Patent Grant
10274294
The present disclosure relates to a cartridge casing.
In particular the disclosure is concerned with a cartridge casing for a blank round.
A conventional cartridge casing 10 is shown in
Side and end views of a conventional blank ammunition round (i.e. without projectiles, for training purposes) is shown in
Thus a cartridge casing for a blank ammunition round which is more reliably sealed, thus resulting in more reliable operation, is highly desirable.
According to the present disclosure there is provided an apparatus and method as set forth in the appended claims. Other features of the invention will be apparent from the dependent claims, and the description which follows.
Accordingly there may be provided a cartridge casing comprising: a casing tube formed substantially of metal with a closed end and an open end; the casing tube bounding at least part of a head cap entered into the open end of the tube; the head cap being fixed relative to the tube; wherein an end wall defines the closed end opposite the head cap end of the cartridge; and the end wall comprises a weakened region.
The casing tube may be made of a continuous metal element.
The end wall may be continuous.
The end wall may be integral with and continuous with the remainder of the tube.
The end wall may be substantially flat.
The weakened region may be thinner than the remainder of the end wall.
The weakened region may be provided as a stamped pattern on the end wall.
The formation of a weakened region on the closed end of the tube allows for monitoring of the quality and reproducibility of the closed end of the tube, prior to forming the weakened region. The closed end of the tube is already air tight, and thus the quality and reproducibility of the weakened region may be more consistent as no air tight seal is formed during the final step. Further the weakened region is formed thereon, before the final blank ammunition is prepared. The formation of a weakened region on an already closed end, mitigates against defects of forming a final product in which the final steps are to produce the required closure in the form of a weakened region. In the prior art the final steps are to close an open end or partially open end, and perform a drawing or crimping step to provide the weakened region. The steps of quality control of the weakened region in the current arrangement may be carried out without any propellant or energetic material being present.
The open end of the casing tube may be deformable to sealingly join the tube to the head cap.
There may also be provided a blank round comprising a cartridge casing according to the present disclosure which contains a charge such that, when the charge is ignited the casing is blown open at the weakened region of the casing.
There may also be provided a method of manufacturing a cartridge casing comprising the steps of: providing a material sheet; and deforming the material sheet to comprise a cylindrical tube such that the cylindrical tube is open at one end and closed at its other end by an end wall.
The method may further comprise the step of providing a weakened region in the end wall.
The weakened region may be provided by stamping the end wall to thereby indent/notch the material of the end wall.
The process may further comprise the steps of: entering a pre-formed head cap into the open end of the casing tube; deforming/crimping the casing tube such that the casing tube and head cap are sealingly joined together.
The process may further comprise the steps of: entering a pre-formed head cap into the open end of the casing tube; sealingly joining the casing tube and head cap together by a laser or friction welding process.
There may also be provided a method of manufacturing a blank round comprising the steps of at least in part filling the a cartridge according to the present disclosure with a charge; such that, when the charge is ignited the casing is blown open at the weakened region of the casing.
Hence there is provided a cartridge casing, a blank ammunition round and method of manufacture which are an improvement upon the related art. Since propellant is held in a round that is inherently better sealed than blank ammunition rounds of the related art, the round is more inclined to discharge on demand, thus resulting in more reliable operation of the weapon system which it is provided for.
Examples of the present disclosure will now be described with reference to the accompanying drawings, in which:
The cartridge casing 40 comprises a casing tube 42 having an open end 44 which is closed by a head cap 46. The casing tube 42 is made of a single continuous metal element or sheet. The casing tube 42 may be formed substantially of metal, and the head cap 46 may be formed of a metal or non-metallic material. The casing tube 42 is substantially cylindrical and has an internal diameter at the open end 44 which receives the head cap 46. The casing tube 42 bounds at least part of the head cap 46 entered into its open end 44. The head cap 46 is configured to support and reinforce the base of the casing tube 42 to prevent it from swelling and rupturing during operation. As will be described in more detail later, the head cap 46 is fixed relative to the casing tube 42, thereby fixing the head cap 46 and casing tube 42 relative to one another. The open end 44 of the casing tube 42 may be deformable to sealingly join the tube to the head cap.
The casing tube 42 further comprises a closed end 48 opposite the head cap 46 end of the cartridge 40. An end wall 50 defines the closed end 48. That is to say the casing tube 42 terminates at the closed end 48, distal to the open end 44. The end wall 50 is continuous. The end wall 50 is integral with and continuous with the remainder of the tube 42. The end wall 50 may be substantially flat.
The end wall 50 comprises a weakened region 52. The weakened region 52 is thinner than the remainder of the end wall 50. The weakened region 52 may be provided as a stamped pattern on the end wall 50.
The closed end 48 has a diameter which may be substantially the same as, or less than, the diameter of the open end 44. In the example shown the diameter of the closed end 48 is substantially less than the diameter of the open end 44.
