Diversionary Device

Information

  • Patent Application
  • 20180283836
  • Publication Number
    20180283836
  • Date Filed
    June 14, 2016
    8 years ago
  • Date Published
    October 04, 2018
    6 years ago
Abstract
In a multi-burst diversionary device (10) containing a number of pyrotechnic cartridges (22) arranged in a series and a firing arrangement (14), a first of the cartridges is ignited by the firing arrangement, the remaining cartridges are each ignited sequentially by the flash of pressure and heat (hot gasses) produced when a previous cartridge in the series deflagrates. The device has a housing (12) defining a number of compartments (20) in which the cartridges are received. The housing defines flow paths interconnecting the compartments in series and the first compartment with the firing arrangement. Each compartment is also fluidly connected with atmosphere.
Description
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable.


MICROFICHE APPENDIX

Not Applicable


BACKGROUND OF THE INVENTION

1. Field of the Invention


The present invention relates to a multi-burst diversionary device and to a method of igniting the fuzes of a plurality of pyrotechnic cartridges in a multi-burst diversionary device.


2. Description of the Related Art


Diversionary devices, sometimes also referred to as stun grenades or distraction devices, are generally intended for use by law enforcement and military personnel to physiologically and psychologically stun an intended victim or victims in high-risk situations. Known diversionary devices generally comprise a housing containing an energetic pyrotechnic charge and a firing arrangement with a small time delay. When activated, the known diversionary devices emit a loud noise, a pressure wave and a flash of light to stun the intended victim but without expelling matter that might cause physical injury. More recently, diversionary devices have been developed which emit multiple bursts of noise, pressure and light rather than a single burst. It is believed that this is more disorientating; especially if the bursts become louder and more intense giving the impression the device is getting closer to the victim.


It is known to use a pyrotechnic charge housed in a replaceable cartridge in a diversionary device. The known cartridges are similar to the so called “flash-bang” cartridges that are commercially available and used typically for scaring birds and often comprise a cylindrical housing containing a combustible fuze and a pyrotechnic charge. The length and composition of the fuze determines the time delay between ignition of the fuze and deflagration of the pyrotechnic charge. Such cartridges are sometime referred to as “sound units.”


In WO 2011086388 A1 the present inventor disclosed a multi-burst diversionary device housing a number of replaceable pyrotechnic cartridges. The device has a firing arrangement incorporating a percussive ignition cap containing a primer charge. When the cap is fired, a proportion of the heat and pressure given off is directed onto the fuze of each of the cartridges so that the fuzes of all the cartridges are ignited at the same time. To provide a multi-burst effect, the cartridges have fuzes with a different time delay arranged so that the pyrotechnic charges are deflagrated sequentially. Whilst this arrangement is highly effective, there are drawbacks. Generally speaking, in order to obtain a longer delay it is necessary to increase the physical length of the fuze resulting in a corresponding decrease in the volume of pyrotechnic charge that can be included in a cartridge of any given size. As a result, there is a limit on the number cartridges that can be incorporated in a device before the length of fuze required to provide a suitable delay for the later bursts means that there is insufficient room for an effective amount of the pyrotechnic charge. A further drawback is that each of the cartridges in the device must have a different delay to produce sequential firing. This requires that a range of cartridges with different fuze delays be provided and that each device must be loaded with a correct set of cartridges.


It is an object of the present invention to provide a multi-burst diversionary device which overcomes or at least mitigates the drawbacks of the known diversionary devices.


It is a further object of the invention to provide a multi-burst diversionary device which is simpler in design and so cheaper and easier to manufacture than known multi-burst diversionary devices.


It is also an object of the invention to provide an alternative method of igniting the fuzes of a plurality of cartridges in a multi-burst diversionary device.


BRIEF SUMMARY OF THE PRESENT INVENTION

In accordance with a first aspect of the invention, there is provided a diversionary device comprising a housing holding a plurality of pyrotechnic cartridges arranged in series, each cartridge having a combustible fuze and a pyrotechnic charge; and a firing arrangement including a primer charge; the housing defining a first flow path configured to channel hot gases from the primer charge onto the fuze of a first cartridge in the series only, the housing defining further flow paths configured to channel a portion of the hot gasses given off on deflagration of the pyrotechnic charge in each of the cartridges onto the fuze of an adjacent downstream cartridge.


In a device in accordance with the first aspect of the invention, only the fuze of a cartridge in the first compartment in the series is ignited by the printer charge, the fuzes in subsequent cartridges are ignited sequentially utilizing a portion of the hot gases produced when the pyrotechnic charge of a cartridge in the preceding compartment deflagrates. Sequentially igniting successive cartridges in series gives rise to a multi-burst effect without the need for the cartridges to have fuzes with different time delays and so enables a multi-burst device to be constructed to hold any desired number cartridges. Indeed, all the cartridges may have a fuze with the same time delay and the device could be loaded with a plurality of identical cartridges. This significantly simplifies the manufacture and supply of cartridges and the loading of the device. That said, it will be appreciated that the cartridges need not all be the same. For example, it may be desirable to use cartridges with different pyrotechnic compositions to create a particular effect over the series of bursts.


The further flow paths might be configured to channel a portion of the hot gasses given off on deflagration of the pyrotechnic charge in at least one of the cartridges onto the fuze of at least two adjacent downstream cartridges.


The device may hold more than one series of cartridges, the housing defining a first flow path configured to channel hot gases from the primer charge onto the fuze of the first cartridge in each series, the housing defining further flow paths configured to channel a portion of the hot gasses given off on deflagration of the pyrotechnic charge in each of the cartridges in each series onto the fuze of an adjacent downstream cartridge in the series.


Each cartridge may be held in a compartment defined in the housing.


Each compartment may have a fuze end and a charge end, the further flow paths being configured to fluidly connect a fuze end of each compartment with the charge end of the preceding upstream compartment in the series.


