The present invention relates generally to projectiles. More particularly, this invention relates to projectiles with sealed propellant.
The kinetic energy (KE) of conventional projectiles, for example standard mortar rounds, may be varied by tailoring the amount of propellant that is associated with each projectile before firing. This may require different internal propellant loads produced during manufacture or the use of auxiliary propellant charges, where possible.
In mortar rounds, the projectiles and auxiliary propellant charges are generally separate from one another before firing. The auxiliary propellant is typically provided in a number of small parcels that may be supplied in different volumes or in the same volume for incremental use. Depending on the range that is required, the mortar operator manually attaches one or more parcels providing the appropriate amount of propellant to the mortar round before insertion into a tube or barrel for firing. This procedure also considerably slows the rate of fire that can be achieved by the weapon and is prone to human error when loading.
It will be appreciated that a more cost effective, convenient and reliable arrangement for varying the kinetic energy of projectiles is desirable, particularly where a high rate of fire is required. Particularly where the projectile firing weapon is of the type including a plurality of rounds stacked in a barrel for sequential firing and required to be remotely controlled. It would be of further advantage if the construction of individual rounds was substantially homogeneous.
Projectiles with sealed propellant are described herein. In one embodiment of the invention, a projectile includes a chamber having a propellant charger, an exit from the chamber for release of propellant gases into a barrel when the propellant is ignited to fire the projectile, and a seal to block the exit which is opened by ignition of the propellant within the chamber but is resistant to ignition of other propellant in the barrel, where the seal is carried from the barrel by the projectile after the ignition.
Other features of the present invention will be apparent from the accompanying drawings and from the detailed description which follows.
In order that this invention may be more readily understood and put into practical effect, reference will now be made to the accompanying drawings which illustrate embodiments of the invention, wherein:
In the following description, numerous details are set forth to provide a more thorough explanation of embodiments of the present invention. It will be apparent, however, to one skilled in the art, that embodiments of the present invention may be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form, rather than in detail, in order to avoid obscuring embodiments of the present invention.
Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification do not necessarily all refer to the same embodiment.
Referring to the drawings it will be appreciated that the invention can be implemented in various ways for a variety of projectiles and purposes. The invention may be provided as a single projectile, as a weapon containing projectiles, or as a barrel assembly containing stacked projectiles for insertion in a weapon, for example.
The embodiments described herein relate to mortar rounds of up to about 60 mm caliber, it will be appreciated that the invention finds application in variety of projectile configurations. In particular, projectile configurations adapted for axial stacking in a barrel assembly and arranged for sequential firing, suitably by electronic means, as disclosed in earlier patent applications originating from either or both of these inventors.
Semiconductor bridges are known devices having the appearance of a microchip with two terminal wires, such as shown in U.S. Pat. No. 4,708,060 and subsequent US patents. If an electric potential is placed across these two wires, the semiconductor bridge releases a small amount of energy, most in the form of heat. The energy released by the SCB may in some cases be insufficient to ignite the propellant charges directly and the initiators may further require a set-up chemical compound (i.e. a compound which is capable of being initiated by an SCB and will, in turn, ignite the charge). SCBs can be designed and arranged such that a current induced between the two terminals can cause energy release. It is considered that the various means of inducing a current in a coil of wire using a magnetic field (induction) are well enough understood by those proficient in the art that such details need not be discussed here, save one example. It is therefore to be taken that all such means of providing a suitable firing current, whether by inducing said current or otherwise, are within the ambit of this invention.
In order to fire the charges in a designated projectile (for example projectile 31.2), the FCU 39 applies firing signal current to the primary coil 33.2 wrapped around the barrel 30 for that projectile 35.2. The resultant magnetic field induces a current in the secondary coil 35.2, which is applied to the two terminals of the initiators 32, 33, 34. Ignition of one or more propellant charges 36a, 36b, 36c occurs in response to those initiators arranged to ignite upon receipt of the firing signal.
