US3140209A - Explosive initiator-booster containing diethylacetylene and a perchlorate salt - Google Patents

Explosive initiator-booster containing diethylacetylene and a perchlorate salt Download PDF

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US3140209A
US3140209A US141269A US14126961A US3140209A US 3140209 A US3140209 A US 3140209A US 141269 A US141269 A US 141269A US 14126961 A US14126961 A US 14126961A US 3140209 A US3140209 A US 3140209A
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booster
cup
diethylacetylene
fuze
explosive
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David C Sayles
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C1/00Impact fuzes, i.e. fuzes actuated only by ammunition impact
    • F42C1/02Impact fuzes, i.e. fuzes actuated only by ammunition impact with firing-pin structurally combined with fuze
    • CCHEMISTRY; METALLURGY
    • C06EXPLOSIVES; MATCHES
    • C06BEXPLOSIVES OR THERMIC COMPOSITIONS; MANUFACTURE THEREOF; USE OF SINGLE SUBSTANCES AS EXPLOSIVES
    • C06B29/00Compositions containing an inorganic oxygen-halogen salt, e.g. chlorate, perchlorate
    • C06B29/02Compositions containing an inorganic oxygen-halogen salt, e.g. chlorate, perchlorate of an alkali metal
    • C06B29/08Compositions containing an inorganic oxygen-halogen salt, e.g. chlorate, perchlorate of an alkali metal with an organic non-explosive or an organic non-thermic component
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C15/00Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges
    • F42C15/18Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges wherein a carrier for an element of the pyrotechnic or explosive train is moved
    • F42C15/188Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges wherein a carrier for an element of the pyrotechnic or explosive train is moved using a rotatable carrier
    • F42C15/192Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges wherein a carrier for an element of the pyrotechnic or explosive train is moved using a rotatable carrier rotatable in a plane which is parallel to the longitudinal axis of the projectile
    • F42C15/196Arming-means in fuzes; Safety means for preventing premature detonation of fuzes or charges wherein a carrier for an element of the pyrotechnic or explosive train is moved using a rotatable carrier rotatable in a plane which is parallel to the longitudinal axis of the projectile by the action of centrifugal or inertia forces on the carrier body, e.g. the carrier having eccentrically mounted weights or eccentric centre of gravity