Each compartment may comprise a chamber defined within the housing, the further flow paths connecting the chambers sequentially in series, a fuze end region of each chamber in the series downstream from the first chamber being connected by means of a flow path with a charge end region of the preceding upstream chamber in the series. The chambers may each have a substantially cylindrical region in which at least part of a respective cartridge is a close sliding fit.


The housing may also define flow paths for connecting each chamber with atmosphere. For each pair of adjacent chambers in the series, the housing may define a flow path which interconnects the charge end region of the upstream chamber in the pair to the fuze end region of the downstream chamber in the pair and which also connects both end regions to atmosphere.


The primer charge may be provided in percussion cap, the first flow path connecting the percussion cap with the fuze end of the first compartment in the series. The device may further comprise a firing mechanism for selectively activating the percussion cap. The firing mechanism may comprise a firing pin which is resiliency biased to a firing position in which it contacts the cap to activate the primer charge, the pin being movable from the firing position to a non-firing position in which it is spaced from the primer charge against the bias force. The firing mechanism may also comprise a release lever, the lever being movable between a non-release position in which it holds the firing pin in the non-firing position and a released position in which the firing pin is able to move to the firing position under the bias force. The firing mechanism may also comprise a removable safety pin for holding the lever in the non-release position. The firing pin may be provided on a striker plate.


At least some of the compartments in the series may be arranged in an array, longitudinally overlapping one another. The compartments could be disposed about a central axis generally parallel to one another. The housing may comprise a main body portion having a central axis with at least some of the compartments disposed in the main body portion about the axis. The main body portion may be generally cylindrical. The compartments may be arranged so that the charge end of each compartment is located adjacent the fuze end of the next downstream chamber in the series. The housing may comprise a first end cap and a second end cap, the end caps being releasably mountable to opposite ends of the main body portion, the end caps defining the further flow paths interconnecting compartments sequentially in series. The first end cap may also comprise a mounting for receiving a firing mechanism and define at least part of the first flow path for fluidly connecting the primer charge with a fuze end of a first one of the compartments in the series. The compartments may be arranged in two or more rows about a central axis.


The compartments in the series may be arranged axially in-line. In this case, the housing may be elongate having an upstream end and a downstream end, the firing arrangement being located at the upstream end. The housing may comprise a plurality of housing sections releasably mountable to one another. The housing may comprise at least two tabular housing members including a first tubular housing member having an end cap at an upstream end incorporating, or to which is mounted, the firing mechanism and a final tubular housing member having a second end cap at a downstream end; each pair of adjacent tubular housing members being releasably interconnected by an adaptor. The first end closure and each of the adaptors may define at a downstream end a recess which opens into the interior of the adjacent downstream tubular housing member, the recess being dimensioned to receive and hold a fuze end of respective one of the pyrotechnic cartridges. Each of the adaptors may also define a further recess at an upstream end which opens into the interior of the adjacent upstream tubular housing member for receiving a charge end of a respective one of the pyrotechnical cartridges, the adaptor also defining a flow path fluidly connecting the recess at the downstream end with the further recess at the upstream end. The adaptor flow path may comprise at least one flow passage which is offset from the axial centreline of the recess. The tubular housing members may each have one or more vent openings therethrough. In accordance with a second aspect of the invention, there is provided a multi-burst diversionary device comprising: a housing holding a plurality of pyrotechnic cartridges and a firing arrangement operatively connected with a first one of the cartridges to ignite said first one of the cartridges only, the device comprising formations for directing on to each of the remaining cartridges a portion of the hot gas given off on deflagration another of the cartridges.


In accordance with a third aspect of the invention, there is provided a method of operating a multi-burst diversionary device comprising a plurality of pyrotechnic cartridges each cartridge having a combustible fuze and a pyrotechnic charge, the method comprising: a. using a primer charge to ignite the fuze of a first one of the cartridges; b. sequentially igniting the fuzes of the remaining pyrotechnic cartridges in series by directing a portion of the hot gasses given off by an upstream cartridge in the series when it deflagrates onto the fuze of the next adjacent downstream cartridge.





BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS


FIG. 1 is a perspective view of a first part of the main body of a diversionary device in accordance with a first embodiment of the invention;



FIG. 2 is similar to FIG. 1 but includes arrows indicating the direction flow of fluid along the various fluid passageways;



FIG. 3 is a longitudinal cross sectional view on an enlarged scale through a typical pyrotechnic cartridge for use in a diversionary device in accordance with the invention;



FIG. 4 is a side view of a main body member forming part of a housing of a diversionary device in accordance with a second embodiment of the invention;



FIG. 5 is an end view of the main body member of FIG. 4;



FIG. 6 is a cross sectional view taken on line A-A of FIG. 7 of a first end cap forming part of the housing of the diversionary device in accordance with the second embodiment of the invention for use with the main body member of FIGS. 4 and 5;



FIG. 7 is an end view of the first end cap of FIG. 6;



FIG. 8 is a side view showing hidden detail of second end cap forming part of the housing of the diversionary device in accordance with the second embodiment of the invention for use with the main body member of FIGS. 4 and 5 and the first end cap of FIGS. 6 and 7;



FIG. 9 is an end view of the second end cap of FIG. 8;



FIG. 10 is a schematic side view of the diversionary device in accordance with the second embodiment;



FIG. 11 is a longitudinal cross-sectional view through a diversionary device in accordance with a third embodiment of the invention;



FIG. 12 is a side view of an adaptor forming part of the device of FIG. 11;



FIG. 13 is an end view of the adaptor of FIG. 12;



FIG. 14 is a side view of a diversionary similar to that shown in FIG. 11 but expanded to include three pyrotechnic cartridges, with certain parts shown ghosted to enable internal details to be seen;



FIG. 15 is schematic representation of an alternative configuration of pyrotechnic cartridges which could be adopted in diversionary device similar to that of the first embodiment of the invention as illustrated in FIGS. 1 and 2; and,



FIG. 16 is a view similar to that of FIG. 10 illustrating an alternative arrangement of pyrotechnic cartridges in a diversionary device similar to that of the second embodiment of the invention as illustrated in FIGS. 4 to 10.