SCBs can also be designed such that they will not initiate due to a simple current but only when a particular “type” of current occurs. Indeed, SCB technology now offers the ability to manufacture SCBs that require various and distinct levels of energy of ignition signal to activate the energetic material. Encoders and decoders could also be used in conjunction with SCB technology, if required. Where encoders/decoders and other logic circuits are employed, a signal modulation scheme may comprise any pulse wave modulation (PWM), pulse code modulation (PCM) or pulse amplitude modulation (PAM) scheme, or in any other suitable encoding scheme. This allows the separate, smaller propellant charges 36 to be discretely ignited via the common induction coil pairs 33, 35.
We now turn to consider the use of variations in current to embed an ignition signal as an example. In order to fire propellant charge 36a for the designated (or any particular) projectile 35.2 the FCU 39 applies current (with the appropriate modulated variations embedded within it) to the primary coil 33.2 associated with that projectile. The resultant current in secondary coil 35.2 (induced by the magnetic field) thus varies in intensity in proportion to the variations in current the FCU has applied. The induced current that is delivered to the SCBs thus also varies in proportion with the variations in intensity of the magnetic field. Thus the appropriate SCB 32 in propellant load 36a of the projectile 35.2 can be delivered the appropriate coded signal and therefore be initiated without the initiation of propellant charges 36b or 36c, through the use of a single induction coil 33 per projectile.
It will be appreciated that, upon initiation of a selected propellant charge or charges 36, the rapid combustion thereof operates to discharge the associated projectile from the barrel 30. Where only one propellant charge is initiated, eg. centre charge 36b by SCB 33, the kinetic energy imparted to the projectile will be considerably lower than imparted when all three propellant charges 36a, 36b, 36c are initiated.
FIGS. 4 to 8 of the drawings depict a projectile 45 of another embodiment of the invention having a projectile body 46 with a cavity 49 wherein a plurality of propellant charges 50 are disposed longitudinally in the projectile. In contrast, the propellant charges of the embodiments discussed above were disposed laterally within the projectile. For reasons of clarity, the initiators and secondary or receiving coils have been omitted from these drawings.
The projectile 45 is depicted in
Since the propellant cavity becomes smaller in diameter toward the head portion 47 of the projectile, if the first loaded sealing disc 51 is forced toward the head 47 of the projectile, wedging will occur between the band edge and the tapered interior wall of the cavity 47, and the disc will retain the forwardmost charge 50.1 in place. Accordingly, when a similarly directed force is applied during firing, e.g. the force resulting from combustion of the second propellant charge 50.2 being initiated, the sealing disc 51 will further be wedged into place with said interior wall 56. This “wedge-sealing” action aims to reduce the likelihood of ignition of propellant charge 50.2 causing any sympathetic or “blow-by” ignition of propellant charge 50.1.
Ignition of propellant volume 50.1 however will push the adjacent sealing band in the other direction, both unlocking it and forcing it toward the tail 48 of the projectile 45. The sealing disc 51 will not move far before the edge of the sealing disc loses contact with the cooperating interior wall 56 of the cavity, thereby allowing burning propellant 50.1 to reach rearward propellant charge 50.2. The next rearward propellant charge 50.2 is thus ignited and the process continues rapidly until propellant volume 50.4 is ignited. In summary, the ignition of a particular propellant charge 50 will not ignite a propellant charge that is closer to the nose of the projectile, as explained above.
The aperture includes means for resisting the expulsion of the sealing discs from the cavity, which take the form of a plurality of inwardly radially extending fingers or catch points 57 (as depicted in FIGS. 4 to 8) to stop or at least resist the sealing discs 51 from being expelled or otherwise leaving the projectile cavity 49 entirely. There are several small catch points 57 disposed around the periphery of the aperture 58, as will be apparent from the view of
Since it may or may not be viable for the catch points to be conveniently manufactured as part of the projectile, the catch points 57 may be formed as a separate component 59 that is removably retained in the tail portion 48′, such as by cooperating screw threads (not shown), once the cavity 49 has been loaded with propellant charges 50 and respective sealing discs. This component modification of the fourth embodiment is shown in
In a further modification, the entire cavity portion 49 including the rearward aperture 58 may be formed as a separate component and similarly removably retained in the projectile body 46. The separate component containing the cavity could alternatively be formed with the lateral arrangement of propellant charges and respective expansion bleed ports as described above.
