face of the rail to the lateral surface of the projectile and to give the rails a greater variety of profiles, according to conduction criteria

  current or mechanical rigidity of the assembly.

  The rails must necessarily be separated and electrically isolated from each other. By cons, the insulating material 5 may consist of a tube or a set of rings continuously surrounding and guiding the projectile. In a cylindrical tube launcher, it is easy to give the

  inner surface of the tube a profile of type "rifled barrel".

  A person skilled in the art can carry out the invention according to

  many other variants without departing from the framework of this one

  ci, which is only limited by the scope of the claims.

Claims (8)

  1. Rail launcher, comprising at least two electrically conductive rails (1, 2), intended for the electromagnetic acceleration of a projectile (3) sliding between said rails (1, 2), characterized in that each of the two rails has a plurality of spaced apart extra thicknesses, forming pads (4) of electrical contact with the projectile (3), the distance (d) between the contact surface of the pads of the first rail (1) and the contact surface of the pads of the second rail (2) being equal to the caliber of the projectile, and in that the spacing between the successive studs (4n, 4n + 1) of the same rail is sufficiently small so that the projectile (3), by sliding, is in permanence in effective contact with at least one stud each of the two rails.   2. Launcher according to claim 1, characterized in that the space between the contact surfaces of two successive studs (4nt 4n + 1) contains an insulating material (5) which   is flush with the contact surface of the studs.   3. Launcher according to one of claims 1 to 2,   characterized in that said studs came in one piece with the rail that carries them.   4. Launcher according to one of claims 1 to 3,   characterized in that said extra thicknesses form ribs, perpendicular to the axis of the launcher, the   crest follows the transverse profile of the projectile.   5. Launcher according to one of claims 1   or 2, characterized in that said pads are made up rods fixed to the body of the rail.   6. Launcher according to claim 5, characterized in   that the height of said studs is adjustable. 13 'A 2739441   7. Launcher according to one of claims 5 to 6,   characterized in that said studs consist of a   heterogeneous material improving contact.   8. Launcher according to one of claims 1, 2, 5,   7, characterized in that said studs consist of filamentary strands.