REFERENCE NUMERALS USED IN THE DRAWINGS




  • 10 diversionary device


  • 12 body member


  • 12
    b end cap


  • 12
    c end cap


  • 14 firing mechanism


  • 16 mating face


  • 18 recess


  • 20 chamber


  • 22 pyrotechnic cartridge


  • 24 housing


  • 26 end closure


  • 28 pyrotechnic charge


  • 30 fuze


  • 32 extended region


  • 40 fluid passageway


  • 42 fluid passageway


  • 44 fluid passageway


  • 46 further flow passageway


  • 48 Y shaped passageway


  • 50 outlet


  • 52 arrow


  • 54 arrow


  • 56 passageway


  • 60 arrow


  • 68 arrow


  • 70 through bore


  • 72 end face


  • 74 end face


  • 76 spigot


  • 78 end face


  • 80 external thread


  • 82 central bore


  • 82
    a internal thread


  • 83 percussion cap


  • 84 end face


  • 85 firing mechanism


  • 85
    a release lever


  • 85
    b safety pin


  • 86 end face


  • 88 central bore


  • 88
    a recessed region


  • 90 bore


  • 92 recess


  • 94 bore


  • 96 recess


  • 98 recess


  • 100 vent hole


  • 102 vent hole


  • 104 recess


  • 106 recess


  • 108 recess


  • 110 vent hole


  • 112 row


  • 114 row


  • 115 divider


  • 116 flow path


  • 118 flow path


  • 120 vent hole


  • 122 main body section


  • 124 threaded spigot


  • 126 threaded spigot


  • 128 recess


  • 132 main body portion


  • 134 threaded spigot


  • 136 recess


  • 138 recess


  • 140 bore


  • 142 main body section


  • 144 threaded spigot


  • 145 recess



DETAILED DESCRIPTION OF THE INVENTION

Several embodiments of a diversionary device in accordance with the present invention will now be described, by way of non-limiting example only, with reference to the accompanying drawings.


With reference to FIGS. 1 to 3, a diversionary device in accordance with a first embodiment of the present invention is indicated generally at 10. The device 10 has a housing with a main body to which is mounted a firing mechanism, indicated schematically at 14. The main body is formed in two parts, only one of which 12 is illustrated, the other part being substantially a mirror image of the part 12 shown. The part 12 is a generally rectangular block of material having a mating face 16. The part 12 can be made of any suitable material such as a metallic material including steel or aluminum/aluminum alloy. Formed within the material are recesses 18 which one open on to the mating face 16. The second part has a corresponding mating face and corresponding recesses. The two parts 12 are connected together mating face to mating face to form the main body and held together by a number of releasable fastenings, such as screws (not shown). When connected together, the opposed recesses 18 in the mating faces 16 of the two parts define a number of cylindrical chambers 20a-20h arranged in a common plane, and a number of fluid passageways which interconnect the chambers fluidly in series and connect each of the chambers with atmosphere at the exterior of the main body 12. The recesses also define a first fluid passageway which fluidly connects only a first of the chambers with the firing arrangement.


In the present embodiment, there are eight chambers in the main body but the number of chambers can be varied as desired. Each of the chambers 20 has a cylindrical region configured to receive a cylindrical pyrotechnic cartridge 22, an example of which is shown in FIG. 3 on an enlarged scale.


Each cartridge 22 has a cylindrical housing 24 closed at one end by an end closure 26. The housing contains a pyrotechnic charge 28 located towards the closed end of the housing and an ignitable and combustible fuze 30 at the open end. Each chamber 20 has a fuze end 20′ and a charge end 20″, the cartridges 22 being inserted in the chambers with the open fuze at the fuze end 20′ of each chamber as illustrated schematically in chambers 20a to 20c in FIG. 1 with the cross hatching representing the fuze 30. At the charge end, the chambers have an extended region 32 of reduced diameter in comparison with the cylindrical region into which the end closure 26 of the cartridge is blown when the pyrotechnic charge is ignited and deflagrates.


The cartridges 22 may be similar to so called “flash-bang” cartridges that are commercially available and used typically for scaring birds. The cylindrical housing 24 may be made of paper or cardboard or the like but any suitable material can be used. The pyrotechnic charge 28 may be any suitable composition which produces the required combination of sound, light and pressure. A differently composed pyrotechnic charge 28 may be used in some/all of the cartridges 22 in the device 10 to create different effects. For example, the cartridges 26 may have different pyrotechnic charge compositions so that when ignited sequentially, each successive cartridge produces a louder noise, more light and more pressure. This gives the impression that the device 10 is moving closer to the victim even though the device is substantially stationary.


Whilst it is expected that the device in accordance with the invention will use pyrotechnic cartridges with a combustible fuze 30 to provide a delay between each successive deflagration (“flash-bang”), at least some pyrotechnic cartridges with no fuze could be used, though this would result in a series of closely spaced bangs.


Seven of the chambers 20b-20h are arranged parallel to one another in a closely spaced array whilst the first chamber 20a is inclined at an angle to the others and is more widely spaced at its fuze end 20′. This positions the fuze end 20′ of the first chamber 20a so as to be more easily connected with the firing arrangement 14 by a first fluid passageway 40. The firing arrangement is releasably mountable to the main body 12 and houses a percussive ignition cap containing a primer charge which emits a flash of heat and pressure (hot gasses) when the cap is struck with a sufficient force. The firing arrangement also includes a firing mechanism to fire the ignition cap. This can be any suitable arrangement such as a conventional spring loaded striker plate and release leaver assembly of the type described in WO 2011086388 A1. However, any suitable firing mechanism could be used such as an inertia activated toggle of the type disclosed in EP 1705454 B. For convenience, the term “flash” will be used in this description to refer collectively to the heat, pressure wave, light, sound and material given off by the primer charge in the percussion cap when it is set off and/or by a pyrotechnic charge in one of the cartridges 22 when it deflagrates. It will be understood, however, that it is the hot gas or gases given off or produced by the pyrotechnic charges which is of primary importance for use in igniting a fuze 30 of a subsequent cartridge 22.