In a fifth embodiment of the present invention depicted in
The sealing plugs 64 are outfitted with a small T-shaped retaining member 65 that stops or at least resists the plugs from leaving the projectile cavity 63 entirely. It is presently expected that the sealing plugs 64 would need to be manufactured as two pieces (ie. plug and retaining member) and assembled in situ. In a similar fashion to the fourth embodiment discussed above, the T-shaped portion is made up of several small catch points, rather than using the entire ring. However, in this embodiment, the catch points are a plurality of radially outwardly extending fingers 66 of somewhat cruciform configuration. Also as above, this is so that when a T-shaped member 65 hits its respective wall member 61, it does not close off the propellant charge 67 to the exterior of the projectile 60, as shown in the enlarged cross-sectional view of the
It is presently considered that the T-shaped retaining member 65 may only be necessary for the screwed-in wall member 61 closest to the rear of the projectile.
The above embodiments of the invention all entail the use of separate (and generally volumetrically smaller) propellant charges. Typically the operator can elect or an automated fire control system can determine, to burn ¼ of the available propellant, ½, ¾ or all of the propellant available to a particular projectile. However, it is to be understood that propellant volumes need not be divided in this manner, and in fact can be divided in any way desired.
In
The applicant has now realized that the present invention may also find a further application as discussed in relation to this sixth embodiment. Here each projectile assembly 80 includes a main projectile body 81 with a head portion 82 and a rearwardly extending tail portion 83 having a tapered skirt 84, as depicted in
With reference to
A further embodiment of the invention is depicted in
With particular reference to
Further, the embodiment illustrates how different propellant charge separating means may be employed together in a projectile assembly, in that a given pair of charges 103-104 is separated from other pairs 101-102 and 105-106 by transverse walls of the auxiliary projectiles 97.1, 97.2, whilst individual charges within the pair may be separated by respective enclosures in the form of non-metallic bags 121, 122, 123, 124, 125 and 126.
In the embodiments discussed above, it will be appreciated that any propellant charges remaining in the barrel after firing a particular projectile may be cleared from the barrel by separate initiation, prior to firing the next projectile in the stack of projectiles.
Furthermore, it is envisaged that the propellant division and selective initiation arrangement of the present invention may be used within many of the present applicant's other earlier projectile designs and barrel assembly configurations. Put more simply, there are existing designs and configurations not mentioned here that could use the method outlined above of separate smaller propellant loads and coded SCBs (or other ignition method) to achieve an electronically selectable range variable projectile.
For example in the barrel assembly 70 of
With the addition of different coded SCBs to each bag and an induction coil pair (not shown) for each projectile we have a system similar to that of above. It is to be taken that the present invention is applicable to alternative configurations of projectile and barrel assemblies (not explicitly mentioned here), including but not necessarily limited to those of the applicant, which are to be considered within the ambit of this patent application.
It is to be understood that the above embodiments have been provided only by way of exemplification of this invention, and that further modifications and improvements thereto, as would be apparent to persons skilled in the relevant art, are deemed to fall within the broad scope and ambit of the present invention described above.
Number | Date | Country | Kind |
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2003900572 | Feb 2003 | AU | national |
2003902103 | May 2003 | AU | national |
2003902556 | May 2003 | AU | national |
This application is a divisional application of a co-pending U.S. patent application Ser. No. 10/545,206, filed Jun. 16, 2006, which is a national phase application of International Application No. PCT/AU2004/000141, filed Feb. 10, 2004, which claims the priority from Australian Patent Application Nos.: 2003900572 filed Feb. 10, 2003; 2003902103 filed May 2, 2003; and 2003902556 filed May 23, 2003. The disclosures of the above-identified applications are incorporated by reference herein in their entirety.
Number | Date | Country | |
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Parent | 10545206 | Jun 2006 | US |
Child | 11800481 | May 2007 | US |