The walls of the casing 42 define a substantially cylindrical thin walled chamber 54. The tube casing 42 has a substantially constant diameter along a first region of its length between the open end 44 and the closed end 48. However, the cylindrical thin walled chamber 54 may have a taper (for example) <1° along at least part or all of its length. That is to say, although having a substantially constant diameter along its length, the diameter of the casing 42 may decrease slightly in a direction away from the open end 44, reducing in diameter from the open end 44 to the closed end 48.
The casing tube 42 also comprises a transition region 60 towards or at the closed end 48 where the transition region 60 of the casing tube 42 reduces in diameter in a direction away from the open end 44 to the closed end 48. Hence the diameter of the casing tube 42 will be different on either side of the transition region 60. The diameter of the casing tube 42 between the open end 44 and transition region 60 is substantially constant.
The transition region 60 may comprise one or more sub regions where the diameter is further reduced in a direction away from the open end 44 towards the closed end 48, for example by way of a step change, linear gradient change, bevel or radiused shoulder.
The head cap 46 defines a passage 66 which extends all of the way through the head cap 46 which in use will be a flash tube (or “flash passage”). The flash tube/passage 66 extends into a chamber 68 which, in use, will house a percussion cap (sometimes referred to as a “primer”). Thus the head cap 46 has a percussion side 70 which, in use, faces away from the casing tube 42.
The head cap 46 further comprises a charge side 72 which, in use, defines part of the internal surface of the cartridge casing 40. Thus the flash passage 66 extends between the percussion side 70 and the charge side 72.
The head cap 46 has an external diameter at least part way along its outer periphery sized such that it fits within the open end 44 of the casing tube 42. The relative dimensions of the internal diameter at the open end 44 of the casing tube 42 and the external diameter of corresponding region of the head cap 46 may be such when the head cap 46 is located in the casing tube 42 they form an interference fit with one another.
The casing tube 42 and head cap 46 may comprise a welded join which bonds them together in a region where they form an interference fit with one another. For example, the join may be provided around the circumference of the casing tube 42 and head cap 46 in a region where they interface with one another. Such a region is indicated with arrows “A” in
The weld may achieved by laser welding. Alternative weld joins may be provided which brought only material of the casing tube 42 into a molten state, or brought material of both the casing tube 42 and head cap 46 into a molten state.
The weld join may be provided by any appropriate welding process. In the context of the present disclosure, “welding” is intended to cover joining processes that produce bonding of materials by heating, which may be done with or without pressure or filler material. For example, the term is intended to encompass brazing and soldering. It may also be taken to encompass a process in which the material of one or more articles being joined are brought into a molten state to facilitate bonding. It may include a process in which the base materials melt along with a filler material.
Alternatively the casing tube 42 may be crimped around the head cap 46 to form a join and seal, for example in a recessed region 80 of the head cap 46, as indicated with arrows “B” in
The casing tube 42 and head cap 46 may be formed from a metal, metallic material or metal alloy comprising, for example, aluminium or titanium. In one example the casing tube 42 and head cap 46 may comprise ferritic alloys, for example stainless steel. The head cap 46 may alternatively be formed from non metallic material and/or metal-plastic composite material. The casing tube 42 and head cap 46 may be made of the same or dissimilar materials. The choice of welding process (if used) will be determined in part by the choice of materials used, as appropriate and as understood in the art.
The method of manufacture of a cartridge casing 40 according to the present disclosure and as shown in
The method comprises a first process including the steps of providing a material sheet 100, and deforming the material sheet 100 into a substantially cylindrical tube (that is to say, deforming the material sheet to comprise a cylindrical tube) by pressing and deforming the sheet in a number of steps, illustrated by way of example by arrow 102 in
The material sheet 100 for example a stainless steel strip 100, is formed on a transfer press into a tapered casing tube 42 as shown in
Propellant 36 is then added to the casing tube 42. With the propellant in the casing tube 42, the casing tube 42 and head cap 46 are joined in a third independent process, after the casing tube 42 and head cap 46 are assembled.
The material sheet 100 which may be deformed in a series of steps, shown in sequence from the bottom to the top of the page on
Alternatively the casing tube 42 may be formed from a pre-drawn tube.
The transition region 60 of the cylindrical tube 42 narrows towards the closed end 48 such that the second end has a diameter less than that of the open end 44. The profile and features of the transition region 60 may be formed by swaging the cylindrical tube 42.
A weakened region 52 is provided in the end wall 48. This may be provided by stamping the end wall to thereby indent/notch the material of the end wall to provide a thinner section. The indentation does not extend through the end wall 48. That is to say, the indentation is provided in the end wall 48, but the end wall 48 still provides a fluid barrier between the internal chamber 16 of the tube 42 and the external environment in which it is located.
The second process, for forming the head cap 46, comprises the step of providing the blank of material, machining and/or forming the material blank into the cylindrical head cap 46 such that the head cap 46 has an external diameter substantially identical to the internal diameter of the open end 44 of the casing tube 42 to thereby provide an interference fit between the two. Alternatively it may be formed with an external diameter slightly less than the internal diameter of the casing tube 42 such that the interference fit is negligible or completely absent. The head cap 46 is also formed with the passage 46 which extends all the way through the head cap 46.