The firing arrangement includes a fluid passageway which connects with the first fluid passageway 40 in the main body to form a flow path along which at least a portion of the hot gasses given off by the primer charge is able to flow into the fuze end 20′ of the first chamber 20a. Fluid passageways 42, 44 defined in the main body connect the fuze end and the charge end respectively of the first chamber 20a to atmosphere at the exterior of the main body. A further flow passageway 46 fluidly connects the charge end of the first chamber 20a to the fuze end of the second chamber 20b. The chambers are all positioned top to toe so that the fuze end of one chamber is located next to the charge end of the adjacent chamber or chambers. Adjacent pairs of the second to eighth chambers 20b to 2h are each interconnected by a generally “Y” shaped fluid passageway 48. The “Y” shaped passageway 48 interconnecting the second chamber 20b and the third chamber 20c will be described in detail. This “Y” shaped passageway 48 includes a first fluid passageway portion 48a extending coaxially from the fuze end of the downstream chamber 20c to an outlet 50 at the edge of the main body 12 where it opens into the atmosphere. A second passageway portion 48b extends from the extended region 32 at the charge end of the upstream chamber 20b to the first passageway portion 48a approximately midway between the outlet 50 and the chamber 20c. The second passageway portion 48b extends from a position approximately midway along the extended region 32 so that it is not blocked by the cartridge end closure 26 which is blown into the end of the extend region when the cartridge is fired. The second passageway is angled relative to the axis of the upstream chamber 20b so that fluid flowing thought it is directed into the first passageway portion 48a primarily in an outward direction towards the outlet end 50 such that when the pyrotechnic charge in chamber 20b deflagrates, most of the flash given off will pass out of the main body through first passageway portion outlet 50 as indicated by arrow 52 in FIG. 2. However, some of the flash, including hot gases, will flow along the first passageway portion 48a into the fuze end of the downstream chamber 20c, as indicated by arrow 54. The remaining pairs of chambers 20c and 20d, 2d and 20e, 20e and 20f, 20f and 20g, 20g and 20h are each interconnected by a similar “Y” shaped passage way 48 and the charge end of the final chamber 20h is connected to atmosphere by a passageway 56 which extends from the extended region 32 to an outlet 58 at the edge of the main body.


In use, the device 10 is loaded with a cartridge 22 in each of the chambers 20, the main body is assembled and the firing arrangement with the primer charge mounted to the main body. When the firing arrangement is activated, the primer charge gives off a flash of pressure and heat and material including hot gasses which passes through the first fluid flow passageway 40 into the fuze end of the first chamber 20a, as indicated by arrow 60 and ignites the fuze 30 of the cartridge in the first chamber 20a. After a short delay determined by the fuze 30 of the first cartridge, the main pyrotechnic charge 28b is ignited and deflagrates giving off a larger flash of light, heat, pressure wave and sound. The majority of the flash passes through the fluid passageways 42, 44 to atmosphere as indicated by arrows 62 and 64 to produce a burst of sound, light and pressure. However, as indicated by arrow 66, a portion of the flash, including hot gas, passes along the fluid flow passageway 46 to enter the fuze end of the second chamber 20b where it ignites the fuze 30 of the cartridge in the second chamber. After a further short delay, determined by the fuze 30 in the second cartridge, the main pyrotechnic charge 28 in the second cartridge deflagrates. The bulk of the flash given off by the second cartridge passes out of the device through the first and second fluid passage way portions 48a, 48b and outlet 50 of the “Y” shaped passageway 48 interconnecting the second and third chambers 20b, 20c as indicated by arrows 52, though some will pass out of the main body through the fluid passageway 46, the extended region 32 of first chamber 20a and fluid flow passageway 44. A proportion of the flash of heat and pressure including hot gasses given off by the pyrotechnic charge of the cartridge in the second chamber 10b though passes along the first passage portion 48a into the fuze end of the third chamber 20c, as indicated by arrow 54, where it ignites the fuze 30 of the cartridge in the third chamber. The process continues in a chain-like reaction, with all the remaining cartridges 22 in the device being sequentially ignited from the flash given off by the previous, upstream cartridge in the series. Connecting the cartridges together sequentially in series in the manner of a daisy chain enables the cartridges to he fired sequentially without the need to use different length fuzes. This means that virtually any number of cartridges could be included in the device without unduly limiting the amount of pyrotechnic charge that can be incorporated in those cartridges that are fired later in the sequence and allows the device to be loaded with a plurality of identical cartridges if desired.



FIG. 15 illustrates schematically an alternative configuration of cartridges 22 in a planar array that could be adopted in a device 10 as described above. In this configuration, the cartridges are arranged in two rows and the arrows 68 indicate the flow of hot gases from one cartridge to next in the series in order that, with the exception of the first cartridge which is ignited from a primer charge, each of the remaining cartridges are ignited in turn by the hot gasses given off when the previous cartridge ignites. It will be appreciated than many other configurations could be adopted by suitable design of the cartridge chambers and interconnecting flow paths.


It will be appreciated that the concept of sequentially igniting subsequent cartridges in a multi-burst diversionary device is not limited to devices where the chambers are arranged in a common plane but can be adapted for use in devices with a range of different designs, provided that fluid flow paths for directing or channeling a proportion of the flash, and in particular the hot gas, given off or generated by each cartridge as it deflagrates onto the fuze an adjacent cartridge downstream in the series are defined. For example, the chambers could be aligned co-axially in-line with one another or they could be arranged about a common axis in a cylindrical housing as described in the following embodiments.