Definitions

  • This invention relates to an explosive initiator-booster device serving as a fuze point detonating apparatus when mounted in the forward end of warheads, projectiles and the like, and a new and improved explosive material for the explosive charge within projectiles of a variety of kinds.
  • Booster devices which are currently used to detonate high explosive charges in projectiles or warheads may contain lead azide of the composition Pb(N as the initiator for a booster charge which may contain RDX, 1,3,5-trinitro-1,3,5-triazacyclohexane, which has been desensitized with selected wax compositions.
  • This explosive train provides [the energy to detonate the high explosive filler in the projectile or warhead.
  • Problems to be overcome in booster devices are the unintentional initiating of fuze explosions by environmental conditions such as the heat encountered in automatic weapons and in aerodynamic heating, heat generated by inductive couplings with electrical apparatus and the like, and abnormal prelaunch shocks and rough jolts from transportation and handling.
  • the objects of the present invention are to provide a new and improved point initiating non-delay fuze for detonating the high explosive in a warhead or a projectile filler; a device that materially reduces the unintentional initiating of fuze explosions; the use of mercury or an amalgam of comparable function to react with a mixture of silver perchlorate and 3-hexyne as replacement for the earlier loading increments of a primer mixture, lead azide and an RDX wax explosive; etc.
  • the booster device that is illustrated in the single figure of the accompanying drawing comprises a hollow cylindrical inner core 1 made of steel or the like.
  • the core 1 bears external threads 2 that thread axially into internal threads 3 of a booster holder assembly outer sleeve 4.
  • a flange 5 of the inner core 1 abuts axially the left hand end of the outer sleeve 4.
  • the outer sleeve 4 may be made of steel and is provided with external threads 20 for threading the device into the front end of the warhead or projectile with which it is to be used.
  • the inner core 1 is apertured centrally to contain a thin inert metal or plastic fuze booster can 6 that is secured in its compartment by beads 7 of cold solder or the like.
  • the fuze booster can 6 contains a suitable fuze booster, such illustratively as a mixture of silver perchlorate AgClO and 3-hexyne or diethylacetylene C H CECC H in the weight proportion of 16.1 grams of silver perchlorate to 7.2 grams of 3-hexyne.
  • the front end 8 of the fuze booster can 6 is frangible and illustratively may be made of glass, a thin, prescored plastic, such as a phenolformaldehyde resin or the like.
  • the front end socket 9 of the inner core 1 is shaped as a concave part of a sphere or a cylinder, as preferred, to house a freely rotatable member 10.
  • the rotatable member 10 contains a detonator containing cup 11.
  • the cup 11 contains a detonator that is explosively reactive when mixed with the fuze booster contents of the can 6.
  • An il- 3,14%,209 Patented July 7, 1964 lustrative detonator is mercury, a suitable amalgam that releases mercury on impact or the like.
  • An amalgam is a solution of a metal in mercury. 1
  • the rotatable member 10 illustratively may be made of a refractory material, as indicated by the dashed section lines.
  • the rotatable member 10 contains a cylindrical detonator cup 11 that is of a material that is inert to mercury, such as glass, or the like.
  • the member 10 is shown in full lines in its unarmed position and in dotted outline in its armed position. In its unarmed position the rotatable member 10 has a firing pin plunger retention hole 21 in its peripheral surface that receives and retains the tip of the frusto-conical plunger end 17 of the firing pin 13.
  • the firing pin 18 slides axially of the assembly in a cylindrical hole in the forward end of the outer sleeve.
  • the cup 11 has a bottom 12 that is of a mercury inert frangible material, such as a thin disc of glass, a scored disc of phenol-formaldehyde resins or the like, that is sealed in plastic with cement against the inwardly flared bottom flange 13 of the cup 11 in leakproof relation therewith to avoid the loss of the contents of the cup 11.
  • a mercury inert frangible material such as a thin disc of glass, a scored disc of phenol-formaldehyde resins or the like
  • the cup 11 contains a cushion 14 of resilient rubber or plastic that compensates for the expansion and contraction of the contents of the cup from the temperature change to which the device is subjected.
  • a top disc 15 of frangible material that is inert toward mercury. The peripheral edge of the cup top disc 15 is cemented against leakage to the upper flange 16 of the cup 11.
  • the upper flange 16 of the cup 11 in its armed position is dimensioned to progressively closely fit and preferably as nearly as possible to seal its engagement with the frustoconical plunger end 17 of the firing pin 18 when the firing pin plunger end is rammed into the orifice defined by the cup 11 upper flange 16 on impact of the device against its target.
  • the rotatable member 10 has a pair of shoulders 24 and 25 that are engaged by a retaining leaf spring 26 to positively secure the rotatable member 10 against rotation in its unarmed position.
  • the spring 26 is positioned with its ends abutting against the outer sleeve shoulder 27 and the firing pin shoulder 28.
  • the rotatable member 10 is held in its unarmed position by the engagement of its shoulders 24 and 25 bearing against the edge of the spring 26.
  • rotatable member shoulders 24 and 25 are shown to be spaced away from the inturned flange 16 that is turned in along the edge of the upper end of the cup 11 to secure the cup 11 in place within the rotatable member 10 during the assembly of the device.
  • a ring 32 arrests the motion of the right hand end of the spring 26 during the assembly of the device.
  • the firing pin 18 flange 33 abuts the right hand end of the outer sleeve 4 and, together with the spring 26 exerts a dual safety provision for the device.
  • the fuze cover 34 is of thin metal such as aluminum, steel or the like and terminates to the left in an inturned flange 35 that overlies the outwardly extending outer sleeve flange 36 that is intermediate between the ends of the device.
  • the rotary member 10 remains as shown in the drawing with the axis of the cup 11 out of incidence with the central axis of the fuze during acceleration.
  • the rifling in the gun bore from which the projectile is launched imparts rotary motion to the fuze.
  • Increasing centrifugal force causes the spring 26 to move out to its dotted line position and free the rotary member and the firing pin 18.
  • the emission of the fuze from the gun bore removes the initial acceleration and the firing pin moves axially forwardly of the assembly and permits the unbalanced rotatable member 10 to assume its balanced position with the central axis of the detonator cup 11 coincident with the central axis of the fuze assembly.
  • the fuze is then armed and awaits impact.
  • the firing pin 18 On impact the velocity of the firing pin 18 is arrested, driving its conical plunger end 17 through the orifice in the front end of the cup 11 and, acting as a piston, the firing pin plunger end 17 crushes the detonator cup frangible top disc and advances the rubber plunger 14 axially of the cup 11.
  • the resulting pressure applied to the mercury or amalgarn in the cup 11 ruptures both the rear frangible disc 12 in the detonato'r cup' 11 and the top frangible disc 8 in the booster can 6.
  • the contents of the booster can 6 detonates on contact with the mercury from thecup 11 and the force of the resultant explosion is directed through the bottom of the can 6 directly into the high explosive filler in the warhead or in the projectile.
  • the melting point of an element or a compound is the temperature at which its liquid and solid phases exist top gether at one atmosphere of pressure.
  • the silver perchlorate disclosed herein may if preferred be replaced for an equivalent function by perchlorates of aluminum, copper and gold.
  • the triple bond between carbon atoms in 3-hexyne or C H CECC H imparts a 40 high performance initiating system to the silver p'erchlorate 3'-hexyne complex in the booster can 6 since the triple bond energy per mole is 123 kilocalories, as compared with single bond at 58.6 kilocalories.
  • Homologues of 4 acetylene HCECH here of interest include Z-pentyne or ethylmethylacetylene H3CCECCH2CH3.
  • Amalgams that function interchangeably with mercury illustratively are those of gallium, indium, tin, bismuth,
  • the booster can contents as a charge proportionally by weight consisting of 7.2 grams of diethylacetylene;
  • the fuze booster material consisting of silver'perchlorate; mixed with diethylacetylene in the weight proportion of 16.1 grams of silver perchlorate to 7.2 grams of diethylacetylene and the mixed material cooperating to produce the unitary result of causing the detonation of an explosive charge.