The head cap 46 may be turned, or cold formed, or any other appropriate method for the forming of a head cap 46.
The third process may comprise the steps of entering the head cap 46 into the open end 44 of the casing tube 42. The casing tube 42 and head cap 46 are then joined (i.e. fixed) together, thereby sealing in propellant 36 in the chamber 54.
The casing tube 42 and head cap 46 may be welded to one another in a region where they form an interference fit with one another. For example, they may be welded to one another by applying a localised welding process around the circumference of the casing tube 42, on the external surface of the casing tube 42, radially outward of where the casing tube 42 is in contact with the external diameter of the head cap 46. Such a region is indicated with arrows “A” in
Alternatively or additionally, the casing tube 42 may be crimped around the head cap 46 to form a join and seal, for example in a recessed region 80 of the head cap 46, as indicated with arrows “B” in
Prior to assembly the casing tube 42 and head cap 46 may be prepared for welding (if used), for example being degreased. Post welding, no subsequent machining may be required, and neither may a cleaning of the casing be required.
Post joining of the casing tube 42 and head cap 46, the cartridge 40 may be turned to ensure the head cap 46 is properly centred on the casing tube 42, and to provide any other additional features required for successful functioning of the cartridge. The assembly is then gauged to ensure it meets the correct dimensional tolerances.
Hence there is provided a blank round, and method for producing such, comprising a cartridge casing which contains a charge such that when the charge is ignited the casing is blown open at the weakened region of the casing.
That is to say, when the charge 36 in the completed blank ammunition round is fired, the pressure build in the hollow chamber (or cavity) 16 induces a force on the end wall 48. The weakened region 52 will fail, causes the end wall 48 rupture. Thereafter, the ammunition of the present disclosure operates as conventional blank ammunition.
Thus there is provided a blank ammunition round and method of manufacture, which because it is better sealed, is more inclined to discharge on demand, thus resulting in more reliable operation of the weapon system which it is provided for.
The thin cartridge casing with a thin wall casing tube of the present disclosure may be made of a material which is inherently lighter than conventional cartridge cases. The material choice enables the casing tube to withstand the ignition pressures induced during operation whilst also being made by a reliable and repeatable manufacturing process.
Since the casing may have a thinner wall than that of the related art, and is made of a material which has a lower density than that used for conventional casings, the resultant cartridge casing will overall be lighter than an equivalent conventional casing. Hence for a given amount of powder propellant, a cartridge having a casing of the present disclosure will produce the same performance for less overall cartridge mass than a conventional cartridge assembly.
The choice of material for the cartridge can be made to optimised to match the design pressure requirements for the ammunition, thus minimising material content. Employing a metal as the casing tube material will ensure than the integrity of the round will not be affected when used in a hot weapon.
The cartridge casing may be made from a steel alloy or titanium alloy, which provide for a lighter casing and round than achievable using material of conventional blank rounds, namely brass. Since steel alloys and titanium alloys are less ductile than brass, they cannot be crimped in the way shown in related art
Additionally the end wall 48, being integral with and continuous with the rest of the casing tube, is inherently air tight, thereby preserving the life of the round.
Hence the configuration of the present disclosure enables a method for consistently producing a well sealed blank round of relatively low weight.
Attention is directed to all papers and documents which are filed concurrently with or previous to this specification in connection with this application and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference.
All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.
Each feature disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.
The invention is not restricted to the details of the foregoing embodiment(s). The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.
| Number | Date | Country | Kind |
|---|---|---|---|
| 15275060 | Mar 2015 | EP | regional |
| 1503918.3 | Mar 2015 | GB | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/GB2016/050532 | 3/1/2016 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2016/142652 | 9/15/2016 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3672301 | Abbott | Jun 1972 | A |
| 20140224144 | Neugebauer | Aug 2014 | A1 |
| 20160245626 | Drieling | Aug 2016 | A1 |
| Number | Date | Country |
|---|---|---|
| 3244548 | Jun 1984 | DE |
| 0056075 | Jul 1982 | EP |
| 1081764 | Dec 1954 | FR |
| 2899321 | Oct 2007 | FR |
| 2008091245 | Jul 2008 | WO |
| 2016142652 | Sep 2016 | WO |
| Entry |
|---|
| International Preliminary Report on Patentability received for Patent Application No. PCT/GB2016/050532, dated, Sep. 21, 2017. 8 pages. |
| International Search Report and Written Opinion received for Patent Application No. PCT/GB2016/050532, dated, May 30, 2016. 10 pages. |
| GB Intellectual Property Office Search Report under Section 17(5) received for GB Patent Application No. 1503918.3 (as it relates to claim one) dated Apr. 27, 2015. 3 pages. |
| GB Intellectual Property Office Search Report under Section 17(5) received for GB Patent Application No. 1503918.3 (as it relates to claims 10-14) dated May 19, 2015 . 2 pages. |
| Extended European Search Report received for EP Patent Application No. 15275060.0 dated Sep. 1, 2015. 8 pages. |
| Number | Date | Country | |
|---|---|---|---|
| 20180058829 A1 | Mar 2018 | US |