FIGS. 4 to 10 illustrate a further embodiment of a diversionary device 10′ in accordance with the invention in which the housing is generally cylindrical and the compartments 20 are arranged in a circular array about a central longitudinal axis.


The housing 12 of the device 10′ comprises three main parts, a main cylindrical body member 12a, a first end cap 12b and a second end cap 12c. Extending through the main body 12a is a small diameter central through bore 70 aligned with a central longitudinal axis of the main body. Disposed in and about the central through bore and longitudinal axis is an array of 6 larger diameter through bores 20a to 20f which define compartments or chambers for receiving pyrotechnic cartridges 22, such as those shown in FIG. 3. The compartments 20 are not equi-spaced about the central axis but arranged into adjacent pairs.


The end caps 12b and 12c are releasably mounted to opposite ends of the main body to hold the cartridges 22 in their respective compartments and serve to define flow paths that connect the compartments in series for sequential, serial ignition of the cartridges.


A first end cap 12a comprises a cylindrical disc portion having an outer diameter which is substantially the same as that of the main body 12a and which has a planar end face 72 which abuts an end face 74 of the main body when the housing is assembled. A spigot 76 projects axially out from the other end face 78 of the disc. The spigot 76 has an external thread 80 on to which can be mounted a firing pin arrangement. A central bore 82 extends through the first end cap. An inner end region 82a of the bore has an internal thread whilst an outer end region is 82b is recessed to hold a percussive ignition cap 83 containing a primer charge.


The second end cap 12c is also in the form a cylindrical disc having an outer diameter which is substantially the same as that of the main body 12a and which has a planar end face 84 which abuts the other end face 86 of the main body when the housing is assembled. A central bore 88 extends through the centre of the disc, the bore having a wider diameter recessed region 88a at its outer end. When the housing 12 is assembled, the end caps 12b, 12c are clamped firmly to the ends of the main body 12a by means of an elongate screw (not shown) which is inserted though the central bore 88 in the second end cap and the central bore 70 in the main body to engage with the internal thread 82a in the central bore of the first end cap. The elongate screw having a head which is received in the recess 88a of the central bore 88 in the second end cap.


The cartridges 22 in the compartments 20a-20f are arranged head to toe, with the fuzes 30 of the cartridges in the first, third, and fifth compartment 20a, 20c, 20e being located adjacent the first end cap 12b and the fuzes 30 of the cartridges in the second, fourth and sixth compartments 20b, 20d, 20f being located adjacent the second end cap.


A bore 90 extends through the disc portion of the first end cap 12b in registration with the fuze end of the first compartment 20a. A radially extending recess 92 is provided in the inner face of the disc which merges with the bore 90 and extends radially inwardly. An angled bore 94 connects the interior of the recess with an outer end region of the central through bore 82. The central through bore 82, the angled bore 94 and the recess 92 together define a first flow path along which the hot gasses given off by the primer charge in the ignition cap 83 in the outer recessed end of the bore 82 can flow to enter the fuze end of the first compartment 20a. The bore 90 forms an exhaust vent through which a portion of the flash given off when the pyrotechnic charge of the cartridge in the first compartment deflagrates can escape to atmosphere.


Two arcuate recesses 96, 98 are formed in the inner face 72 of the first end cap 12a, each recess being connected to atmosphere by an exhaust vent hole 100 extending through the remainder of the end cap to the outer end face 78 of the disc portion. A first of the recesses 96 partially overlaps the ends of the second and third compartments 20b, 20c in the main body to define a flow path fluidly interconnecting the charge end of the second compartment 20b with the fuze end of the third compartment 20c. The recess 96 and the vent hole 100 also fluidly connect the two chambers with atmosphere. The second of the recesses 98 partially overlaps the ends of the fourth and fifth compartments 20d, 20e in the main body to define a flow path fluidly interconnecting the charge end of the fourth compartment 20d with the fuze end of the fifth compartment 20d. The recess 98 and the vent hole 100 also connect the two chambers 20d, 20e with atmosphere. A further exhaust vent hole 102 is formed through the disc portion of the first end cap in line with the sixth compartment 20f to connect the compartment with atmosphere.


Three circular recesses 104, 106, 108 are formed in the inner mating surface 84 of the second end cap 12c equi-spaced about its centre. A smaller diameter exhaust vent hole 110 is formed through the remainder of the disc portion at the base of each of the recesses to connect each recess with atmosphere. The recesses 104, 106, 108 are positioned so that each one aligns with a respective pair of the compartments 20a-20f. The circular recesses 104, 106, 108 are dimensioned so that they only partially overlap the ends of the adjacent compartments so as to fluidly connect them whilst the second end cap 12c holds the cartridges in the compartments. The exhaust vent holes 110 fluidly connected the two respective compartments to atmosphere. In this embodiment, a first circular recess 104 aligns with the ends of the first and second compartments 20a, 20b in the main body so as to fluidly connect the charge end of the first compartment 20a with the fuze end of the second compartment 20b, the vent hole 110 fluidly connecting the compartments 20a, 20b with atmosphere. A second circular of the recesses 106 aligns with the ends of the third and fourth compartments 20c, 20d in the main body so as to fluidly connect the charge end of the third compartment 20c with the fuze end of the fourth compartment 20d, the vent hole 110 fluidly connecting the compartments 20c, 20d with atmosphere. A third of the circular recesses 108 aligns with the ends of the fifth and sixth compartments 20e, 20f in the main body so as to fluidly connect the charge end of the fifth compartment 20e with the fuze end of the sixth compartment 20f, the vent hole 110 fluidly connecting both compartments 20e, 20f with atmosphere.