Description

July 7. 1964 D. c. SAYLES 3,140,209
EXPLOSIVE INITIATOR-BOOSTER CONTAINING DIETHYLACETYLENE AND A PERCHLORATE SALT Filed Sept. 26. 1961 m I I0 1 ATTORNEYS United States Patent 3,140,209 EXPLOSIVE [NITIATOR-BOOSTER CONTAINING DIETHYLACETYLENE AND A PERCHLORATE SALT David C. Sayles, Huntsville, Ala., assignor to the United States of America as represented by the Secretary of the Air Force Filed Sept. 26, 196-1, Ser. No. 141,269 2 Claims. (Cl. 149-75) (Granted under Title 35, US. Code (1952), see. 266) The invention described herein may be manufactured and used by or for the United States Government for governmental purposes without the payment to me of any royalty thereon.
This invention relates to an explosive initiator-booster device serving as a fuze point detonating apparatus when mounted in the forward end of warheads, projectiles and the like, and a new and improved explosive material for the explosive charge within projectiles of a variety of kinds.
Booster devices which are currently used to detonate high explosive charges in projectiles or warheads may contain lead azide of the composition Pb(N as the initiator for a booster charge which may contain RDX, 1,3,5-trinitro-1,3,5-triazacyclohexane, which has been desensitized with selected wax compositions. This explosive train provides [the energy to detonate the high explosive filler in the projectile or warhead. Problems to be overcome in booster devices are the unintentional initiating of fuze explosions by environmental conditions such as the heat encountered in automatic weapons and in aerodynamic heating, heat generated by inductive couplings with electrical apparatus and the like, and abnormal prelaunch shocks and rough jolts from transportation and handling.
The objects of the present invention are to provide a new and improved point initiating non-delay fuze for detonating the high explosive in a warhead or a projectile filler; a device that materially reduces the unintentional initiating of fuze explosions; the use of mercury or an amalgam of comparable function to react with a mixture of silver perchlorate and 3-hexyne as replacement for the earlier loading increments of a primer mixture, lead azide and an RDX wax explosive; etc.
The booster device that is illustrated in the single figure of the accompanying drawing comprises a hollow cylindrical inner core 1 made of steel or the like. The core 1 bears external threads 2 that thread axially into internal threads 3 of a booster holder assembly outer sleeve 4. A flange 5 of the inner core 1 abuts axially the left hand end of the outer sleeve 4. The outer sleeve 4 may be made of steel and is provided with external threads 20 for threading the device into the front end of the warhead or projectile with which it is to be used.
The inner core 1 is apertured centrally to contain a thin inert metal or plastic fuze booster can 6 that is secured in its compartment by beads 7 of cold solder or the like. The fuze booster can 6 contains a suitable fuze booster, such illustratively as a mixture of silver perchlorate AgClO and 3-hexyne or diethylacetylene C H CECC H in the weight proportion of 16.1 grams of silver perchlorate to 7.2 grams of 3-hexyne. The front end 8 of the fuze booster can 6 is frangible and illustratively may be made of glass, a thin, prescored plastic, such as a phenolformaldehyde resin or the like.
The front end socket 9 of the inner core 1 is shaped as a concave part of a sphere or a cylinder, as preferred, to house a freely rotatable member 10. The rotatable member 10 contains a detonator containing cup 11. The cup 11 contains a detonator that is explosively reactive when mixed with the fuze booster contents of the can 6. An il- 3,14%,209 Patented July 7, 1964 lustrative detonator is mercury, a suitable amalgam that releases mercury on impact or the like. An amalgam is a solution of a metal in mercury. 1
The rotatable member 10 illustratively may be made of a refractory material, as indicated by the dashed section lines. The rotatable member 10 contains a cylindrical detonator cup 11 that is of a material that is inert to mercury, such as glass, or the like. The member 10 is shown in full lines in its unarmed position and in dotted outline in its armed position. In its unarmed position the rotatable member 10 has a firing pin plunger retention hole 21 in its peripheral surface that receives and retains the tip of the frusto-conical plunger end 17 of the firing pin 13. The firing pin 18 slides axially of the assembly in a cylindrical hole in the forward end of the outer sleeve.
The cup 11 has a bottom 12 that is of a mercury inert frangible material, such as a thin disc of glass, a scored disc of phenol-formaldehyde resins or the like, that is sealed in plastic with cement against the inwardly flared bottom flange 13 of the cup 11 in leakproof relation therewith to avoid the loss of the contents of the cup 11.
The cup 11 contains a cushion 14 of resilient rubber or plastic that compensates for the expansion and contraction of the contents of the cup from the temperature change to which the device is subjected. Above the rubber cushion 14 is a top disc 15 of frangible material that is inert toward mercury. The peripheral edge of the cup top disc 15 is cemented against leakage to the upper flange 16 of the cup 11.
The upper flange 16 of the cup 11 in its armed position is dimensioned to progressively closely fit and preferably as nearly as possible to seal its engagement with the frustoconical plunger end 17 of the firing pin 18 when the firing pin plunger end is rammed into the orifice defined by the cup 11 upper flange 16 on impact of the device against its target.
The rotatable member 10 has a pair of shoulders 24 and 25 that are engaged by a retaining leaf spring 26 to positively secure the rotatable member 10 against rotation in its unarmed position. The spring 26 is positioned with its ends abutting against the outer sleeve shoulder 27 and the firing pin shoulder 28. The rotatable member 10 is held in its unarmed position by the engagement of its shoulders 24 and 25 bearing against the edge of the spring 26. The