In the assembled device 10′, the recesses and vent holes in the end caps 12b, 12c form flow paths which connect all the compartments 20a-20f sequentially in series. In other words, they form a chain of flow paths which allow each cartridge downstream from the first to be ignited by the hot gasses from the preceding cartridge in the series when it deflagrates.


The fuze end of the first chamber 20a is fluidly connected with the primer charge in the firing arrangement via the recess 92, the angled bore 94 and the axial bore 82 in the first end cap which collectively form a first fluid passageway. The charge end of the first compartment 20a is connected with the fuze end of the second compartment 20b by the first circular recess 104 in the second end cap. The charge end of the second compartment 20b is connected with the fuze end of the third compartment 20c by the first arcuate recess 96 in the first end cap. The charge end of the third compartment 20c is connected with the fuze end of the fourth compartment 20d by the second circular recess 106 in the second end cap. The charge end of the fourth compartment 20d is connected with the fuze end of the fifth compartment 20e by the second arcuate recess 98 in the first end cap. Finally, the charge end of the filth compartment 20e is connected with the fuze end of the sixth compartment 20f by the third circular recess 108 in the second end cap.


In use, a pyrotechnic cartridge 22 is loaded into each of the compartments 20a-20f in the main body 12a in the appropriate orientation. The end caps 12b, 12c are mounted to the ends of the main body and secured in position. A percussion cap 83 including a primer charge is loaded into the recessed end 82b of the axial bore in the first end cap 12b and a firing mechanism 85 is mounted to the first end cap 12b. The firing mechanism 85 is a conventional firing mechanism of the type disclosed in WO 2011086388 A1 and comprises a release lever 85a for controlling the release of a spring loaded striker plate which when released is urged to strike the percussion cap in order to set off the primer charge and a removable safety pin 85b. However, other types of firing mechanism can be adopted. When the device 10 is activated and the primer charge set off, the flash of heat, pressure and material given off by the primer charge passes through the first fluid passageway comprising the axial bore 82, the angled bore 94, and the recess 92 in the first end cap and enters the fuze end of the first compartment 20a to ignite the fuze 30 of the cartridge in the first compartment. After a short delay, the pyrotechnic charge 28 in the first cartridge is ignited and deflagrates giving off a large flash of light, heat, pressure wave, and sound. The majority of this flash passes out through the vent hole 90 and the vent hole 110 in the first circular recess 104. However, a portion of the flash including hot gas is guided by the first circular recess to enter the fuze end of the second compartment 20b where it ignites the fuze of the second cartridge in the second compartment 20b. When the second cartridge deflagrates, the majority of the flash given off passes out though the vent hole 110 in the first circular recess 104 and the vent hole 100 in the first arcuate recess 96 in the first end cap 12b. A portion of the hot gasses though is guided by the first arcuate recess 96 to enter the fuze end of the third compartment 20c to ignite the fuze of the third cartridge in the third compartment. This process continues with each cartridge being ignited by a portion of the hot gasses (flash) given off by the cartridge in the previous upstream compartment by means of the flow paths as described above. FIG. 10 is a somewhat schematic side view of the assembled device 10′ which is ghosted to show the positions of the cartridges 22 in main body member 12a, though details of the compartments 20a-20f themselves are omitted for clarity. Arrows 54 indicate the flow of hot gas from one cartridge when it deflagrates onto the fuze of the next adjacent downstream cartridge to ignite the fuze of the downstream cartridge. The arrows 52 indicate the movement of flash to atmosphere through the exhaust vent holes when each cartridge deflagrates.


It will be appreciated various changes can be made to the device 10′ without departing from the inventive concept. For example the number of compartments in the main body 12a can be changed with an appropriate change to design of the end caps 12b, 12c to ensure that the compartments are connected in series. Other changes can also be made. For example, elongate actuate holes could be provided through the disc part of the first end cap 12b rather than the recesses 96, 98 and vent holes 100. Similarly, the circular recesses 104, 106, 108 in the second end cap 12c could be replaced by simple through holes. These changes would allow the compartments to vent more easily ensuring that a sufficiently large flash is emitted whilst the shroud effect of the end cap surrounding the holes constrains sufficient heat and pressure (hot gas) given off by one cartridge when it deflagrates to pass though to the fuze end of the next compartment. The disc portion may need to be of sufficient thickness to ensure that it channels sufficient of the hot gasses onto the fuze of the downstream cartridge but this can be established for each application relatively easily by means of trial and error if necessary. With the benefit of the teaching in this patent specification, those skilled in the art will have no difficulty in configuring the housing so as to deflect part of the hot gasses given off by each cartridge onto the fuze of an adjacent downstream cartridge.



FIG. 16 illustrates a modified version of the device 10a in which the cartridges are arranged in two rows 112, 114 stacked one above the other (as shown) in modified main body portion 12a′ and separated by a divider 115. The main body portion defines flow paths 116, 118 which direct hot gases between pyrotechnic cartridges 22 vertically adjacent one another in the two rows so that all the cartridges can be ignited sequentially in series. The flow paths are arranged so that a first cartridge 22a in the row 112 adjacent the first end cap 12b is ignited from the primer charge. A proportion of the flash given off when the first cartridge 22a deflagrates is directed by means of flow passage 116 on to the fuze of a second cartridge 22b immediately below the first cartridge in the row 114 adjacent the second end cap 12b. Flash from the second cartridge 22b is directed by a suitable flow path defined in the second end cap 12c on to the fuze of a third cartridge in the same row 114, whilst flow passage 118 directs a proportion of the flash from the third cartridge 22c on to the fuze of a fourth cartridge 22d in the first row 112 immediately above the third cartridge. Similar arrangements interconnect all the remaining pyrotechnic cartridges 22 in the device. It will be appreciated that various different configurations of cartridges can be adopted by suitable design of the chambers and interconnecting flow paths.