rotatable member shoulders 24 and 25 are shown to be spaced away from the inturned flange 16 that is turned in along the edge of the upper end of the cup 11 to secure the cup 11 in place within the rotatable member 10 during the assembly of the device. A ring 32 arrests the motion of the right hand end of the spring 26 during the assembly of the device.
The firing pin 18 flange 33 abuts the right hand end of the outer sleeve 4 and, together with the spring 26 exerts a dual safety provision for the device.
The fuze cover 34 is of thin metal such as aluminum, steel or the like and terminates to the left in an inturned flange 35 that overlies the outwardly extending outer sleeve flange 36 that is intermediate between the ends of the device.
The theory of operation of the point detonating fuze that is shown in the accompanying drawing mounted in the front end of a warhead or a projectile starts with inertial forces acting on the members of the fuze assembly. The leaf spring 26 acts as a strut and together with the firing pin flange 33 prevents the firing pin plunger 17 from damaging the rotary member 10 during acceleration within the gun bore.
During the launching operation with the fuze in the gun bore the rotary member 10 remains as shown in the drawing with the axis of the cup 11 out of incidence with the central axis of the fuze during acceleration. The rifling in the gun bore from which the projectile is launched imparts rotary motion to the fuze. Increasing centrifugal force causes the spring 26 to move out to its dotted line position and free the rotary member and the firing pin 18.
The emission of the fuze from the gun bore removes the initial acceleration and the firing pin moves axially forwardly of the assembly and permits the unbalanced rotatable member 10 to assume its balanced position with the central axis of the detonator cup 11 coincident with the central axis of the fuze assembly. The fuze is then armed and awaits impact.
On impact the velocity of the firing pin 18 is arrested, driving its conical plunger end 17 through the orifice in the front end of the cup 11 and, acting as a piston, the firing pin plunger end 17 crushes the detonator cup frangible top disc and advances the rubber plunger 14 axially of the cup 11.
The resulting pressure applied to the mercury or amalgarn in the cup 11 ruptures both the rear frangible disc 12 in the detonato'r cup' 11 and the top frangible disc 8 in the booster can 6. The contents of the booster can 6 detonates on contact with the mercury from thecup 11 and the force of the resultant explosion is directed through the bottom of the can 6 directly into the high explosive filler in the warhead or in the projectile.
The melting point of an element or a compound is the temperature at which its liquid and solid phases exist top gether at one atmosphere of pressure. Mercury melts at 39 C. or 38 F. Gallium melts at 30 C. Indium melts at 156 C. Tin melts at 232 C. Bismuth melts at 271 C. Cadmium melts at321 C. Lead melts at 327 C. All of these melting points are depressed or lowered when mecury is alloyed with the element as an amalgam of the element. The same is true for other elements such as zinc,- tellurium, antimony, aluminum, gold, copper etc. The silver perchlorate disclosed herein may if preferred be replaced for an equivalent function by perchlorates of aluminum, copper and gold. The triple bond between carbon atoms in 3-hexyne or C H CECC H imparts a 40 high performance initiating system to the silver p'erchlorate 3'-hexyne complex in the booster can 6 since the triple bond energy per mole is 123 kilocalories, as compared with single bond at 58.6 kilocalories. Bombs containing comparable charges in glass or plastic frangible containers that mix the reagents on impact fall Within this disclosure. Amalgamsa're solid or liquid depending on the proportion of mercury present. Prestressed aluminum dissolves promptly in mercury. Homologues of 4 acetylene HCECH here of interest include Z-pentyne or ethylmethylacetylene H3CCECCH2CH3.
Amalgams that function interchangeably with mercury illustratively are those of gallium, indium, tin, bismuth,
5 cadmium, lead, zinc, tellurium, antimony, aluminum, gold,
and copper.
The chemical complex of inorganic perchlorates with disubstituted alkynes and low melting point metals impart an improved performance to the device that is disclosed 10 herein. In this initiator the mercury replaces three loading increments in earlier devices, namely the primer mixture, lead azide and the RDX wax explosive. The ex- 1 plosive components that are disclosedherein provide uniformly reproducible results. 1
5 It is to be understood that the device and the charge that are described herein are submitted for the purposes of describing this invention and that similarly functioning modifications may he made therein without departing from the spirit and scope of the invention.
I claim:
1. The booster can contents as a charge proportionally by weight consisting of 7.2 grams of diethylacetylene;
mixed with the equivalent of 16.1 grams of silver perchlorate of a perchlorate of a metal selected from the group consisting of silver, aluminum, gold and copper and the mixed material cooperating to produce the unitary result of causing the detonation of an explosive charge.
2. The fuze booster material consisting of silver'perchlorate; mixed with diethylacetylene in the weight proportion of 16.1 grams of silver perchlorate to 7.2 grams of diethylacetylene and the mixed material cooperating to produce the unitary result of causing the detonation of an explosive charge.
References Cited in the file of this patent UNITED STATES PATENTS 2,824,518 Piskorski et a1 Feb. 25, 1958 2,850,980 Stevenson et a1. Sept. 9, 1958 FOREIGN PATENTS 18,659 Great Britain a"-.. -1912 OTHER REFERENCES Appleton-Century Co., Inc.,- New York.