FIGS. 11 to 14 illustrate a still further embodiment of a diversionary device 10″ in accordance with the invention. In the device 10″ according to this embodiment, the compartments and cartridges are aligned axially in-line with one another. In the embodiment as shown in FIG. 12, there are two compartments 20a, 20b each housing a corresponding cartridge 22a, 22b. However, the device is modular in nature and any number of additional compartments/cartridges can be added and FIG. 14 illustrates the device 10″ having three compartments 20a, 20b, 20c.


The device 10″ comprises a housing 12 including a first end cap 12b at an upstream end of the device and a second end cap 12c at a downstream end. At least two tubular housing members 12d, 12e, 12f are arranged between the first and second end caps with adjacent tubular housing members being interconnected by an adaptor 12g. The components of the housing can be made of any suitable materials such as metallic materials including steel or aluminum/aluminum alloy.


The tubular housing members 12d, 12e, 12f are identical and interchangeable. They each have an internal thread at either end for connection with an end cap 12b, 12c or adaptor 12g and a number of exhaust vent holes 120.


The first end cap 12b is located at the upstream end of the device 10″. It includes a main body section 122 with a first threaded spigot 124 which projects from the inner end of the main body section for engagement with the thread at one end of a first tubular housing member 12d to secure them together. A second threaded spigot 126 projects from the outer end of the main body section 122. The second spigot 126 is smaller in diameter than the first and has an external thread on to which can be mounted a firing mechanism 85 similar to that of the previous embodiment, as is shown in FIG. 14. A circular recess 128 is formed coaxially in the inner end of the first threaded spigot. The recess 128 is dimensioned to receive and hold the fuze end of a pyrotechnic cartridge 22a. The recess may have tapered side walls for ease of inserting the cartridge. An axial bore 82 extends through the second spigot 126 and opens into the recess 128. The bore has a stepped larger diameter portion 82a at its outer end in which a percussion cap 83 containing a primer charge can be mounted. The firing mechanism 85 includes a striker plate and/or a firing pin which is urged to strike the percussion cap 83 when the device 10″ is activated so as to produce a flash of heat and pressure (hot gasses) and material which travels down the axial bore 82 to ignite the fee of the first cartridge 22a. The axial bore 82 in this embodiment comprises a first flow path whilst the downstream recess 128 in the first end cap 12b and the corresponding tubular housing member 12d together define the first compartment 20a for receiving the first pyrotechnic cartridge 22a.


Each adaptor 12g has a main body portion 132 with a threaded spigot 134 projecting from either end. The spigots 134 are similar to the first spigot 124 on the first end cap 12b and are configured to engage with the threads at the ends of two adjacent tabular housing members 12d & 12e or 12e & 12f to join them together. A circular and tapered recess 136 is formed at the downstream end of each adaptor for holding the fuze end of a cartridge 22b, 22c in a manner similar to the recess 128 in the first end cap 12b. A further circular recess 138 is formed in the upstream end of each adaptor to hold the charge end of the upstream cartridge 22a, 22b. The two recesses are fluidly connected by means of four bores 140 equi-spaced about a longitudinal axis of the device. The downstream recess 136 in the adaptor and the adjacent downstream tubular housing member 12e, 12fd together define a compartment 20b, 20c for receiving the respective pyrotechnic cartridge 22b, 22c. The downstream end of the last tubular housing member, 12e, 12f is closed by the second end cap 12c. The second end cap 12c comprises a main body section 142 with a threaded spigot 144 projecting from the upstream end of the main body section for engagement with the thread at the end of the last tubular housing member 12e, 12f. A circular recess 145 is formed in the upstream end of the second end cap to hold the charge end of the upstream cartridge 22b, 22c.


When the device is activated, a flash of heat and pressure and material produced when the primer charge in the percussion cap 83 is set off travels down the axial bore 82 in the first end cap 12b and ignites the fuze of the first cartridge 22a. After a delay determined by the fuze, the first cartridge deflagrates giving off a larger flash of heat, pressure wave, sound and light. The bulk of this flash passes out through the vent holes 120 in the first tubular housing member but a portion of the hot gas in particular passes through the recess 138 in the upstream end of the adaptor and the four bores 140 to ignite the fuze of the second cartridge 22b. After a further delay, the pyrotechnic charge in the second cartridge deflagrates giving of a flash of heat, pressure, sound and light, most of which passes out through the vent holes 120 in the second tubular housing member 12e. Where the device 10″ has more than two cartridges, the process continues with each cartridge in the chain being ignited by the deflagration of the charge in the preceding upstream cartridge. In FIG. 14, the arrows 52 schematically illustrate the flow paths of the flash passing out through the vent holes from each cartridge as it deflagrates and the arrows 54 indicate the flow path for hot gasses from one chamber to the next to cause sequential firing of the cartridges. It will be appreciated that the carriages are set off sequentially and not simultaneously.


It has been found that it is advantageous to offset the flow path through the adaptor 12g from the central axis of the cartridges hence the use of the offset bores 140. However, it will be appreciated that the design of the flow path could be varied in a number of ways and is not limited the arrangements shown.


The main body portions 122, 132, 142 of the end caps and the adaptor have a hexagonal outer profile so that the device 10″ will tend to come to a rest more quickly on a surface when thrown as compared with a device which is wholly cylindrical. Nevertheless, this feature is not essential to the main inventive concept.


If more “bangs” are required, the device 10″ can be extended by using an additional adaptor 12g and tubular housing member 12d, 12e, 2f for each additional cartridge. In each device 10″ the first end cap 12b is mounted at the upstream end of the first tubular housing member and the second end cap 12c mounted to the downstream end of the last tubular housing member, with each adjacent pair of tubular housing members being interconnected by an adaptor 12g.