Claims (1)

1. THE BOOSTER CAN CONTENTS AS A CHARGE PROPORTIONALLY BY WEIGHT CONSISTING OF 7.2 GRAMS DIETHYLACETYLENE; MIXED WITH THE EQUIVALENT OF 16.1 GRAMS OF SILVER PERCHLORATE OF A PERCHLORATE OF A METAL SELECTED FROM THE GROUP CONSISTING OF SILVER, ALUMINUM, GOLD AND COPPER AND THE MIXED MATERIAL COOPERATING TO PRODUCE THE UNITARY RESULT OF CAUSING THE DETONATION OF AN EXPLOSIVE CHARGE.
US141269A 1961-09-26 1961-09-26 Explosive initiator-booster containing diethylacetylene and a perchlorate salt Expired - Lifetime US3140209A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3763785A (en) * 1972-03-20 1973-10-09 Us Navy Mal-assembly feature for explosive train fuzes

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB191218659A (en) * 1912-08-14 1913-11-14 Philipp Lentz Explosive Projectile.
US2824518A (en) * 1953-11-06 1958-02-25 Piskorski John Fuze for small caliber ammunition
US2850980A (en) * 1955-07-08 1958-09-09 Albert E Stevenson Point detonating fuze for high velocity round

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB191218659A (en) * 1912-08-14 1913-11-14 Philipp Lentz Explosive Projectile.
US2824518A (en) * 1953-11-06 1958-02-25 Piskorski John Fuze for small caliber ammunition
US2850980A (en) * 1955-07-08 1958-09-09 Albert E Stevenson Point detonating fuze for high velocity round

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3763785A (en) * 1972-03-20 1973-10-09 Us Navy Mal-assembly feature for explosive train fuzes

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