The above embodiments are described by way of example only. Many variations are possible without departing from the scope of the invention as defined in the appended claims. For example, generally it is expected that a diversionary device in accordance with the invention, all the pyrotechnic cartridges will be interconnected in a single series so as to be ignited sequentially. However, the cartridges could be arranged in more than one series, with a first cartridge in each series being ignited from a primer charge and the remaining cartridges in each series being ignited by the hot gas given off when the previous cartridge in the series deflagrates. In a further alterative, the cartridges may be arranged in a series which splits into two or more paths. For example, two cartridges might both be ignited from the hot gas given off by a single previous cartridge in a series. This arrangement could be used to produce a loud bang at the end of a series by setting off two cartridges at the same time.

Claims
  • 1. A diversionary device comprising: a housing holding a plurality pyrotechnic cartridges arranged in series, each cartridge having a combustible fuze and a pyrotechnic charge;a firing arrangement including a primer charge; andthe housing defining a first flow path configured to channel hot gasses (flash) given off by the primer charge onto the fuze of a first cartridge in the series only, the housing defining further flow paths configured to channel a portion of the hot gas (flash) produced on deflagration of the pyrotechnic charge in each of the cartridges upstream from a last cartridge in the series onto the fuze of an adjacent downstream cartridge.
  • 2. A diversionary device as claimed in claim 1, wherein the housing defines a plurality of compartments, each compartment for holding a respective one of the pyrotechnic cartridges.
  • 3. A diversionary device as claimed in claim 2, wherein each compartment has a fuze end and a charge end, each cartridge being located in its respective compartment with its fuze at the fuze end of the compartment and the further flow paths being configured to connect a fuze end of each compartment with the charge end of the preceding upstream compartment in the series.
  • 4. A diversionary device as claimed in claim 3, wherein each compartment comprises a chamber defined within the housing, the further flow paths connecting the chambers sequentially in series, a fuze end region of each chamber in the series downstream from the first chamber being connected by means of a flow path with a charge end region of the preceding upstream chamber in the series.
  • 5. A diversionary device as claimed in claim 1, wherein, for each pair of adjacent chambers in the series, the housing defines a flow path which interconnects the charge end region of the upstream chamber in the pair to the fuze end region of the downstream chamber in the pair and which also connects both end regions to atmosphere.
  • 6. A diversionary device as claimed in claim 3, wherein the housing comprises a main body portion having a central axis with compartments disposed in the main body portion about the axis, the compartments arranged so that the charge end of each compartment is located adjacent the fuze end of the next downstream chamber in the series; the housing also comprising a first end cap and a second end cap, the end caps being releasably mountable to opposite ends of the main body portion, the end caps defining the further flow paths interconnecting compartments sequentially in series.
  • 7. A diversionary device as claimed in claim 6, wherein the first end cap comprises a mounting for receiving a firing mechanism and defines at least part of the first flow path for fluidly connecting the primer charge with a fuze end of a first one of the compartments in the series.
  • 8. A diversionary device as claimed in claim 1, wherein the compartments are disposed generally in a common plane.
  • 9. A diversionary device as claimed in claim, wherein the housing comprises a main body in which the compartments are located and a firing mechanism releasably mountable to the main body, the main body having two parts releasably attachable to one another, the chambers and fluid flow paths being defined by corresponding formations in mating faces of the two parts.
  • 10. A diversionary device as claimed in claim 1, wherein the compartments are arranged axially in-line.
  • 11. A diversionary device as claimed in claim 10, wherein the housing is elongate having an upstream end and a downstream end, the firing arrangement being located at the upstream end.
  • 12. A diversionary device as claimed in claim 11, wherein the housing comprises at least two tubular housing members including a first tubular housing member having an end cap at an upstream end incorporating or to which is mounted the firing mechanism and a final tubular housing member having a second end cap at a downstream end; each pair of adjacent tubular housing members being releasably interconnected by an adaptor.
  • 13. A diversionary device as claimed in claim 12, wherein the first end cap and each of the adaptors define at a downstream end a recess which opens into the interior the adjacent downstream tubular housing member, the recess being dimensioned to receive a fuze end of a respective one of the pyrotechnic cartridges.
  • 14. A diversionary device as claimed in claim 13, wherein each adaptor defines at an upstream end a further recess which opens into the interior of the adjacent upstream tubular housing member for receiving a charge end of a respective one of the pyrotechnic cartridges; each adaptor farther defining a flow path fluidly connecting the recess at the downstream end and the further recess at the upstream end.
  • 15. A diversionary device as claimed in claim 14, wherein the adaptor flow path comprises at least one flow passage which is offset from the axial centreline of the recess.
  • 16. A multi-burst diversionary device comprising: a housing holding a plurality of pyrotechnic cartridges and a firing arrangement operatively connected with a first one of the cartridges to ignite said first one of the cartridges only, the device comprising formations for directing on to each of the remaining cartridges a portion of the hot gas given off on deflagration another of the cartridges.
  • 17. A method of operating a multi-burst diversionary device comprising a plurality of pyrotechnic cartridges each cartridge having a combustible fuze and a pyrotechnic charge, the method comprising: (a) using a primer charge to ignite the fuze of a first one of the cartridges; and(b) sequentially igniting the fuzes of the remaining pyrotechnic cartridges in series by directing a portion of the hot gas produced when each cartridge deflagrates onto the fuze of another of the cartridges.
Priority Claims (1)
Number Date Country Kind
1510556.2 Jun 2015 GB national
CROSS-REFERENCES TO RELATED APPLICATIONS

This is a U.S. National Stage filing made pursuant to 35 U.S.C. § 371. This U.S. application claims the benefit of a prior Patent Cooperation Treaty filing that was assigned Application No. PCT/GB2016/051756. The earliest priority date in the parent application is Jun. 16, 2015

PCT Information
Filing Document Filing Date Country Kind
PCT/GB2016/051756 6/14/2016 WO 00